modular thermal storage

专利摘要:
power generation system comprising a shared hot-side thermal store, a shared cold-side thermal store, a plurality of energy subunits and an electric bus is disclosed. each of the energy subunits can be connected to or isolated from the thermal storage on the shared hot side and / or the thermal store on the shared cold side.
公开号:BR112019013453A2
申请号:R112019013453
申请日:2017-12-18
公开日:2019-12-31
发明作者:green Julian；Larochelle Philippe；Apte Raj
申请人:Malta Inc；
IPC主号:

专利说明:

MODULAR THERMAL STORAGE
CROSS REFERENCE FOR RELATED APPLICATION [001] This application claims priority for US patent application 15 / 396,461, filed on December 31, 2016, which is incorporated into this document by reference in its entirety.
BACKGROUND [002] In a thermal engine or heat pump, a heat exchanger can be employed to transfer heat between a thermal storage material and a working fluid for use with turbomachinery. The thermal motor can be reversible, for example, it can also be a heat pump, and the working fluid and heat exchanger can be used to transfer heat or cold to thermal storage media.
SUMMARY [003] A closed thermodynamic cycle power generation or energy storage system, such as a reversible Brayton cycle system, can include at least one working fluid circulated through a closed cycle fluid path including at least two heat exchangers, a turbine and a compressor. Some systems may include a plurality of closed loop systems (energy subunits), each configured to be connected to or isolated from shared hot-side thermal storage and shared cold-side thermal storage.
[004] Example power generation systems may include hot-side thermal storage comprising a first thermal storage tank
Petition 870190103250, of 10/14/2019, p. 8/149
2/114 hot (HTS), a second HTS tank, an HTS medium, an HTS supply flow configured to receive an HTS medium flow from the first HTS tank, an HTS return flow configured to send an HTS medium flow to the second HTS tank. Example power generation systems may additionally include a cold-side thermal storage comprising a first cold thermal storage (CTS) tank, a second CTS tank, a CTS medium, a CTS supply stream configured to receive a flow of CTS medium from the second CTS tank, a CTS return flow configured to send a flow of CTS medium to the first CTS tank. Examples of power generation systems may additionally include a plurality of energy subunits, each energy subunit comprising: a generator configured to generate electricity, a compressor, a hot-side heat exchanger, a turbine, a heat exchanger of cold side, a working fluid circulating in a closed cycle path, where the closed cycle path comprises, in sequence, the compressor, the hot side heat exchanger, the turbine and the cold side heat exchanger, and a configurable valve arrangement to be in a connected state or in an isolated state, where in the connected state the valve arrangement is configured to connect the hot-side heat exchanger to the HTS supply flow and the HTS return flow and to connect the cold side heat exchanger to the CTS supply flow and the CTS return flow, where in the isolated state the valve arrangement is configured to isolate the heat exchanger r hot side in relation to the HTS supply flow and the
Petition 870190103250, of 10/14/2019, p. 9/149
3/114 HTS return flow and to isolate the cold side heat exchanger from the CTS supply flow and the CTS return flow. Example power generation systems may additionally include an electrical bus coupled electrically to each generator of each energy subunit of the plurality of energy subunits, in which the electrical bus is configured to charge electrical energy generated by each generator to an electrical node.
BRIEF DESCRIPTION OF THE DRAWINGS [005] Figure 1 schematically illustrates the operation of a pumped electrical thermal storage system.
[00 6] Figure 2 is a schematic flow diagram of working fluid and heat storage media from a thermal system pumped in a load / heat pump mode.
[007] Figure 3 is a schematic flow diagram of working fluid and heat storage media from a thermal system pumped in a thermal engine / discharge mode.
[008] Figure 4 is a schematic diagram of pressure and temperature of the working fluid as it is subjected to the load cycle in figure 2.
[009] Figure 5 is a schematic diagram of pressure and temperature of the working fluid as it is subjected to the discharge cycle in figure 3.
[010] Figure 6 is a schematic perspective view of a closed cycle working fluid system in the thermal system pumped in figures 2-3.
[Oil] Figure 7 is a schematic perspective view of the thermal system pumped in figures 2-3 with tanks of
Petition 870190103250, of 10/14/2019, p. 10/149
4/114 hot and cold side storage and a closed cycle working fluid system.
[012] Figure 8 shows a heat storage load cycle for a molten water / salt system with r) _c = 0.9 and r) t = 0.95. The dashed lines correspond to r) _c = i) _t = 1.
[013] Figure 9 shows a heat storage discharge (extraction) cycle for the molten water / salt system in figure 8 with η ₀ = 0.9 er) t = 0.95. The dashed lines correspond to η ₀ = ht = 1 · [014] Figure 10 shows a heat storage cycle in a pumped thermal system with varying compression ratios between loading and unloading cycles.
[015] Figure 11 shows full cycle efficiency curves for a water / salt system. The symbols © and 0 represent an approximate range of adiabatic efficiency values of large turbomachinery present. The dashed arrows represent the direction of increased efficiency.
[016] Figure 12 shows full cycle efficiency curves for a cooler salt / storage system. The symbols © and 0 represent an approximate range of adiabatic efficiency values of large turbomachinery present.
[017] Figure 13 is a schematic flow diagram of working fluid and heat storage media from a thermal system pumped with a gas-to-gas heat exchanger to the working fluid in a charge / pump mode. heat.
[018] Figure 14 is a schematic flow diagram of
Petition 870190103250, of 10/14/2019, p. 11/149
5/114
working fluid and means in storage in heat in a thermal system pumped with a changer in heat in gas-gas for the fluid work in a mode in
discharge / thermal engine.
[019] Figure 15 is a schematic flow diagram of working fluid and heat storage media from a thermal system pumped with a gas-to-gas heat exchanger to the working fluid in a charge / pump mode. heat with indirect heat rejection to the environment.
[020] Figure 16 is a schematic flow diagram of working fluid and heat storage media from a thermal system pumped with a gas-gas heat exchanger to the working fluid in a thermal engine / discharge mode. with indirect heat rejection to the environment.
[021] Figure 17 shows a heat storage charge cycle for a storage system with a gas-gas heat exchanger, a cold-side storage medium capable of cooling to temperatures significantly below ambient temperature and r] _c = 0.9 er] t = 0.95.
[022] Figure 18 shows a heat storage discharge cycle for a storage system with a gas-gas heat exchanger, a cold-side storage medium capable of cooling to temperatures significantly below ambient temperature and r] _c = 0.9 and ht = 0.95.
[023] Figure 19 is a schematic flow diagram of hot side recharging in a heat cycle pumped in solar mode with heating of a solar salt only.
Petition 870190103250, of 10/14/2019, p. 12/149
6/114 by means of solar energy.
[024] Figure 20 is a schematic flow diagram of a thermal system discharge cycle pumped with heat rejection into the environment.
[025] Figure 21 is a schematic flow diagram of a thermal system discharge cycle pumped with heat rejection to an intermediate fluid circulated in a thermal bath at room temperature.
[026] Figures 22 and 23 are thermal systems pumped with separate compressor / turbine pairs for loading and unloading modes.
[027] Figures 24 and 25 show pumped thermal systems configured in a combustion heat input generation mode.
[028] Figure 26 is a schematic flow diagram of hot-side recharging in a heat cycle pumped through heating by a combustion heat source or a residual heat source.
[029] Figure 27 shows an example of a pumped thermal system with pressure regulated energy control.
[030] Figure 28 shows an example of a thermal system pumped with a generator closed with pressure.
[031] Figure 29 is an example of variable stators in a compressor / turbine pair.
[032] Figure 30 shows a computer system that is programmed to implement various methods and / or regulate various systems of the present disclosure.
[033] Figure 31 illustrates a power generation system with subunits, according to a modality of
Petition 870190103250, of 10/14/2019, p. 13/149
7/114 example.
DETAILED DESCRIPTION [034] Example systems and methods are described in this document. It should be understood that the words example and / or example are used in this document to mean serving as an example, instance or illustration. Any modality or feature described in this document as being an example or example is not necessarily to be interpreted as preferred or advantageous in relation to other modalities or features. The example modalities described in this document are not intended to be limiting. It will be readily understood that certain aspects of the revealed systems and methods can be arranged and combined in a wide variety of configurations
many different, all at Which are they considered in this document.[035] Although several modalities of invention be shown and described in this document, it will be obvious To the
skilled in the art that such modalities are provided by way of example only. Numerous variations, changes and substitutions can occur for those skilled in the art without departing from the invention. It is to be understood that several alternatives to the modalities of the invention described in this document can be employed. It should be understood that different aspects of the invention can be evaluated individually, collectively or in combination with each other.
[036] It is to be understood that the terminology applied in this document is used for the purpose of describing specific modalities, and is not proposed to limit the
Petition 870190103250, of 10/14/2019, p. 14/149
8/114 scope of the present invention. It should be noted that, as used in this document, the singular forms of one, one, o and a include plural references unless the context clearly dictates otherwise. In addition, unless otherwise defined, all technical and scientific terms used in this document have the same meaning commonly understood by a person of ordinary knowledge in the technique to which this invention belongs.
[037] Although preferable embodiments of the present invention are shown and described in this document, it will be obvious to those skilled in the art that such modalities are provided by way of example only. Numerous variations, changes and substitutions will occur for those skilled in the art without departing from the invention. It is to be understood that several alternatives to the modalities of the invention described in this document can be employed when carrying out the invention. The following claims are intended to define the scope of the invention and methods and structures within the scope of these claims and their equivalents are covered in this way.
I. Overview [038] A closed thermodynamic cycle power generation or energy storage system, such as a reversible Brayton cycle system, can use a generator / engine connected to a turbine and compressor that act on a working fluid circulating in the system. Examples of working fluids include air, argon, carbon dioxide or gas mixtures. A power generation or cycle energy storage system
Petition 870190103250, of 10/14/2019, p. 15/149
9/114 closed thermodynamics, such as a reversible Brayton cycle system, can have a hot side and / or a cold side. Each side can include a heat exchanger coupled to one or more cold storage containers and / or one or more hot storage containers. Preferably, heat exchangers can be arranged as countercurrent heat exchangers for increased thermal efficiency. Liquid thermal storage media can be used and can include, for example, liquids that are stable at high temperatures, such as nitrate salt or molten solar salt, or liquids that are stable at low temperatures, such as glycols or alkanes such as hexanes. As an example in a molten salt and hexane system, hot-side molten salt can include hot storage at approximately 5 65 ° C and cold storage at approximately 290 ° C, and cold hexane can include hot storage at approximately 35 ° C and cold storage at approximately -60 ° C.
[039] Large power generation systems can be slow to achieve full power generation. In addition, transient out-of-phase increases in energy generated in such large systems can be disruptive. Instead, it may be desirable to use a plurality of energy subunits, each energy subunit generating a portion of the maximum total energy. Each power sub-unit can include a configurable valve arrangement to be in a connected state or in an isolated state in relation to shared hot-side thermal storage and shared cold-side thermal storage (that is, to be in use or not in use).
Petition 870190103250, of 10/14/2019, p. 16/149
11/104
II. Illustrative Reversible Thermal Motor [040] Although various modalities of the invention are shown and described in this document, it will be obvious to those skilled in the art that such modalities are provided by way of example only. Numerous variations, changes and substitutions can occur for those skilled in the art without departing from the invention. It is to be understood that several alternatives to the modalities of the invention described in this document can be employed. It should be understood that different aspects of the invention can be evaluated individually, collectively or in combination with each other.
[041] It is to be understood that the terminology applied in this document is used for the purpose of describing specific modalities, and is not proposed to limit the scope of the present invention. It should be noted that, as used in this document, the singular forms of one, one, o and a include plural references unless the context clearly dictates otherwise. In addition, unless otherwise defined, all technical and scientific terms used in this document have the same meaning commonly understood by a person of ordinary knowledge in the technique to which this invention belongs.
[042] Although preferable embodiments of the present invention are shown and described in this document, it will be obvious to those skilled in the art that such modalities are provided by way of example only. Numerous variations, changes and substitutions will occur for those skilled in the art without departing from the invention. Must be
Petition 870190103250, of 10/14/2019, p. 17/149
11/114 it is understood that various alternatives to the modalities of the invention described in this document can be employed when carrying out the invention. The following claims are intended to define the scope of the invention and methods and structures within the scope of these claims and their equivalents are covered in this way.
[043] The term reversible, as used in this document, generally refers to a process or operation that can be reversed through infinitesimal changes in some process or operation property without substantial entropy production (eg, dissipation power). A reversible process can be approximated by a process that is in thermodynamic equilibrium. In some instances, in a reversible process, the direction of energy flow is reversible. As an alternative, or in addition, the general direction of operation of a reversible process (for example, the direction of fluid flow) can be reversed, such as, for example, from clockwise to counterclockwise and vice versa. versa.
[044] The term sequence, as used in this document, generally refers to elements (for example, unit operations) in order. Such an order can refer to a process order, such as, for example, the order in which a fluid flows from one element to another. In one example, a compressor, heat storage unit and turbine in sequence includes the compressor upstream of the heat exchange unit, and the heat exchange unit upstream of the turbine. In a case like this, a fluid can flow from the compressor to the heat exchange unit and the
Petition 870190103250, of 10/14/2019, p. 18/149
12/114 turbine heat exchange unit. A fluid flowing through sequential unit operations can flow sequentially through unit operations. A sequence of elements can include one or more intervening elements. For example, a system comprising a compressor, heat storage unit and turbine in sequence may include an auxiliary tank between the compressor and the heat storage unit. A sequence of elements can be cyclical.
Pumped Thermal Systems [045] The revelation provides pumped thermal systems capable of storing electrical energy and / or heat, and releasing energy (for example, producing electricity) later. The pumped thermal systems of the development can include a thermal engine, and a heat pump (or cooler). In some cases, the thermal engine can be operated inverted like a heat pump. In some cases, the thermal engine can be operated inverted like a refrigerator. Any description of heat pump / thermal engine systems or refrigerator / thermal engine systems capable of reverse operation in this document can also be applied to systems comprising thermal engine (s) system (s), system (s) of separate heat pump (s) and / or cooler system (s) and / or in a combination of separate and inverted operables. In addition, as heat pumps and refrigerators share the same operating principles (albeit for different purposes), any description of heat pump configurations or operation in this document can also be applied to configurations or operation of refrigerators and vice versa.
Petition 870190103250, of 10/14/2019, p. 19/149
13/114 [046] Systems of the present disclosure can operate as thermal motors or heat pumps (or refrigerators). In some situations, development systems may alternately operate as thermal motors and heat pumps. In some instances, a system can operate as a thermal engine to generate energy, and subsequently operate as a heat pump to store energy, or vice versa. Such systems alternately and sequentially can operate as thermal motors and as heat pumps. In some cases, such systems in a reversible or substantially reversible manner operate as thermal motors and as heat pumps.
[047] Reference will now be made to the figures, in which equal numbers refer to equal parts throughout them. It will be noticed that the figures and resources on them are not necessarily drawn to scale.
[048] Figure 1 schematically illustrates operating principles of pumped electrical thermal storage using a heat pump / thermal motor electricity storage system. Electricity can be stored in the form of thermal energy from two materials or media at different temperatures (for example, thermal energy tanks comprising heat storage fluids or thermal storage media) when using a combined heat pump / thermal motor system. In a loading or heat pump mode, work can be consumed by the system to transfer heat from a cold material or medium to a hot material or medium, thereby lowering the temperature (for example, sensitive energy) of the cold material and increasing the temperature (ie energy
Petition 870190103250, of 10/14/2019, p. 20/149
14/114 sensitive) of the hot material. In a thermal engine or unloading mode, work can be produced by the system by transferring heat from the hot material to the cold material, thereby lowering the temperature (ie sensitive energy) of the hot material and increasing the temperature (ie energy of the cold material. The system can be configured to ensure that the work produced by the system at the discharge is a favorable fraction of the energy consumed at the load. The system can be configured to achieve high full cycle efficiency, defined in this document as the work produced by the system under discharge divided by the work consumed by the system under load. In addition, the system can be configured to achieve high full cycle efficiency using components at a desired cost (for example, acceptable low). The arrows H and W in figure 1 represent directions of heat flow and work, respectively.
[049] Developing thermal engines, heat pumps and coolers can involve a working fluid to and from which heat is transferred while undergoing a thermodynamic cycle. The development's thermal motors, heat pumps and coolers can operate in a closed cycle. Closed cycles allow, for example, a wider selection of working fluids, operation at high cold side pressures, operation at lower cold side temperatures, improved efficiency and reduced risk of turbine damage. One or more aspects of the disclosure described in relation to systems having working fluids being subjected to closed cycles can also be
Petition 870190103250, of 10/14/2019, p. 21/149
11/15 applied to systems with working fluids being subjected to open cycles.
[050] In one example, thermal engines can operate on a Brayton cycle and heat pumps / coolers can operate on an inverse Brayton cycle (also known as a gas refrigeration cycle). Other examples of thermodynamic cycles to which the working fluid can be subjected or approached include the Rankine cycle, the ideal vapor compression refrigeration cycle, the Stirling cycle, the Ericsson cycle or any other cycle advantageously used in common with exchange heat with development heat storage fluids.
[051] The working fluid can be subjected to a thermodynamic cycle operating at one, two or more pressure levels. For example, the working fluid can operate in a closed cycle between a low pressure limit on a cold side of the system and a high pressure limit on a hot side of the system. In some implementations, a low pressure limit of about 10 atmospheres (atm) (1.01325 MPa) or greater can be used. In some instances, the low pressure limit may be at least about 1 atm (0.101325
MPa), fur less about 2 atm (0, 20265 MPa), fur any less fence out of 5 atm (0.506625 MPa) , fur any less about 10 ATM (1.01325 MPa), at least about 15 atm (1, 51988 MPa), fur any less about 20 ATM (2 , 0265 MPa), fur any less fence of 30 atm (3.03975 MPa) , fur any less fence of 4 0 atm (4,053 MPa), fur less about of 60 ATM (6 0795 MPa), fur any less fence of 8 0 atm (8,106 MPa), at least fence 100 ATM
(10.1325 MPa), at least about 120 atm (12.159 MPa), at least about 160 atm (16.212 MPa), or at least
Petition 870190103250, of 10/14/2019, p. 22/149
16/114 about 200 atm (20.265 MPa), 500 atm (50.6625 MPa), 1000 atm (101.325 MPa), or more. In some instances, a low subatmospheric pressure limit may be used. For example, the low pressure limit may be less than about 0.1 atm (0.0101325 MPa), less than about 0.2 atm (0.020265 MPa), less than about 0.5 atm (0 , 0506625 MPa) or less than about 1 atm (0.101325 MPa). In the case of a working fluid operating in an open cycle, the low pressure limit can be about 1 atm (0.101325 MPa) or equal to the ambient pressure.
[052] In some cases, the low pressure limit value may be selected based on the desired energy output and / or the energy input requirements of the thermodynamic cycle. For example, a pumped thermal system with a low pressure limit of about 10 atm (1.01325 MPa) may be able to provide an energy output comparable to that of an industrial gas turbine with ambient air inlet (1 atm) (0.101325 MPa). The low pressure limit value may also be subject to compensatory cost / safety changes. In addition, the value of the low pressure limit can be limited by the value of the high pressure limit, the operating ranges of the heat storage media on the hot and cold sides (for example, pressure and temperature ranges in which the heat storage media are stable), pressure ratios and operating conditions (eg operating limits, ideal operating conditions, pressure drop) achievable by turbomachinery and / or other system components, or any combination thereof. The high blood pressure limit can be determined according to
Petition 870190103250, of 10/14/2019, p. 23/149
17/114 these system restrictions. In some instances, higher values of the high pressure limit may result in improved heat transfer between the working fluid and the hot-side storage medium.
[053] Working fluids used in pumped thermal systems may include air, argon, other noble gases, carbon dioxide, hydrogen, oxygen or any combination thereof, and / or other fluids in a gaseous, liquid, critical or supercritical state (eg example, supercritical CO2). The working fluid can be a gas or a liquid of low viscosity (for example, viscosity below about 500x10 ⁶ Poise in 1 atm (0.101325 MPa)), satisfying the requirement that the flow be continuous. In some implementations, a gas with a high specific heat ratio can be used to achieve higher cycle efficiency than a gas with a low specific heat ratio. For example, argon (for example, a specific heat ratio of about 1.66) can be used to replace air (for example, a specific heat ratio of about 1.4). In some cases, the working fluid may be a mixture of one, two, three or more fluids. In one example, helium (having a high thermal conductivity and high specific heat) can be added to the working fluid (eg, argon) to improve heat transfer rates in heat exchangers.
[054] Thermal systems pumped in this document may use heat storage media or materials, such as one or more heat storage fluids. The heat storage media can be low viscosity gases or liquids, satisfying the requirement that the flow
Petition 870190103250, of 10/14/2019, p. 24/149
18/114 is continuous. Systems can use a first heat storage medium on a hot side of the system (HTS thermal storage medium (HTS) or HTS in this document) and a second heat storage medium on a cold side of the system (heating medium) cold-side thermal storage (CTS) or CTS in this document). Thermal storage media (for example, low viscosity liquids) can have high heat capacities per unit volume (for example, heat capacities above about 1,400 Joules (kilogram Kelvin) ^x ) and high thermal conductivities (for example , thermal conductivities above about 0.7 Watt (Kelvin meter) ^x ). In some implementations, several different thermal storage media (also heat storage media in this document) on either side of the hot side, the cold side or both of the hot side and the cold side can be used.
[055] The operating temperatures of the hot side thermal storage medium may be in the liquid range of the hot side thermal storage medium, and the operating temperatures of the cold side thermal storage medium may be in the liquid range of the hot side. cold-side thermal storage medium. In some instances, liquids can enable a faster exchange of large amounts of heat through convective countercurrent than can solids or gases. Thus, in some cases, liquid HTS and CTS media can advantageously be used. Pumped thermal systems using thermal storage media in this document can advantageously provide an alternative energy storage (eg
Petition 870190103250, of 10/14/2019, p. 25/149
19/114 example, electricity) safe, non-toxic and independent of geography.
[05 6] In some implementations, the hot-side thermal storage medium may be a molten salt or a mixture of molten salts. Any salt or mixture of salts that is liquid within the operating temperature range of the hot-side thermal storage medium can be employed. Molten salts can provide numerous advantages as a means of storing thermal energy, such as low vapor pressure, are devoid of toxicity, chemical stability, low chemical reactivity with typical steels (eg melting point below the creep temperature of steels, low corrosivity, low capacity to dissolve iron and nickel) and low cost. In one example, HTS is a mixture of sodium nitrate and potassium nitrate. In some instances, HTS is a eutectic mixture of sodium nitrate and potassium nitrate. In some examples, HTS is a mixture of sodium nitrate and potassium nitrate having a lower melting point than those of the individual components, a higher boiling point than those of the individual components or a combination thereof. Other examples include potassium nitrate, calcium nitrate, sodium nitrate, sodium nitride, lithium nitrate, mineral oil or any combination thereof. Additional examples include any gaseous media (including compressed gases), liquids or solids (eg, pulverized solids) having adequate thermal storage capacities (eg, high) and / or capable of achieving adequate heat transfer rates (eg, high) with
Petition 870190103250, of 10/14/2019, p. 26/149
11/204 working fluid. For example, a mixture of 60% sodium nitrate and 40% potassium nitrate (also referred to as a solar salt in some situations) can have a thermal capacity of approximately 1,500 Joules (Kelvin mol) ¹ and a thermal conductivity of approximately 0.75 Watt (Kelvin meter) ¹ within a temperature range of interest. The hot-side thermal storage medium can be operated in a temperature range that structural steels can handle.
[057] In some cases, liquid water at temperatures of about 0 ° C to 100 ° C (about 273 K-373 K) and a pressure of about 1 atm (0.101325 MPa) can be used as the medium of cold-side thermal storage. Because of a risk of possible explosion associated with the presence of steam at or near the boiling point of water, the operating temperature can be maintained below about 100 ° C or less while maintaining an operating pressure of 1 atm ( that is, without pressurization). In some cases, the operating temperature range of the cold-side thermal storage medium may be extended (for example, to -30 ° C to 100 ° C in 1 atm (0.101325 MPa)) when using a water mixture and one or more antifreeze compounds (for example, ethylene glycol, propylene glycol or glycerol).
[058] As described in more detail elsewhere in this document, improved storage efficiency can be achieved by increasing the temperature difference at which the system operates, for example, by using a cold-side heat storage fluid capable of operate at lower temperatures. In some instances,
Petition 870190103250, of 10/14/2019, p. 27/149
21/114 cold-side thermal storage media may comprise hydrocarbons, such as, for example, alkanes (for example, hexane or heptane), alkenes, alkynes, aldehydes, ketones, carboxylic acids (for example, HCOOH), ethers, cycloalkanes , aromatic hydrocarbons, alcohols (for example, butanol), other type (s) of hydrocarbon molecules, or any combination thereof. In some cases, the cold-side thermal storage medium may be hexane (for example, n-hexane). Hexane has a wide liquid range and can remain fluid (ie liquid) in its total liquid range (-94 ° C to 68 ° C in 1 atm (0.101325 MPa)). Low temperature properties of hexane are aided by its immiscibility with water. Other liquids such as, for example, ethanol or methanol may become viscous at the low temperature ends of their liquid ranges because of pre-crystallization of water absorbed from the air. In some cases, the cold-side thermal storage medium may be heptane (for example, n-heptane). Heptane has a wide liquid range and can remain fluid (ie liquid) in its total liquid range (-91 ° C to 98 ° C in 1 atm (0.101325 MPa)). Low temperature properties of heptane are helped by its immiscibility with water. Even at lower temperatures, other heat storage media can be used, such as, for example, isohexane (2-methylpentane). In some examples, cryogenic liquids having a boiling point below about -150 ° C (123 K) or about -180 ° C (93.15 K) can be used as cold-side thermal storage media (for example, propane, butane, pentane, nitrogen, helium, neon,
Petition 870190103250, of 10/14/2019, p. 28/149
22/114 argon and krypton, air, hydrogen, methane, or liquefied natural gas). In some implementations, choice of cold-side thermal storage medium may be limited by the choice of working fluid. For example, when a gaseous working fluid is used, a liquid cold-side thermal storage medium having a range of liquid temperatures at least partially or substantially above the boiling point of the
job can be required. [059] In some cases, the banner of temperatures in operation in means CTS and / or HTS can be changed to pressurize ( this is, raise the pressure) or relieve (this is, decrease the pressure) the tanks and change so the temperature in which the means of storage are submitted at
phase transitions (for example, going from liquid to solid, or from liquid to gas).
[060] In some cases, the cold-side and hot-side heat storage fluids of the pumped thermal systems are in a liquid state in at least part of the operating temperature range of the energy storage device. The hot-side heat storage fluid can be liquid within a given temperature range. Similarly, the cold-side heat storage fluid can be liquid within a given temperature range. Heat storage fluids can be heated, cooled or maintained to achieve an appropriate operating temperature before, during or after operation.
[061] Thermal systems pumped from the development can operate in cycles between loaded and unloaded modes. In
Petition 870190103250, of 10/14/2019, p. 29/149
23/114 some examples, pumped thermal systems can be fully charged, partially charged or partially discharged, or fully discharged. In some cases, cold side heat storage can be loaded (also reloaded in this document) regardless of the hot side heat storage. Additionally, in some implementations, loading (or some part of it) and unloading (or some part of it) can occur simultaneously. For example, a first part of a hot side heat storage can be recharged while a second part of the hot side heat storage together with a cold side heat storage is being discharged.
[062] Pumped thermal systems may be able to store energy for a given amount of time. In some cases, a given amount of energy can be stored for at least about 1 second, at least about 30 seconds, at least about 1 minute, at least about 5 minutes, at least about 30
minutes at least about 1 hour, fur any less fence in 2 hours at least about 3 hours, fur any less fence in 4 hours at least about 5 hours, fur any less fence in 6 hours at least about 7 hours, fur any less fence in 8 hours at least about 9 hours, fur any less fence in 10 hours at least about 12 hours, fur any less fence in 14 hours at least about 16 hours, fur any less fence in 18 hours at least about 20 hours, fur any less fence in 22 hours at least about 24 hour s (1 day) , fur any less about 2 days at least fence of 4 days, fur any less
Petition 870190103250, of 10/14/2019, p. 30/149
24/114 about 6 days, at least about 8 days, at least about 10 days, 20 days, 30 days, 60 days, 100 days, 1 year or more.
[063] Thermal systems pumped from the revelation may be able to store / receive input and / or extract / supply output of a substantially large amount of energy and / or energy for use with power generation systems (eg power generation systems) intermittent energy such as wind or solar energy), energy distribution systems (eg, power grid), and / or other loads or uses in grid or autonomous scale configurations. During a charging mode of a pumped thermal system, electrical energy received from an external power source (for example, a wind power system, a solar photovoltaic system, a power grid, etc.) can be used to operate the system. thermal system pumped in a heat pump mode (that is, transferring heat from a low temperature reservoir to a high temperature reservoir, thus storing energy). During a pumped thermal system discharge mode, the system can supply electrical energy to a power system or external load (for example, one or more electrical networks connected to one or more loads, a load, such as a factory or a process energy intensive, etc.) when operating in a thermal engine mode (ie, transferring heat from a high temperature reservoir to a low temperature reservoir, thereby extracting energy). As described elsewhere in this document, during loading and / or unloading, the system may receive or reject thermal energy, including, but not limited to,
Petition 870190103250, of 10/14/2019, p. 31/149
25/114 not limited to this, electromagnetic energy (for example, solar radiation) and thermal energy (for example, sensitive energy from a medium heated by solar radiation, combustion heat, etc.).
[064] In some implementations, pumped thermal systems are synchronized in loops. Synchronization can be achieved by matching the speed and frequency of motors / generators and / or turbomachinery of a system with the frequency of one or more grid networks with which the system exchanges energy. For example, a compressor and a turbine can rotate at a given fixed speed (for example, 3,600 revolutions per minute (rpm)) which is a multiple of mains frequency (for example, 60 hertz (Hz)). In some cases, a configuration like this can eliminate the need for additional power electronics. In some implementations, turbomachinery and / or engines / generators are not synchronous in mesh. In such cases, frequency matching can be performed by using power electronics. In some implementations, the turbomachinery and / or motors / generators are not directly synchronized in mesh, but can be matched by the use of gears and / or a mechanical gearbox. As described in more detail elsewhere in this document, pumped thermal systems may also be capable of jumping. Such capabilities can enable these mesh-scale energy storage systems to operate as peak power plants and / or as a load following power plants. In some cases, development systems may be able to operate as base-load power plants.
Petition 870190103250, of 10/14/2019, p. 32/149
26/114 [065] Pumped thermal systems can have a given energy capacity. In some cases, energy capacity during charging may differ from energy capacity during discharge. For example, each system can have a load and / or discharge power capacity of less than about 1 megawatt (MW), at least about 1 megawatt, at least about 2 MW, at least about 3 MW, at least about 4 MW, at least about 5 MW, at least about 6 MW, at least about 7 MW, at least about 8 MW, at least about 9 MW, at least about 10 MW, at least at least about 20 MW, at least about 30 MW, at least about 40 MW, at least about 50
MW, at least about 75 MW, at least about 100 MW, at least about 200 MW, at least about 500 MW, at least about 1 gigawatt (GW), at least about 2 GW, at least about 5 GW, at least about 10 GW, at least about 20 GW, at least about 30 GW, at least about 40 GW, at least about 50 GW, at least about 75 GW, at least about 100 GW or more.
[066] Pumped thermal systems can have a given energy storage capacity. In one example, a pumped thermal system is configured as a 100 MW unit operating for 10 hours. In another example, a pumped thermal system is configured as a 1 GW installation operating for 12 hours. In some instances, the energy storage capacity may be less than about 1 megawatt hour (MWh), at least about 1 megawatt hour, at least about 10 MWh, at least about 100 MWh, at least about 1 gigawatt hour (GWh), at least about 5 GWh, at least about 10 GWh, at least
Petition 870190103250, of 10/14/2019, p. 33/149
11/274
any less fence of 2 0 GWh, at least ! 50 GWh, fur any less fence in 100 GWh, fur any less fence in 200 GWh, fur any less fence in 500 GWh, fur any less fence in 700 GWh, fur any less fence
1,000 GWh, or more.
[067] In some cases, a given energy capacity can be achieved with a given size, configuration and / or operating conditions of the thermal motor / heat pump cycle. For example, the size of turbomachinery, ducts, heat exchangers or other system components can correspond to a given energy capacity.
[068] In some implementations, a given energy storage capacity can be achieved with a given size and / or number of thermal storage tanks on the hot side and / or thermal storage tanks on the cold side. For example, the thermal motor / heat pump cycle can operate at a given energy capacity for a given amount of time established by the heat storage capacity of the system or installation. The number and / or heat storage capacity of the hot-side thermal storage tanks may differ from the number and / or heat storage capacity of the cold-side thermal storage tanks. The number of tanks may depend on the size of individual tanks. The size of the hot-side storage tanks may differ from the size of the cold-side thermal storage tanks. In some cases, the hot-side thermal storage tanks, the hot-side heat exchanger and the hot-side thermal storage medium may be referred to as a hot-side (thermal) heat storage unit. In some cases, storage tanks
Petition 870190103250, of 10/14/2019, p. 34/149
28/114 cold side thermal storage, cold side heat exchanger and cold side thermal storage medium can be referred to as a cold side (thermal) heat storage unit.
[069] A pumped thermal storage facility can include any suitable number of hot-side storage tanks, such as at least about 2, at least about 4, at least about 10, at least about 50, at least about 100, at least about 500, at least about 1,000, at least about 5,000, at least about 10,000 and more. In some examples, a pumped thermal storage facility includes 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, 50, 60, 70, 80, 90, 100, 200 , 300, 400, 500, 600, 700, 800, 900, 1,000 or more hot-side tanks.
[070] A pumped thermal storage facility may also include any suitable number of cold-side storage tanks, such as at least about 2, at least about 4, at least about 10, at least about 50, at least at least about 100, at least about 500, at least about 1,000, at least about 5,000, at least about 10,000, and more. In some examples, a pumped thermal storage facility includes 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, 50, 60, 70, 80, 90, 100, 200 , 300, 400, 500, 600, 700, 800, 900, 1,000 or more cold side tanks.
Pumped Thermal Storage Cycles [071] One aspect of the disclosure concerns pumped thermal systems operating in pumped thermal storage cycles. In some examples, cycles allow
Petition 870190103250, of 10/14/2019, p. 35/149
29/114 that electricity is stored as heat (for example, in the form of a temperature differential) and then converted back to electricity by using at least two parts of turbomachinery, a compressor and a turbine. The compressor consumes work and raises the temperature and pressure of a working fluid (WF). The turbine produces work and lowers the temperature and pressure of the working fluid. In some instances, more than one compressor and more than one turbine are used. In some cases, the system may include at least 1, at least 2, at least 3, at least 4 or at least 5 compressors. In some cases, the system may include at least 1, at least 2, at least 3, at least 4 or at least 5 turbines. The compressors can be arranged in series or in parallel. The turbines can be arranged in series or in parallel.
[072] Figures 2 and 3 are schematic flow diagrams of working fluid and heat storage media for an exemplary pumped thermal system in a load / heat pump mode and a discharge / thermal engine mode, respectively . The system can be designed for simplicity of explanation so that there are no losses (ie, entropy generation) in the turbomachinery or heat exchangers. The system can include a working fluid 20 (for example, argon gas) flowing in a closed cycle between a compressor 1, a hot side heat exchanger 2, a turbine 3 and a cold side heat exchanger 4. Paths / fluid flow directions for working fluid 20 (for example, a gas), a hot-side thermal storage medium
Petition 870190103250, of 10/14/2019, p. 36/149
30/114 (HTS) 21 (for example, a low viscosity liquid) and for a cold side thermal storage medium (CTS) 22 (for example, a low viscosity liquid) are
indicated by arrows • [073] The figures 4 and 5 are diagrams schematic in pressure and temperature of the fluid working 20 to measure what he is subjected to cycles in charge on figures 2 and 3,
respectively, again simplified in approaching no generation of entropy. Normalized pressure is shown on the y axes and temperature is shown on the x axes. The direction of processes taking place during cycles is indicated with arrows, and the individual processes taking place in compressor 1, hot side CFX 2, turbine 3 and cold side CFX 4 are indicated in the diagram with their respective numbers.
[074] Heat exchangers 2 and 4 can be configured as countercurrent heat exchangers (CFXs), where the working fluid flows in one direction and the substance with which it is exchanging heat is flowing in the opposite direction. In an ideal countercurrent heat exchanger with correctly matched flows (that is, capacities or flow rates of balanced capacities), the temperatures of the working fluid and the thermal storage medium reverse (that is, the countercurrent heat exchanger can have unit effectiveness).
[075] Countercurrent heat exchangers 2 and 4 can be designed and / or operated to reduce the generation of entropy in the heat exchangers to negligible levels when compared to the entropy generation associated with
Petition 870190103250, of 10/14/2019, p. 37/149
31/114 other system components and / or processes (eg compressor and / or turbine entropy generation). In some cases, the system can be operated in such a way that generation of entropy in the system is minimized. For example, the system can be operated in such a way that generation of entropy associated with heat storage units is minimized. In some cases, a temperature difference between fluid elements exchanging heat can be controlled during operation in such a way that generation of entropy in hot and cold side heat storage units is minimized. In some instances, the entropy generated in the hot and cold side heat storage units is negligible when compared to the entropy generated by the compressor, the turbine, or both of the compressor and the turbine. In some instances, generation of entropy associated with heat transfer in heat exchangers 2 and 4 and / or generation of entropy associated with operation of the hot side storage unit, the cold side storage unit, or both heat storage units hot side and cold side can be less than about 50%, less than about 25%, less than about 20%, less than about 15%, less than about 10%, less than about 5%, less than about 4%, less than about 3%, less than about 2%, or less than about 1% of the total entropy generated within the system (for example, entropy generated by compressor 1, the heat exchanger of hot side 2, the turbine 3, the cold side heat exchanger 4 and / or other components described in this document, such as, for example, a stove). For example, entropy generation can be reduced or
Petition 870190103250, of 10/14/2019, p. 38/149
32/114 minimized if the two substances exchanging heat do so in a local temperature differential ΔΤ -> 0 (that is, when the temperature difference between any two fluid elements that are in closed thermal contact in the heat exchanger is small). In some examples, the temperature differential ΔΤ between any two fluid elements that are in close thermal contact can be less than about 300 Kelvin (K) (26, 85 ° C), less than about 200 K (-73.15 ° C), less than about 100 K (-173.15 ° C), less than about 75 K (-198.15 ° C), less than about 50 K (-223.15 ° C), less at about 40 K (-233.15 ° C), less than about 30 K (-243.15 ° C), less than about 20 K (-253.15 ° C), less than about 10 K (-263, 15 ° C), less than about 5 K (-268.15 ° C), less than about 3 K (-270.15 ° C), less than about 2 K (-271.15 ° C) or less than about 1 K (-272.15 ° C). In another example, the generation of entropy associated with pressure drop can be reduced or minimized through proper design. In some instances, the heat exchange process can take place at constant or near constant pressure. Alternatively, a negligible pressure drop can be felt by the working fluid and / or by one or more means of thermal storage during passage through a heat exchanger. Pressure drop in heat exchangers can be controlled (for example, reduced or minimized) through proper heat exchanger design. In some instances, the pressure drop across each heat exchanger may be less than about 20% of the inlet pressure, less than about 10% of the inlet pressure, less than about 5% of the inlet pressure
Petition 870190103250, of 10/14/2019, p. 39/149
33/114 inlet, less than about 3% of the inlet pressure, less than about 2% of the inlet pressure, less than about 1% of the inlet pressure, less than about 0.5% of the inlet pressure , less than about 0.25% of the inlet pressure, or less than about 0.1% of the inlet pressure.
[07 6] When entering the heat exchanger 2, the temperature of the working fluid may increase (receiving heat from the HTS 21 medium, corresponding to the discharge mode in figures 3 and 5) or decrease (giving heat to the HTS 21 medium, corresponding to the charging mode in figures 2 and 4), depending on the temperature of the HTS medium in the heat exchanger relative to the temperature of the working fluid. Similarly, when entering the heat exchanger 4, the temperature of the working fluid may increase (receiving heat from the CTS 22 medium, corresponding to the load mode in figures 2 and 4) or decrease (giving heat to the CTS 22 medium, corresponding to the discharge mode in figures 3 and 5), depending on the temperature of the CTS medium in the heat exchanger relative to the temperature of the working fluid.
[077] As described in more detail with reference to the charging mode in figures 2 and 4, the process of adding heat to the cold side CFX 4 can take place in a different temperature range than the process of removing heat in the Hot-side CFX 2. Similarly, in the discharge mode in figures 3 and 5, the heat rejection process on the cold-side CFX 4 can occur in a different temperature range than the heat-adding process in the CFX of hot side 2. At least part of the temperature ranges of the hot-side and cold-side heat exchange processes can overlap
Petition 870190103250, of 10/14/2019, p. 40/149
34/114 during loading, during unloading, or during both loading and unloading.
[078] As used in this document, the temperatures To, Ti, To ⁺ and Ti ⁺ are so named because To ⁺ , Ti ⁺ are the temperatures reached at the outlet of a compressor with a given compression ratio r, adiabatic efficiency η ₀ and input temperatures of To, Ti respectively. The examples in figures 2, 3, 4 and 5 can be idealized examples where η ₀ = 1 and where adiabatic efficiency of turbine r] t also has the value r] _c = 1.
[07 9] With reference to the load mode shown in figures 2 and 4, the working fluid 20 can enter compressor 1 in position 30 at a pressure P and a temperature T (for example, with Τι, P2). As the working fluid passes through the compressor, the work Wi is consumed by the compressor to increase the pressure and temperature of the working fluid (for example, for Ti ⁺ , Pi), as indicated by Pt and Tf at position 31. In load mode, the Ti ⁺ temperature of the working fluid leaving the compressor and entering the hot side CFX 2 at position 31 is higher than the temperature of the HTS 21 medium entering the hot side CFX 2 at position 32 from one second hot-side thermal storage tank 7 at a To ⁺ temperature (ie, To ⁺ <Ti ⁺ ). As these two fluids pass in thermal contact with each other in the heat exchanger, the temperature of the working fluid decreases as it moves from position 31 to position 34, giving heat Qi to the HTS medium, while the temperature of the HTS medium in turn increases as it moves from position 32 to position 33, absorbing the heat Qi from the
Petition 870190103250, of 10/14/2019, p. 41/149
35/114 work. In one example, the working fluid exits the hot side CFX 2 at position 34 at To ⁺ temperature and the HTS medium exits the hot side CFX 2 at position 33 into a first hot side thermal storage tank 6 at Ti ⁺ temperature. The heat exchange process can take place at a constant or almost constant pressure such that the working fluid exits the hot side CFX 2 in position 34 at a lower temperature, but with the same pressure Pi, as indicated by P and Tj, in position 34. Similarly, the temperature of the HTS 21 medium rises in the hot side CFX 2, while its pressure can remain constant or almost constant.
[080] When exiting the CFX from the hot side 2 in position 34 (for example, with To ⁺ , Pi), the working fluid 20 undergoes expansion in turbine 3 before leaving the turbine in position 35. During expansion, the pressure and working fluid temperature decrease (for example, for To, P2), as indicated by P j, and T j, at position 35. The magnitude of the work W2 generated by the turbine depends on the enthalpy of the working fluid entering the turbine and the degree of expansion. In load mode, heat is removed from the working fluid between positions 31 and 34 (on the hot side CFX 2) and the working fluid is expanded back to the pressure with which it initially entered the compressor at position 30 ( for example, P2). The compression ratio (for example, P1 / P2) in compressor 1 being equal to the expansion ratio in turbine 3, and the enthalpy of gas entering the turbine being less than the enthalpy of gas leaving the compressor, the work W2 generated by the turbine 3 is less than the work Wi consumed by compressor 1 (that is, W2 <Wi).
Petition 870190103250, of 10/14/2019, p. 42/149
36/114 [081] Because of the heat that was removed from the working fluid in the hot side CFX 2, the temperature To with which the working fluid leaves the turbine in position 35 is lower than the temperature Ti with which the working fluid initially entered the compressor at position 30. To close the cycle (ie, to return the pressure and temperature of the working fluid to its initial values Τι, P2 at position 30), heat Q2 is added to the working fluid by means of CTS 22 in the cold side CFX 4 between positions 35 and 30 (that is, between turbine 3 and compressor 1). In one example, the CTS medium 22 enters the cold side CFX 4 at position 36 from a first cold storage thermal tank 8 at temperature Ti and exits the cold side CFX 4 at position 37 into a second tank of cold-side thermal storage 9 at temperature To, while working fluid 20 enters the cold-side CFX 4 at position 35 at temperature To and exits cold-side CFX 4 at position 30 at temperature Ti. Again, the The heat exchange process can take place at a constant or almost constant pressure in such a way that the working fluid exits the cold side CFX 4 in position 30 with a higher temperature, but with the same pressure P2, as indicated by P and Τ ΐ in position 30. Similarly, the temperature of the CTS 22 medium decreases in the cold side CFX 4, while its pressure can remain constant or almost constant.
[082] During loading, heat Q2 is removed from the CTS medium and heat Qi is added to the HTS medium, where Qi> Q2. A net amount of Wi - W2 work is consumed, since the Wi work used by the compressor is greater than the
Petition 870190103250, of 10/14/2019, p. 43/149
37/114 W2 work generated by the turbine. A device that consumes work while shifting heat from a body or cold thermal storage medium to a body or hot thermal storage medium is a heat pump; thus, the thermal system pumped in charge mode operates like a heat pump.
[083] In one example, the discharge mode shown in figures 3 and 5 may differ from the charge mode shown in figures 2 and 4 in the temperatures of the thermal storage media being introduced into the heat exchangers. The temperature at which the HTS medium enters the hot-side CFX 2 at position 32 is Ti ⁺ instead of To ⁺ , and the temperature of the CTS medium entering the cold-side CFX 4 at position 36 is To instead of Ti. During discharge, the working fluid enters the compressor in position 30 with To and P2, leaves the compressor in position 31 with To ⁺ <Ti ⁺ and Pi, absorbs heat from the HTS medium in the hot side CFX 2, enters turbine 3 in position 34 with Ti ⁺ and Pi, leaves the turbine in position 35 with Ti> To and P2, and finally rejects heat to the CTS medium in the cold side CFX 4, returning to its initial state in position 30 with To and P2.
[084] The HTS medium at Ti ⁺ temperature can be stored in a first thermal storage tank on the hot side 6, the HTS medium at temperature To ⁺ can be stored in a second thermal storage tank on the hot side 7, the CTS medium at Ti temperature can be stored in a first thermal storage tank on the cold side
8, and the: medium CTS at temperature To Can be stored in one second tank in storage thermal cold side 9 during both the modes of loading and unloading. In a
Petition 870190103250, of 10/14/2019, p. 44/149
38/114 implementation, the inlet temperature of the HTS medium in position 32 can be switched between Ti ⁺ and To ⁺ when switching between tanks 6 and 7, respectively. Similarly, the inlet temperature of the CTS medium at position 36 can be switched between Ti and To by switching between tanks 8 and 9, respectively. Switching between tanks can be achieved by including a valve or a valve system (for example, valve systems 12 and 13 in figure 7) to switch connections between the hot side heat exchanger 2 and the hot side tanks 6 and 7, and / or between the cold side heat exchanger 4 and the cold side tanks 8 and 9 as needed for loading and unloading modes. In some implementations, connections can be switched on the working fluid side instead, while connections from storage tanks 6, 7, 8 and 9 to heat exchangers 2 and 4 remain static. In some instances, flow paths and connections for heat exchangers may depend on the design (for example, housing and tubes) of each heat exchanger. In some implementations, one or more valves can be used to switch the direction of both the working fluid and the heat storage medium through the countercurrent heat exchanger for loading and unloading. Such configurations can be used, for example, because of the high thermal storage capacities of the heat exchanger component, to decrease or eliminate transient temperature phenomena or a combination thereof. In some implementations, one or more valves can be used to switch the direction of the working fluid only, while the direction of the HTS or CTS can be changed by changing the
Petition 870190103250, of 10/14/2019, p. 45/149
39/114 pumping direction, thereby maintaining the countercurrent configuration. In some implementations, different valve configurations can be used for HTS and CTS. In addition, any combination of valve configurations in this document can be used. For example, the system can be configured to operate using different valve configurations in different situations (for example, depending on system operating conditions).
[085] In the discharge mode shown in figures 3 and 5, working fluid 20 can enter compressor 1 in position 30 at a pressure P and a temperature T (for example, with To, P2) · As the fluid work passes through the compressor, the work Wi is consumed by the compressor to increase the pressure and temperature of the working fluid (for example, for To ⁺ , Pi), as indicated by Pt and Tΐ in position 31. In the discharge mode, the temperature To ⁺ of the working fluid exiting the compressor and entering the CFX on the hot side 2 in position 31 is lower than the temperature of the medium HTS 21 entering the CFX on the hot side 2 in position 32 from a first thermal storage tank of hot side 6 with a Ti ⁺ temperature (ie, To ⁺ <Ti ⁺ ). As these two fluids pass in thermal contact with each other in the heat exchanger, the temperature of the working fluid increases as it moves from position 31 to position 34, absorbing the heat Qi from the HTS medium, while the temperature of the HTS medium in turn decreases as it moves from position 32 to position 33, giving heat Qi to the working fluid. In one example, the working fluid leaves the CFX on its side
Petition 870190103250, of 10/14/2019, p. 46/149
40/114 hot 2 at position 34 at Ti ⁺ temperature and the HTS medium exits the CFX on the hot side 2 at position 33 into the second thermal storage tank 7 at the To ⁺ temperature. The heat exchange process can take place at a constant or almost constant pressure such that the working fluid exits the hot side CFX 2 in position 34 at a higher temperature, but with the same pressure Pi, as indicated by P and T | in position 34. Similarly, the temperature of the HTS 21 medium decreases in the hot side CFX 2, while its pressure can remain constant or almost constant.
[086] When exiting the hot side CFX 2 in position 34 (for example, with Ti ⁺ , Pi), the working fluid 20 undergoes expansion in turbine 3 before leaving the turbine in position 35. During expansion, the pressure and working fluid temperature decrease (for example, for Τι, P2), as indicated by P j, and T j, at position 35. The magnitude of the work W2 generated by the turbine depends on the enthalpy of the working fluid entering the turbine and the degree of expansion. In the discharge mode, heat is added to the working fluid between positions 31 and 34 (on the hot side CFX 2) and the working fluid is expanded back to the pressure with which it initially entered the compressor in position 30 ( for example, P2). The compression ratio (for example, P1 / P2) in compressor 1 being equal to the expansion ratio in turbine 3, and the enthalpy of gas entering the turbine being greater than the enthalpy of gas leaving the compressor, the work W2 generated by the turbine 3 is greater than the work Wi consumed by compressor 1 (that is, W2> Wi).
[087] Because of the heat that was added to the fluid
Petition 870190103250, of 10/14/2019, p. 47/149
41/114 working on the hot side CFX 2, the temperature Τι with which the working fluid leaves the turbine in position 35 is higher than the temperature To with which the working fluid initially entered the compressor in position 30. For close the cycle (that is, to return the working fluid pressure and temperature to their initial values To, P2 at position 30), the heat Q2 is rejected by the working fluid to the CTS 22 medium on the cold side CFX 4 between positions 35 and 30 (that is, between turbine 3 and compressor 1). The CTS medium 22 enters the cold side CFX 4 at position 36 from a second cold storage tank 9 at temperature To and exits the cold side CFX 4 at position 37 into a first thermal storage tank at cold side 8 at Ti temperature, while working fluid 20 enters the cold side CFX 4 at position 35 at Ti temperature and exits cold side CFX 4 at position 30 at temperature To. Again, the heat exchange process can take place at a constant or almost constant pressure in such a way that the working fluid exits the cold side CFX 4 in position 30 at a higher temperature, but with the same pressure P2, as as indicated by P and T j, at position 30. Similarly, the temperature of the CTS medium 22 increases in the cold side CFX 4, while its pressure can remain constant or almost constant.
[088] During discharge, heat Q2 is added to the CTS medium and heat Qi is removed from the HTS medium, where Qi> Q2. A net amount of work W2 - Wi is generated, since the work Wi used by the compressor is less than the work W2 generated by the turbine. A device that generates
Petition 870190103250, of 10/14/2019, p. 48/149
42/114 work while shifting heat from a body or hot thermal storage medium to a body or cold thermal storage medium is a thermal motor; thus, the thermal system pumped in the discharge mode operates like a thermal engine.
[089] Figure 6 is a simplified schematic view in perspective of a closed cycle working fluid system in the thermal system pumped in figures 2-3. As indicated, working fluid 20 (contained within the pipeline) circulates clockwise between compressor 1, hot-side heat exchanger 2, turbine 3 and cold-side heat exchanger 4. Compressor 1 and the turbine 3 can be grouped on a common mechanical axis 10 in such a way that they rotate together. In some implementations, compressor 1 and turbine 3 may have separate mechanical shafts. A motor / generator 11 (for example, including a synchronous motor converter - synchronous generator on a single common axis) provides power to and from the turbomachinery. In this example, the compressor, the turbine and the motor / generator are all placed on a common axis. Tubes in positions 32 and 33 transfer thermal storage fluid from the hot side to and from the heat exchanger 2, respectively. Tubes in positions 36 and 37 transfer thermal storage fluid from the cold side to and from the cold side heat exchanger 4, respectively.
[090] Although the system of figure 6 is illustrated as comprising a compressor 1 and a turbine 3, the system can include one or more compressors and one or more turbines, which can operate, for example, in a
Petition 870190103250, of 10/14/2019, p. 49/149
43/114 parallel configuration, or alternatively in a series configuration or in a combination of parallel and series configurations. In some examples, a compressor or turbine system can be assembled in such a way that a given compression ratio is achieved. In some cases, different compression ratios (for example, loading and unloading) may be used (for example, when connecting or disconnecting, in a parallel and / or serial configuration, one or more compressors or turbines from the compressor system or turbines). In some examples, the working fluid is directed to a plurality of compressors and / or a plurality of turbines. In some instances, the compressor and / or turbine may have temperature-dependent compression ratios. Arrangement and / or operation of the turbomachinery and / or other elements of the system can be adjusted according to the temperature dependence (for example, to optimize performance).
[091] Figure 7 is a simplified schematic view in perspective of the thermal system pumped in figures 2-3 with hot and cold side storage tanks and a closed-loop working fluid system. In this example, the HTS medium is a molten salt and the CTS medium is a low temperature liquid. One, two or more first hot-side tanks 6 (at Ti ⁺ temperature) and one, two or more second hot-side tanks 7 (at To ⁺ temperature), both to retain the HTS medium, are in fluid communication with a valve 13 configured to transfer HTS medium to and from the hot-side heat exchanger 2. One, two or more first cold-side tanks 8 (at Ti temperature) and one, two or more second
Petition 870190103250, of 10/14/2019, p. 50/149
44/114 cold side 9 (at temperature To), both to retain the CTS medium, are in fluid communication with a valve 12 configured to transfer the CTS medium to and from the cold side heat exchanger 4.
[092] Thermal energy storage tanks or tanks can be thermally insulated tanks that can retain an appropriate amount of the relevant thermal storage medium (for example, heat storage fluid). Storage tanks can allow relatively compact storage of large amounts of thermal energy. In one example, hot-side tanks 6 and / or 7 can have a diameter of about 80 meters, while cold-side tanks 8 and / or 9 can have a diameter of about 60 meters. In another example, the size of each thermal storage (ie, hot side or cold side) for a 1 GW facility operating for 12 hours can be about 20 medium-sized oil refinery tanks.
[093] In some implementations, a third set of tanks containing storage media with temperatures intermediate between the other tanks can be included on the hot side and / or on the cold side. In one example, a third tank (or set of tanks) for storage or transfer with an intermediate temperature at the temperatures of a first tank (or set of tanks) and a second tank (or set of tanks) can be provided. A set of valves can be provided to switch the storage media between the different tanks and heat exchangers. For example, thermal media can be directed to different sets of tanks
Petition 870190103250, of 10/14/2019, p. 51/149
45/114 after leaving the heat exchangers depending on conditions and / or the operating cycle being used. In some implementations, one or more additional sets of storage tanks with different temperatures can be added on the hot side and / or the cold side.
[094] Storage tanks (for example, hot-side tanks comprising hot-side thermal storage medium and / or cold-side tanks comprising cold-side thermal storage medium) can operate at ambient pressure. In some implementations, storage of thermal energy at ambient pressure can provide safety benefits. Alternatively, storage tanks can operate at high pressures, such as, for example, at a pressure of at least about 2 atm (0.20265 MPa), at least about 5 atm (0.506625 MPa), at least about 10 atm (1.01325 MPa), at least about 20 atm (2.0265 MPa), or more. Alternatively, storage tanks can operate at reduced pressures, such as, for example, at a pressure of at most about 0.9 atm (0.911925 MPa), at most about 0.7 atm (0.0709275 MPa ), at most about 0.5 atm (0.0506625 MPa), at most about 0.3 atm (0.0303975 MPa), at most about 0.1 atm (0.0101325 MPa), at most about 0.01 atm (0.00101325 MPa), at most about 0.001 atm (0.000101325 MPa), or less. In some cases (for example, when operating at higher / higher or lower pressures or to avoid contamination of the thermal storage media), the storage tanks can be sealed from the surrounding atmosphere. Alternatively, in some cases, storage tanks may not be
Petition 870190103250, of 10/14/2019, p. 52/149
46/114 sealed. In some implementations, tanks may include one or more pressure relief or regulation systems (for example, a valve for safety or system optimization).
[095] As used in this document, the first hot-side tank (s) 6 (at Ti ⁺ temperature) may contain HTS medium at a temperature higher than that of the second (s) (s) hot side tank (s) 7 (at To ⁺ temperature), and the first cold side tank (s) 8 (at Ti temperature) can contain CTS medium at a temperature higher than that of the second cold side tank (s) 9 (at temperature To). During loading, half HTS in the first tank (s) on the hot side (highest temperature) 6 and / or half CTS in the second tank (s) on the cold side (lowest temperature) ) 9 can be reset. During discharge, half HTS in the first tank (s) on the hot side (highest temperature) 6 and / or half CTS in the second tank (s) on the cold side (lowest temperature) ) 9 can be consumed.
[096] In the examples indicated above, in either mode of operation, two of the four storage tanks 6, 7, 8 and 9 are providing thermal storage medium for heat exchangers 2 and 4 at inlets 32 and 36, respectively , and the other two tanks are receiving thermal storage medium from heat exchangers 2 and 4 through outlets 33 and 37, respectively. In this configuration, the feed tanks can contain a storage medium at a given temperature because of previous operating conditions, whereas the temperatures of the feed tanks
Petition 870190103250, of 10/14/2019, p. 53/149
47/114 receipt may depend on current system operation (for example, operating parameters, loads and / or power input). Receiving tank temperatures can be established by Brayton cycle conditions. In some cases, receiving tank temperatures may deviate from desired values because of deviations from predetermined cycle conditions (eg, absolute pressure variation in response to system demand) and / or because of entropy generation within the system. In some cases (for example, because of entropy generation), at least one of the four tank temperatures may be higher than desired. In some implementations, an irradiator can be used to reject or dissipate this residual heat into the environment. In some cases, heat rejection to the environment can be improved (for example, using evaporative cooling, etc.). The residual heat generated during the operation of the thermal systems pumped in this document can also be used for other purposes. For example, residual heat from one part of the system can be used elsewhere in the system. In another example, residual heat can be supplied to an external process or system, such as, for example, a manufacturing process requiring low-grade heat, commercial or residential heating, thermal desalination, commercial drying operations, etc.
[097] Thermal system components pumped from the development may exhibit non-optimal performance, resulting in losses and / or inefficiencies. The biggest losses in the system can occur because of turbomachinery inefficiencies
Petition 870190103250, of 10/14/2019, p. 54/149
48/114 (eg compressor and turbine) and heat exchangers. Losses due to heat exchangers can be small when compared to losses due to turbomachinery. In some implementations, losses due to heat exchangers can be reduced to near zero with adequate design and cost. Therefore, in some analytical examples, losses due to heat exchangers and other possible small losses due to pumps, the motor / generator and / or other factors can be neglected.
[098] Losses due to turbomachinery can be quantified in terms of adiabatic efficiencies η ₀ ei) t (also known as isentropic efficiencies) for compressors and turbines, respectively. For large turbomachinery, typical values can vary between r | c = 0.85 - 0.9 for compressors and i) t = 0.9 - 0.95 for turbines. The actual amount of work produced or consumed by a cycle can then be expressed as. r - w η, w - - wf ^ · '«“ _{ideai ífff} “ _ideai example assuming specific heat constant in the fluid where, in a work, = c _p T _input W - 1), = c _p T _entracla (l _Yl where ψ = rv, r is the compression ratio (that is, the ratio of the highest pressure to the lowest pressure), and γ = Cp / Cv is the ratio of specific heats of the working fluid. Because of compressor inefficiencies and turbine, more work is required to achieve a given compression ratio during compression, and less work is generated during expansion for a given compression ratio. Losses can also be quantified in terms of polytropic or single-stage efficiencies, η _Ο ρ ei) tp,
Petition 870190103250, of 10/14/2019, p. 55/149
49/114 for compressors and turbines respectively.
Polytropic efficiencies are related to adiabatic efficiencies rfjW
r] t by the equations ^- [099] In the examples where
1, pumped thermal cycles of the development can follow identical paths in both loading and unloading cycles (for example, as shown in figures 4 and
5). In the examples where q _c <1 and / or compression in the compressor may result in a temperature increase greater than that in the ideal case for the same compression ratio, and expansion resulting in a temperature decrease in the turbine may be less than that in the ideal case .
[0100] In some implementations, the polytropic efficiency of the q _C p compressor can be at least about 0.3, at least about 0.5, at least about 0.6, at least about 0.7, at least about 0.75, at least about 0.8, at least about 0.85, at least about 0.9, at least about 0.91, at least about 0.92, at least about 0.93, at least about 0.96, or more. In some implementations, the polytropic efficiency of the η _Ρρ compressor can be at least about 0.3, at least about 0.5, at least about 0.6, at least about 0.7, at least about 0.75, at least about 0.8, at least about 0.85, at least about 0.9, at least about 0.91, at least about 0.92, at least about 0, 93, at least about 0.96, at least about 0.97 or more.
[0101] To ⁺ , Ti ⁺ were previously defined as the temperatures reached at the outlet of a compressor with a
Petition 870190103250, of 10/14/2019, p. 56/149
50/114 given compression ratio r, adiabatic efficiency η ₀ and input temperatures of To, Ti respectively. In some examples, these four temperatures are related by the equation - = - =.
[0102] Figure 8 shows an exemplary heat storage load cycle for a water (CTS) / molten salt (HTS) system with η ₀ = 0, 9 and r) t = 0, 95. The dashed lines correspond to η ₀ = r] t = 1 and the continuous lines show the load cycle with r] _t = 0.95 and ry = 0.9. In this example, the CTS medium on the cold side is water, and the HTS medium on the hot side is molten salt. In some cases, the system may include 4 heat storage tanks. In the load cycle, the working fluid in To and P2 can exchange heat with a CTS medium in the cold side heat exchanger 4, so its temperature can increase to Ti (assuming a negligible pressure drop, its pressure can remain P2) . In compressor 1 with η ₀ = 0.9, the temperature and pressure of the working fluid can increase from Τι, P2 to Ti ⁺ , Pi. The working fluid can then exchange heat with an HTS medium in the hot-side heat exchanger 2, in such a way that its temperature can decrease (at constant pressure Pi, assuming a negligible pressure drop). If the working fluid enters turbine 3 with r] t = 0.95 at temperature Tq and expands back to its original pressure P2, its temperature when leaving the turbine may not be To. Instead, the working fluid can enter the turbine at a temperature T _o ⁺ and leave the turbine at temperature To and pressure P2. In some instances, temperatures are
Tq__4 · related by the relation „- ψ '. In some examples, T _o is the temperature at which the working fluid enters a
Petition 870190103250, of 10/14/2019, p. 57/149
51/114 turbine with adiabatic efficiency i) t and compression ratio r in order to come out at temperature To.
[0103] In some implementations, the temperature T _o ⁺ can be incorporated in development charge cycles by first exchanging heat from the working fluid with the HTS medium from Tf to Tf, followed by additionally cooling the working fluid from Tf to Tf , as illustrated by section 38 of the cycle in figure 8.
[0104] Figure 9 shows an exemplary heat storage discharge (extraction) cycle for the molten water / salt system in figure 8 with q _c = 0.9 _and i) t = 0.95. The dashed lines correspond to q _c = qt = 1 and the continuous lines show the load cycle with r] t = 0.95 and he = 0.9. In the discharge cycle, the working fluid in Ti and P2 can exchange heat with a CTS medium in the cold side heat exchanger 4, so its temperature can decrease to To (assuming a negligible pressure drop, its pressure can remain P2) . In compressor 1 with q _c = 0.9, the temperature and pressure of the working fluid can increase from To, P2 to To ⁺ , Pi. The working fluid can then exchange heat with an HTS medium in the hot-side heat exchanger 2, such that its temperature can increase (at constant pressure Pi, assuming a negligible pressure drop). Working fluid entering turbine 3 at Tf may not leave the turbine at temperature Ti as in the load cycle, but instead it can leave at a temperature T _lr where, in some examples, T ₁ = Tfip ~ ^riCp . In some examples, 7] is the temperature at which the working fluid leaves the outlet of a turbine with adiabatic efficiency i) te compression ratio r after entering the
Petition 870190103250, of 10/14/2019, p. 58/149
52/114 turbine at temperature.
[0105] In some implementations, T _± can be incorporated into the development discharge cycles by first cooling the working fluid out of the T to Ti turbine, as illustrated by section 39 of the cycle in figure 9, followed by changing heat of the working fluid with the CTS medium from Ti to To.
[0106] The charge and discharge cycles can be closed by means of additional heat rejection operations in sections 38 (between T _o ⁺ and T _o ⁺ ) and 39 (between T and Ti), respectively. In some cases, closing the cycles by rejecting heat in sections of the cycles where the working fluid can reject heat into the environment at low cost can eliminate the need for additional heat to enter the system. The sections of the cycles where the working fluid can reject heat into the environment can be limited to sections where the temperature of the working fluid is high enough above the ambient temperature for room cooling to be feasible. In some instances, heat may be rejected to the environment in sections 38 and / or 39. For example, heat may be rejected using one or more working fluid radiators for air, intermediate water cooling or various other methods. In some cases, heat rejected in sections 38 and / or 39 can be used for another useful purpose, such as, for example, cogeneration, thermal desalination and / or other examples described in this document.
[0107] In some implementations, cycles can be closed by varying the compression ratios between the loading and unloading cycles, as shown, for example, in
Petition 870190103250, of 10/14/2019, p. 59/149
53/114 figure 10. The ability to vary the compression ratio under loading and unloading can be implemented, for example, by varying the speed of rotation of the compressor and / or the turbine, by means of variable stator pressure control, when deflecting a subset of the compression or expansion stages for loading or unloading by using valves, or when using dedicated compressor / turbine pairs for loading and unloading mode. In one example, the compression ratio in the discharge cycle in figure 9 can be changed in such a way that heat rejection in section 39 is not used, and only heat rejection in section 38 in the load cycle is used. Varying the compression ratio can allow heat to be rejected (i.e., entropy) at a lower temperature, thereby increasing total full cycle efficiency. In some examples of this configuration, the compression ratio under load, rc, can be, and under discharge established in such a way the ratio so that r _D
Where - - ¢ (in some cases, compression temperatures = - higher and Ti can be identical in loading and unloading and heat removal may not be necessary in this part (also leg in this document) of the cycle. In cases, the To ⁺ temperature in charge (for example, Tq ^ = Τοψ ^ ') and the To ⁺ temperature in discharge (for example, = T _o ip _D ^ ^cp ) can be different and heat can be rejected (also dissipated or discharged in this document) into the environment between temperatures T _o ⁺ ^ and T _o ⁺ ^. In an implementation where only the storage media exchange heat with the environment, a heat rejection device (for example, devices 55 and 56 shown in the figure
Petition 870190103250, of 10/14/2019, p. 60/149
54/114
16) can be used to decrease the temperature of the CTS from ₁₀ to ₁₀ between discharge and charge.
[0108] Figure 10 shows an example of a cycle with varying compression ratios. The compression ratio can be higher in discharge (when work is produced by the system) than in load (when work is consumed by the system), which can increase the total full cycle efficiency of the system. For example, during a load cycle 80 with T ₀ ⁺ ^ ^c a compression ratio less than 3 can
be used; during a discharge cycle 81 rp + (d) with 1 _Q , an reason of compression greater than 3 can be used. At higher temperatures achieved in both the cycles 80 and 81 can be and Tf, and excess heat can not to be rejected. [0109] The reason for compression can be varied between
loading and unloading in such a way that the heat dissipation necessary for the environment to close the cycle in both loading and unloading occurs between temperatures (the temperature of the working fluid before entering the turbine during the loading cycle) and (a working fluid temperature as it leaves the compressor in discharge) and not above the Ti temperature (the temperature of the working fluid before entering the compressor under load and / or leaving the turbine in discharge). In some instances, no heat is rejected at a temperature above the lowest temperature in the HTS medium.
[0110] In the absence of system losses and / or inefficiencies, such as, for example, in the case of pumped thermal systems comprising heat pump (s) and thermal motor (s) operating at zero creation limit
Petition 870190103250, of 10/14/2019, p. 61/149
55/114 entropy / isentropic, a given amount of heat Qh can be transferred using a given amount of work W in heat pump (load) mode, and the same Qh can be used in thermal engine (discharge) mode to produce the same IV work, resulting in a full unit cycle efficiency (ie 100%). In the presence of system losses and / or inefficiencies, efficiencies of complete cycles of pumped thermal systems can be limited by how much the components differ from optimal performance.
[0111] The complete cycle efficiency of a pumped thermal system can be defined as h storage ⁼ l ^ extraction | / | j ^ car5a |. _{a few} examples, with an ideal heat exchange approach, the full cycle efficiency can be derived by considering the net work produced during the discharge cycle, fl'K-vI ^{= -} and the net work introduced during the discharge cycle load, ΡΚτ · I ⁼ - using the work and temperature equations given above.
[0112] Efficiencies of complete cycles can be calculated for different configurations of pumped thermal systems (for example, for different classes of thermal storage media) based on the efficiencies of turbomachinery components, q _c and qt.
[0113] In an example, figure 11 shows complete cycle efficiency curves for a water / salt system, such as, for example, the water / salt system in figures 8 and 9 with To = 273 K (0 ° C), Ti = 373 K (100 ° C) and a compression ratio of r = 5.65 chosen to achieve compatibility with the salt (s) on the hot side. Efficiency curves of exemplary complete cycles at values of
Petition 870190103250, of 10/14/2019, p. 62/149
56/114 storage of 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80% 6 90% are shown as a function of the component efficiencies q _{c and} i) t on the x and y axes, respectively . The symbols © and 0 represent the approximate range of adiabatic efficiency values of large turbomachinery present. The dashed arrow represents the direction of increased efficiency.
[0114] Figure 12 shows full cycle efficiency curves for a cooler salt / storage system, such as, for example, a hexane / salt system with a gas-gas heat exchanger in figures 13, 14, 17 and 18 with To = 194 K (-79 ° C), Ti = 494 K (221 ° C) and a compression ratio of r = 3.28. Efficiency curves of exemplary complete cycles at storage values of 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80% and 90% are shown as a function of the component efficiencies q _c and i ) t on the x and y axes, respectively. The symbols © and 0 represent the approximate range of adiabatic efficiency values of large turbomachinery present. As discussed in detail elsewhere in this document, using hexane, heptane and / or another CTS medium capable of low temperature operation can result in significant improvements in system efficiency.
Pumped Thermal Recovery Cycles With Recovery [0115] Another aspect of the disclosure concerns pumped thermal systems with recovery. In some situations, the terms regeneration and recovery may be used interchangeably, however they may have different meanings. As used in this document, the terms recovery and recovery in general
Petition 870190103250, of 10/14/2019, p. 63/149
57/114 refer to the presence of one or more additional heat exchangers where the working fluid exchanges heat with itself during different segments of a thermodynamic cycle by means of continuous heat exchange without intermediate thermal storage. The full cycle efficiency of pumped thermal systems can be substantially improved if the permissible temperature ranges of the storage materials can be extended. In some implementations, this can be achieved by choosing a material or medium on the cold side that can go below 273 K (0 ° C). For example, a CTS medium (eg hexane) with a low temperature limit of approximately To = 17 9 K (-94 ° C) can be used in a system with a molten salt HTS medium. However, T _o ⁺ (ie, the lowest temperature of the working fluid in the hot side heat exchanger) in some compression ratios (for example, modest) may be below the freezing point of the molten salt, making the salt fused as HTS medium. In some implementations, this can be resolved by including a working fluid to working fluid heat exchanger (for example, gas-gas) (also recovered in this document) in the cycle.
[0116] Figure 13 is a schematic flow diagram of working fluid and heat storage media from a thermal system pumped in a load / heat pump mode with a gas-gas heat exchanger 5 for the fluid of work. The use of the gas-to-gas heat exchanger may enable the use of a cooler heat storage medium on the cold side of the system. The working fluid can be air.
Petition 870190103250, of 10/14/2019, p. 64/149
58/114 working fluid can be dry air. The working fluid can be nitrogen. The working fluid can be argon. The working fluid can be a mixture primarily of argon mixed with another gas such as helium. For example, the working fluid can comprise at least about 50% argon, at least about 60% argon, at least about 70% argon, at least about 80% argon, at least about 90 % argon, or about 100% argon, with the rest of helium.
[0117] Figure 17 shows a heat storage load cycle for the storage system in figure 13 with a cold side storage medium (eg liquid hexane) capable of cooling to approximately 17 9 K (-94 °) C) and a molten salt as the hot side storage, and η ₀ = 0.9 and r) t = 0.95. The CTS medium can be hexane or heptane and the HTS medium can be molten salt. In some cases, the system may include four heat storage tanks.
[0118] In an implementation, during loading in figures 13 and 17, the working fluid enters the compressor in Ti and 2, leaves the compressor in Ti ⁺ and Pi, rejects the heat Qi for the HTS 21 medium in the CFX on the side hot 2, leaves the CFX hot side 2 in Ti and Pi, rejects the heat Qrecup (also Qregen in this document, as shown, for example, in the accompanying drawings) for the cold side (low pressure) working fluid in heat exchanger or stove 5, leaves stove 5 in To ⁺ and Pi, rejects heat to the environment (or to another heat sink) in section 38 (for example, a radiator), enters turbine 3 in T _o ⁺ e Pi, get out
Petition 870190103250, of 10/14/2019, p. 65/149
59/114 of the turbine in To and P2, absorbs heat Q2 from the CTS 22 medium in the cold side CFX 4, leaves the cold side CFX 4 in To ⁺ and P2, absorbs the heat Qrecup from the hot side working fluid ( high pressure) in the heat exchanger or stove 5, and finally leaves stove 5 in Ti and P2, returning to its initial state before entering the compressor.
[0119] Figure 14 is a schematic flow diagram of working fluid and heat storage media for the thermal system pumped in figure 13 in a thermal engine / discharge mode. Again, the use of the gas-to-gas heat exchanger may enable the use of cooler heat storage fluid (CTS) and / or cooler working fluid on the cold side of the system.
[0120] Figure 18 shows a heat storage discharge cycle for the storage system in figure 14 with a cold side storage medium (eg liquid hexane) capable of cooling to 179 K (-94 ° C) and a molten salt as the hot side storage, er) c = 0.9 and i) t = 0.95. Again, the CTS medium can be hexane or heptane and the HTS medium can be molten salt, and the system can include 4 heat storage tanks.
[0121] During discharge in figures 14 and 18, the working fluid enters the compressor at To and P2, exits the compressor at To ⁺ and Pi, absorbs Qrecup heat from the cold (low pressure) working fluid at the exchanger or stove 5, leaves stove 5 in Ti and Pi, absorbs heat Qi from HTS 21 medium in hot side CFX 2, leaves hot side CFX 2 in Ti ⁺ and Pi, enters turbine 3 in Ti ⁺ and Pi, leaves the turbine in T _± and P2, rejects heat to the environment (or to another heat sink) in section 39
Petition 870190103250, of 10/14/2019, p. 66/149
60/114 (for example, a radiator), rejects heat Qrecup for the hot side working fluid (of high pressure) in the heat exchanger or stove 5, enters the cold side CFX 4 in To ⁺ and P ₂ , rejects heat Q ₂ for the CTS 22 medium in the cold side CFX 4, and finally exits the cold side CFX 4 in To and P ₂ , returning to its initial state before entering the compressor.
[0122] In another implementation, shown in figure 15, the load cycle remains the same as in figures 13 and 17, except that the working fluid leaves the stove 5 in T _o ⁺ and Pi (instead of in To ⁺ e Pi as in figures 13 and 17), enters turbine 3 at To ⁺ and Pi, exits the turbine at To and P2, absorbs heat Q ₂ from the CTS 22 medium having a temperature T _o ⁺ (instead of at To ⁺ as in figures 13 and 17) in the cold side CFX 4, and exits the cold side CFX 4 in To ⁺ and P2 (instead of in To ⁺ and P2 as in figure 13) before re-entering the stove 5. The heat between the To ⁺ and To ⁺ temperatures is no longer discharged from the working fluid directly into the environment (as in section 38 in figures 13 and 17).
[0123] During discharge in figure 16, the discharge cycle remains the same as in figures 14 and 18, except that the temperature of the HTS medium being stored in tank 7 is changed. The working fluid leaves the stove 5 in 7 ^ and Pi (instead of in Ti and Pi as in figures 14 and 18) and absorbs the heat Qi from the HTS 21 medium in the hot side CFX 2. The HTS medium leaves the Hot-side CFX 2 having a temperature T _± (instead of Ti as in figures 14 and 18). The working fluid then leaves the CFX hot side 2 in Ti ⁺ and Pi, enters turbine 3 in Ti ⁺ and Pi, and leaves the turbine in 7 and P ₂ before re-entering the stove 5. Heat
Petition 870190103250, of 10/14/2019, p. 67/149
61/114 between temperatures T _± e is no longer discharged from the working fluid directly into the environment (as in section 39 in figures 14 and 18). As in figure 14, the CTS medium enters tank 8 at temperature To ⁺ .
[0124] After the discharge in figure 16, in preparation for the charge in figure 15, heat exchange with the environment can be used to cool the HTS 21 medium from the temperature T _± used in the discharge cycle to the temperature Ti used in the cycle of cargo. Similarly, heat exchange with the environment can be used to cool the CTS 22 medium from the temperature To ⁺ used in the discharge cycle to the temperature T _o ⁺ used in the charge cycle. Unlike the configuration in figures 13 and 14, where the working fluid may need to reject a substantial amount of heat (in sections 38 and 39, respectively) at a high rate, in this configuration, the hot-side and cold side can be cooled at an arbitrarily low rate (for example, by radiating or by other means of releasing heat to the environment).
[0125] As shown in figure 16, in some implementations, heat can be rejected from the CTS medium into the environment by circulating the CTS medium in tank 8 in a heat rejection device 55 that can absorb heat from the CTS medium and reject heat to the environment until the CTS medium cools from temperature T _o ⁺ to temperature T _o ⁺ . In some cases, the heat rejection device 55 may be, for example, a radiator, a thermal bath containing a substance such as water or salt water, or a device immersed in a natural body of water such as a lake, river or Ocean. In some instances, the
Petition 870190103250, of 10/14/2019, p. 68/149
62/114 heat rejection 55 can also be an air-cooling device, or a series of tubes that are thermally connected to a solid reservoir (for example, tubes embedded in the earth).
[0126] Similarly, in some implementations, heat can be rejected from the HTS medium into the environment by circulating the HTS in tank 7 in a heat rejection device 56 that can absorb heat from the HTS medium and reject heat into the environment until the HTS medium to cool from the temperature to the Ti temperature. In some cases, the heat rejection device 56 may be, for example, an irradiator, a thermal bath containing a substance such as water or salt water, or a device immersed in a natural body of water such as a lake, river or ocean. In some instances, the heat rejection device 56 can also be an air-cooling device or a
series of tubes that are connected thermally to a reservoir solid (per example, tubes embedded in Earth).[0127] On some implementations, rejection of heat
for the environment by the use of the thermal storage media can be used in combination with the loading and / or discharge cycles of variable compression ratio described, for example, in figure 10. In this system, only the CTS medium can exchange heat with the environment. Such a system can also be implemented with a stove to extend the temperature ranges of the HTS and CTS media in the cycles.
[0128] In some implementations, three separate cold-side storage tanks in the respective
Petition 870190103250, of 10/14/2019, p. 69/149
63/114 temperatures T _Or Tf and Tf can be used (for example, an extra tank can be used in addition to tanks 8 and 9). During heat exchange on the cold side CFX 4 in the discharge cycle, heat from the working fluid leaving the stove 5 can be transferred to the CTS medium in the tank at temperature Tf. The CTS medium can be cooled, for example, in / by the heat rejection device 55 before entering the tank at temperature Tf · In some implementations, three separate hot-side storage tanks at the respective temperatures T _lr T and Tf can be used (for example, an extra tank can be used in addition to tanks 6 and 7). During heat exchange on the hot side CFX 2 in the discharge cycle, heat from the working fluid leaving the stove 5 can be transferred to the HTS medium in the tank at temperature Tj. The HTS medium can be cooled, for example, in / by the heat rejection device 56 before entering the tank at temperature Τ _χ . Heat rejection to the environment in such a way can present several advantages. In a first example, it can eliminate the need for a potentially expensive working fluid for ambient heat exchanger that is capable of absorbing heat from the working fluid at a rate proportional to the energy input / output of the system. The HTS and CTS media can instead reject heat for extended periods of time, thereby reducing the cost of the cooling infrastructure. In a second example, it can allow the choice regarding when heat should be rejected to the environment, which can be delayed in such a way that heat exchange to the environment can be performed when temperature (for example, room temperature) and more
Petition 870190103250, of 10/14/2019, p. 70/149
64/114 favorable.
[0129] In the loading and unloading cycles of figures 13 and 17, and figures 14 and 18, respectively, the same compression ratios and temperature values are used for both loading and unloading. In this configuration, the full cycle efficiency can be about r | storage ⁼ 7 4-6, as given by To = 194 K (-79 ° C), Ti = 494 K (221 ° C), rit = 0 , 95, q _c = 0.9 and r = 3.3.
[0130] Thus, in some examples involving recovery of working fluid to working fluid, heat rejection on the hot (high pressure) side of the closed load cycle can occur in three operations (heat exchange with the HTS medium, followed by by recovery, followed by heat rejection to the environment), and heat rejection on the cold (low pressure) side of the closed discharge cycle can happen in three operations (heat rejection to the environment, followed by recovery, followed by exchange heat with the CTS medium). As a result of recovery, the higher temperature HTS tank (s) 6 may remain in Ti ⁺ while the lower temperature HTS tank (s) 7 may now remain at Ti> To ⁺ temperature, and the lowest temperature CTS tank (s) 9 can remain in To while the highest temperature CTS tank (s) 8 can (m) now stay at the temperature To ⁺ <Ti.
[0131] In some cases, recovery can be implemented using heat exchanger 5 for direct heat transfer between the working fluid on the high pressure side and the working fluid on the low pressure side. In an alternative configuration, a pair (or
Petition 870190103250, of 10/14/2019, p. 71/149
65/114 plurality) additional heat exchangers together with an additional heat transfer medium or fluid (for example, a dedicated heat transfer fluid that is liquid in an appropriate temperature range, such as, for example, Therminol® ) can be used to achieve recovery. For example, an additional heat exchanger can be added in series with the cold side heat exchanger and an additional heat exchanger can be added in series with the hot side heat exchanger. The additional heat transfer medium can circulate between the two additional heat exchangers in a closed loop. In other examples, one or more additional heat exchangers can be placed elsewhere in the system to facilitate recovery. In addition, one or more additional heat transfer means or mixtures thereof can be used. One or more additional fluid heat transfer means may be in thermal or fluid communication with one or more other components, such as, for example, a cooling tower or a radiator.
[0132] In one example, hexane or heptane can be used as a CTS medium, and nitrate salt can be used as an HTS medium. On the low pressure side of the cycle, the operating temperatures of the pumped thermal storage cycles can be limited by the melting point of hexane (178 K or -95 ° C) in To and the melting point of nitrate (494 K or 221 ° C) in Ti. On the high pressure side of the cycle, operating temperatures can be limited by the boiling point of hexane (341 K or 68 ° C) in To ⁺ and by the decomposition of nitrate (873 K or 600 ° C ) in Ti ⁺ . In these
Petition 870190103250, of 10/14/2019, p. 72/149
66/114 conditions, the high pressure and low pressure temperature ranges can overlap in such a way that recovery can be implemented. Actual To, Ti, To ⁺ and Ti ⁺ temperatures and pressure ratios implemented in hexane / nitrate systems may differ from the above limits.
[0133] In some examples, recovery can enable the compression ratio to be reduced. In some cases, reducing the compression ratio can result in reduced compressor and turbine losses. In some cases, the compression ratio can be at least about 1.2, at least about 1.5, at least about 2, at least about 2.5, at least about 3, at least about 3.5, at least about 4, at least about 4.5, at least
fence at least 5 fence at least 6 fence of 8, at least about 10, fur minus about 15, fur any less fence at least 20 fence 30 or more. [0 134] In some cases, T _o can be at any less fence of 30 K (-243.15 ° C), fur less about 50 K (- 223.15 ° C), at least about in : 80 K (-193.15 ° C), fur any less fence 100K (-173.15 ° C), at least about 120K (- 153.15 ° C) at least fence 140K (-133.1 5 ° C) , fur any less about 160 K (-1 13, 15 ° C) at least about of 180
K (-93.15 ° C), at least about 200 K (-73.15 ° C), at least about 220 K (-53.15 ° C), at least about 240 K (-33, 15 ° C), at least about 260 K (-13.15 ° C), or at least about 280 K (6.85 ° C). In some cases, Tq can be at least about 220 K (-53.15 ° C) at least about 240 K (-33.15 ° C), at least about 260 K (-13.15 ° C) at least about 280 K (6.85 ° C), at least about 300 K, at least 320 K, at least 340 K (66, 85 ° C),
Petition 870190103250, of 10/14/2019, p. 73/149
67/114 at least 360 K (86, 85 ° C), at least about 380 K (106, 85 ° C), at least about 400 K (126, 85 ° C), or more. In some cases, T _o and T _o ⁺ temperatures may be restricted by the ability to reject excess heat into the room at room temperature. In some cases, the TQ and To ⁺ temperatures may be restricted by the CTS operating temperatures (for example, a phase transition temperature). In some cases, the To and T _o ⁺ temperatures may be restricted by the compression ratio being used. Any description of the T _Q and / or Tq temperatures in this document can be applied to any system or method of development.
[0135] In some cases Τ _χ can be at least about 350 K (76, 85 ° C), at least about 400 K (126, 85 ° C), at least about 440 K (166.85 ° C ), at least about 480 K (206.85 ° C), at least about 520 K (246.85 ° C), at least about 560 K (286.85 ° C), at least about 600 K (326.85 ° C), at least about 640 K (366.85 ° C), at least about 680 K (406.85 ° C), at least about 720 K (446.85 ° C), at least about 760 K (486.85 ° C), at least about 800 K (526.85 ° C), at least about 840 K (566.85 ° C), at least about 880 K (606 , 85 ° C),
fur least about 920 K (646.85 ° C), fur any less fence in 960 K (686.85 ° C), fur least about 1000 K (726 85 ° Ç) , fur least about 1100 K (826, 85 ° C), fur any less fence in 1200 K at least fence from 1300 K, E > link any less fence in 1400 K (1126, 85 ° C) , or more. In some cases, Tf can to be fur least about 480 K (206, 85 ° C), fur any less fence in 520 K (246, 85 ° C), fur least about 560 K (286 85 ° Ç) , fur least about 600 K (326, 85 ° C), fur any less fence in
Petition 870190103250, of 10/14/2019, p. 74/149
68/114
640 K (366.85 ° C), at least about 680 K (406.85 ° C),
fur least about 720 K (446, 85 ° C), fur less about in 760 K (486, 85 ° C), fur least about 800 K (526, 85 ° Ç) , fur least about 840 K (566.85 ° C), fur less about in 880 K (606.85 ° C), fur least about 920 K (646, 85 ° Ç) , fur least about 960 K (686.85 ° C), fur less about in 1000 K (726, 85 ° C), fur least about 1100 K (826, 85 ° Ç) , fur least about 1200 K (926.85 ° C), fur less about in 1300 K (1026, 85 ° C) , fur any less fence of 1 400K (1126 85 ° C), at least about 1500K (1226, 85 ° C) at least
about 1600 K (1326, 85 ° C), at least about 1700 K (1426.85 ° C), or more. In some cases, temperatures Τ _χ and Tf may be restricted by the operating temperatures of the HTS. In some cases, temperatures T _± and Tf may be restricted by the thermal limits of the metals and materials being used in the system. For example, a conventional solar salt may have a recommended temperature range of approximately 560-840 K (286, 85 - 566, 85 ° C). Various system improvements such as, for example, increased full cycle efficiency, increased energy and increased storage capacity can be realized as available materials, metallurgy and storage materials improve over time and enable different temperature ranges to be achieved. Any description of the temperatures T _± and / or Tf in this document can be applied to any system or method of development.
[0136] In some cases, the full cycle efficiency of storage (eg electricity storage efficiency) with and / or without recovery can be at least about 5%, at least about 10%, at least
Petition 870190103250, of 10/14/2019, p. 75/149
69/114 about 15%, at least about 20%, at least about 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least at least about 85%, at least about 90%, or at least about 95%.
[0137] In some implementations, at least part of the heat transfer in the system (for example, heat transfer to and from the working fluid) during a charge and / or discharge cycle includes heat transfer with the environment (eg example, heat transfer in sections 38 and 39). The remainder of the heat transfer in the system can occur via thermal communication with thermal storage media (for example, thermal storage media 21 and 22), through heat transfer in the stove 5 and / or through various processes of heat transfer within system boundaries (ie, not with the surrounding environment). In some examples, the environment may refer to reservoirs of gases or liquids surrounding the system (for example, air, water), any system or medium capable of exchanging thermal energy with the system (for example, another cycle or thermodynamic system , heating / cooling systems, etc.), or any combination thereof. In some instances, heat transferred via thermal communication with the heat storage media can be at least about 25%, at least about 50%, at least about 60%, at least about 70%, at least
Petition 870190103250, of 10/14/2019, p. 76/149
70/114 minus about 80%, or at least about 90% of all heat transferred in the system. In some instances, heat transferred through heat transfer in the stove can be at least about 5%, at least about 10%, at least about 15%, at least about 20%, at least about 25 %, at least about 50%, or at least about 75% of all heat transferred in the system. In some instances, heat transferred via thermal communication to the heat storage media
and why middle transfer heat in the stove can be of fur any less about 25%, fur least about 50%, at least fence 60%, at least any less about 70%, fur
at least about 80%, at least about 90%, or even about 100% of all heat transferred in the system. In some instances, heat transferred through heat transfer with the environment can be less than about 5%, less than about 10%, less than about 15%, less than about 20%, less than about 30%, less than about 40%, less than about 50%, less than about 60%, less than about 70%, less than about 80%, less than about 90%, less than about 100 %, or even 100% of all heat transferred in the system. In some implementations, all heat transfer in the system can be with thermal storage media (for example, CTS and HTS media), and only thermal storage media can conduct heat transfer with the environment.
[0138] Pumped thermal cycles of the development (for example, the cycles in figures 13 and 14) can be implemented through various tube and valve configurations to transport the working fluid between the
Petition 870190103250, of 10/14/2019, p. 77/149
71/114 turbomachinery and heat exchangers. In some implementations, a valve system can be used in such a way that the different cycles of the system can be exchanged while maintaining the same or almost the same temperature profile through at least one, through a subset or through all countercurrent heat exchangers in the system. For example, the valves can be configured in such a way that the working fluid can pass through the heat exchangers in opposite flow directions for loading and unloading and flow directions of the HTS and CTS media are reversed by reversing the direction of the pumps.
[0139] In some implementations, the system with a stove may have a different compression and / or expansion ratio in loading and unloading. This can then involve heat rejection at only one or both heat rejection locations 38 and 39, as shown in figure 5C along the lines described above.
[0140] Figure 19 is a schematic flow diagram of hot side recharging in a heat cycle pumped in solar mode with heating of a solar salt solely by means of solar energy. The system may comprise a solar heater to heat the heat storage on the hot side. The HTS medium 21 in the second hot thermal storage tank 7 of a discharge cycle, such as, for example, the HTS medium of the discharge cycle in figure 14, can be recharged within the element 17 using heating provided by solar radiation. The HTS medium (eg molten salt) can be heated by
Petition 870190103250, of 10/14/2019, p. 78/149
72/114 solar heating from Ti temperature in the second hot thermal storage tank 7 to Ti ⁺ temperature in
first tank thermal storagesome implementations, hotsuch 6. [0141] In how, per example, for the system in figure 19, heat solar for heat the middle HTS (for example, from Ti = 493 K (220 ° C) for Ti ⁺ = 873 ; K (600 ° C)) can be provided by an structure concentration solar. In some examples, an structure in small concentration scale can to be used for provide heat. In some cases, the structure solar from concentration may include one or more components
to achieve high solar concentration efficiency, including, for example, high performance actuators (eg adaptive fluidic actuators made of polymers), multiplexing control system, dense heliostat layout, etc. In some examples, the heat supplied to heat the HTS medium (for example, in element 17) can be a residual heat flux from the concentration solar structure.
[0142] Figure 20 is a schematic flow diagram of a pumped thermal system discharge cycle that can be coupled with external heat input (eg, solar, combustion) with heat rejection to the environment. A discharge cycle like this can be used, for example, in situations where the capacity for recharging on the hot side (for example, using solar heating, residual heat or combustion) is greater than the capacity for recharging on the cold side. Solar heat can be used to load HTS 21 medium into Ti-Ti ⁺ Ti ⁺ hot side storage tanks, such as
Petition 870190103250, of 10/14/2019, p. 79/149
73/114 described elsewhere in this document. The discharge cycle can operate in a similar way to the discharge cycle in figure 3, but after leaving the turbine 3 the working fluid 20 can proceed to the CFX heat exchanger on the cold side 4 where it exchanges heat 4 with a storage medium intermediate thermal (ITS) 61 having a lower To temperature at or near room temperature. The ITS medium 61 enters the cold side CFX 4 from a second intermediate thermal storage tank 59 at temperature To (for example, room temperature) and exits the cold side CFX 4 into a first intermediate thermal storage tank 60 at temperature Tj, while working fluid 20 enters the cold side CFX 4 at temperature T _± and exits the cold side CFX 4 at temperature To. The working fluid enters compressor 1 in To and P2, leaves the compressor in To ⁺ and Pi, absorbs heat Qi from the medium HTS 21 in the hot side CFX 2, leaves the hot side CFX 2 in Tf and Pi, enters in turbine 3 in Tf and Pi, it leaves the turbine in T _± and P2, it rejects the heat Q2 of the medium ITS 61 in the cold side CFX 4, and it leaves the cold side CFX 4 in To and P2, returning to its initial state before entering the compressor.
[0143] In some implementations, the ITS 61 medium can be a liquid in the total range of T _o to Tj. In other implementations, the ITS 61 medium may not be a liquid in the total range of T _o to Tj, but can be supplied to the countercurrent heat exchanger 4 at a higher flow rate in order to achieve a lower temperature rise through countercurrent heat exchanger (for example, such that the temperature of the ITS medium in the
Petition 870190103250, of 10/14/2019, p. 80/149
74/114 countercurrent heat exchanger 4 output is less than Ti) while still cooling the working fluid from T _± to T _o . In this instance, the temperature of the ITS medium in tank 60 may be lower than T). The ITS medium in tank 60 can exchange heat with the environment (for example, by means of a radiator or other implementations described in this document) in order to cool back to temperature T _o . In some cases, the ITS medium can then be returned to tank 59. In some cases, the heat deposited in the ITS medium can be used for various useful purposes such as, for example, residential or commercial heating, thermal desalination or other described uses elsewhere in this document.
[0144] Figure 21 is a schematic flow diagram of a thermal system discharge cycle pumped in solar mode or combustion heated mode with heat rejection to an intermediate fluid circulated in a thermal bath at room temperature. The discharge cycle can operate similarly to the discharge cycle in figure 20, but after leaving turbine 3 the working fluid 20 can proceed to the cold side CFX 4 where it exchanges heat with a medium or intermediate fluid 62 circulating through of a thermal bath 63 at temperature To or near room temperature. The medium or intermediate fluid 62 (eg Therminol®, or a heat transfer oil) can be used to exchange heat between the working fluid 20 and a thermal bath 63 in the cold side CFX 4. The use of the intermediate fluid 62 can provide an advantage over placing a cheap heatsink or thermal medium (eg water) directly in contact with the working fluid. Per
Petition 870190103250, of 10/14/2019, p. 81/149
75/114 example, placing a thermal medium like this directly in contact with the working fluid in the cold side CFX 4 can cause problems such as, for example, evaporation or excess pressurization (for example, explosion) of the thermal medium. The intermediate fluid 62 can remain in the liquid phase for the entire, for at least part or for a significant part of the operation on the cold side CFX 4. As the intermediate fluid 62 passes through the thermal bath 58, it can be cooled sufficiently to circulate back into the cold side CFX 4 to cool the working fluid from 7 to T _o . The thermal bath 63 can contain a large amount of cheap heat-dissipating material or medium, such as, for example, water. In some cases, the heat deposited on the heat sink material can be used for several useful purposes such as, for example, residential or commercial heating, thermal desalination or other uses described elsewhere in this document. In some cases, the heat-dissipating material can be rebalanced at room temperature (for example, by means of a radiator or other implementations described in this document).
[0145] In some implementations, the discharge cycles in figures 20 and / or 21 may include a stove, as described in more detail in examples throughout the disclosure. Such systems can be implemented using the Ti ⁺ , Ti, To ⁺ and To temperatures described in more detail elsewhere in this document. Solar Aided Pumped Thermal Storage Cycles
With Intercooling [0146] In some instances, the thermal system
Petition 870190103250, of 10/14/2019, p. 82/149
76/114 pumped can supply heat sources and / or cold sources to other installations or systems such as, for example, by means of joint location with a liquid gas installation (GTL) or a desalination plant. In one example, GTL installations may make use of one or more of the cold reservoirs in the system (for example, the CTS medium in tank 9 for use in oxygen separation in the GTL installation) and / or one or more hot reservoirs in the system ( for example, the HTS medium in tank 6 for use in a Fischer-Tropsch process in the GTL installation). In another example, one or more hot reservoirs or one or more cold reservoirs in the pumped thermal system can be used for operating thermal desalination methods. Additional examples of possible uses of heat and cold include colocalization or heat exchange with building / area heating and cooling systems.
[0147] Conversely, in some cases, the pumped thermal system may make use of residual heat sources and / or residual cold sources from other facilities or systems such as, for example, by jointly locating with a terminal import or export of liquefied natural gas. For example, a residual cold source can be used to cool the cold side thermal storage media 22. In some implementations, recharging the cold side using residual cold can be combined with recharging the hot side thermal storage media 21 by means of external heat input (eg solar, combustion, residual heat, etc.). In some cases, refilled storage media can then be used in a discharge cycle
Petition 870190103250, of 10/14/2019, p. 83/149
77/114 such as, for example, the discharge cycles in figures 14 or 16. In some cases, the pumped thermal system can be used as a thermal motor with a residual heat source serving as the hot side heat input and a residual cold source serving as the cold side heatsink. In another implementation, the hot-side storage media can be refilled using a modified version of the cycle shown in figure 15, where the temperature T _o is approximately room temperature and T _o ⁺ corresponds to a temperature above room temperature. In some instances, a residual heat source can be used to provide the necessary heat at a temperature of at least To ⁺ to heat the working fluid and / or the CTS medium to To ⁺ . In another implementation, an intermediate fluid (eg Therminol®) that can remain liquid between the To ⁺ and TQ temperatures can be used to transfer the heat from the residual heat source to the working fluid.
Pumped Thermal Systems With Dedicated Compressor / Turbine Pairs [0148] In an additional aspect of the development, pumped thermal systems comprising multiple working fluid systems, or working fluid flow paths are provided. In some cases, components of the thermal system pumped in the loading and unloading modes may be the same. For example, the same compressor / turbine pair can be used for loading and unloading cycles. Alternatively, one or more system components may differ between loading and unloading modes. For example, separate compressor / turbine pairs can be
Petition 870190103250, of 10/14/2019, p. 84/149
78/114 used in loading and unloading cycles. In one implementation, the system has a set of heat exchangers, and a common set of HTS and CTS tanks that are loaded or unloaded by two pairs or sets of compressors and turbines. In another implementation, the system has a common set of HTS and CTS tanks, but separate sets of heat exchangers and separate sets of compressors and turbines.
[0149] Pumped thermal systems with recovery, use of external sources of heat, cold and / or residual heat / cold can benefit from having separate compressor / turbine pairs as a result of turbomachinery operation over large temperature ranges and / or different in loading and unloading modes. For example, temperature changes between loading and unloading cycles can result in a period of thermal adjustment or other difficulties during transition between cycles (for example, issues or factors related to metallurgy, thermal expansion, Reynolds number, compression ratios dependent on temperature, tip clearance and / or bearing friction, etc.). In another example, turbomachinery (for example, turbomachinery used in systems with recovery) can operate at a relatively low pressure ratio (for example, with relatively few compression stages), but at a relatively high temperature during both compression and expansion. The temperature ranges can change (for example, switch as in figures 17 and 18) between loading and unloading modes. In some cases, operation in large temperature ranges during compression and / or expansion can complicate the design of a
Petition 870190103250, of 10/14/2019, p. 85/149
79/114 compressor and turbine combined for both loading and unloading. In addition, recovery, incorporation of residual heat / cold and / or other pumped thermal system resources can reduce the compression ratio of the compressor / turbine in the load cycle and / or in the discharge cycle, thereby reducing the cost associated with doubling compressor / turbine sets.
[0150] Figures 22 and 23 show thermal systems pumped with pairs of separate compressors 1 / turbines 3 for load mode C and discharge mode D. The separate pairs of compressors / turbines can be grouped or not on a common mechanical axis. In this example, the compressor and turbine pairs C and D can have separate axes 10. The axes 10 can rotate at the same speed or at different speeds. Compressor / turbine pairs
separated or systems in fluid job can or no to share changers of heat (per example, the changers in heat 2 and 4) • [0151] At the example at figure 22 , the system has one
common set of tanks HTS 6 and 7 and tanks CTS 8 and 9. The system has separate pairs of heat exchangers 2 and 4 and separate pairs of compressors 1 / turbines 3 for loading mode C and discharge mode D. The paths streams of HTS and CTS storage media for the loading cycle are shown as continuous black lines. The flow paths of HTS and CTS storage media for the discharge cycle are shown as dashed gray lines.
[0152] In the example in figure 23, the system, shown in a load configuration, has a set of exchangers
Petition 870190103250, of 10/14/2019, p. 86/149
80/114 heat 2 and 4, and a common set of tanks HTS 6 and 7 and tanks CTS 8 and 9. HTS and CTS tanks can be loaded by a compressor / turbine set C, or discharged by a compressor / turbine set D, each set comprising a compressor 1 and a turbine 3. The system can switch between sets C and D using valves 83. In the example in figure 22, the system, again shown in a load configuration, has a common set of tanks HTS 6 and 7 and tanks CTS 8 and 9. The tanks HTS and CTS can be loaded by the load set C which includes a first set of heat exchangers 2 and 4, the compressor 1 and the turbine 3. The HTS tanks and CTS can be discharged by switching to a separate discharge set C which includes a second set of heat exchangers 2 and 4, compressor 1 and turbine 3.
[0153] In one example, if the compressor and turbine loading and unloading assemblies in figures 22 and 23 are not operated at the same time, the loading and unloading assemblies can share a common set of heat exchangers that are switched between turbomachinery pairs using valves 83. In another example, if the loading and unloading turbomachinery sets or pairs in figures 22 and 23 are operated at the same time (for example, in order for a set to load, following intermittent generation, and the other set discharges at the same time, following the load), so each set of turbomachinery can have a dedicated set of heat exchangers. In this instance, the loading and unloading assemblies may or may not share a set of HTS and CTS tanks.
Petition 870190103250, of 10/14/2019, p. 87/149
81/114 [0154] In some implementations, separate compressor / turbine sets or pairs can be advantageously used in pumped thermal systems used with intermittent and / or variable electrical inputs. For example, a first compressor / turbine set can be used in a load cycle that uses wind and / or solar energy (for example, electric energy input from the wind and / or solar energy system) while a second compressor set / turbine can be used in a discharge cycle that uses a charge (for example, mackerel for electricity to a power grid). In this configuration, pumped thermal systems placed between a power generation system and a load can help to mitigate variations / fluctuations in input and / or output power requirements.
Hybrid Pumped Thermal Systems [0155] According to another aspect of the disclosure, pumped thermal systems can be augmented by means of additional energy conversion processes and / or can be used directly as energy conversion systems without energy storage (ie is, like power generation systems). In some examples, thermal systems pumped in this document can be modified to allow direct energy generation using natural gas, diesel oil, petroleum gas (eg propane / butane), dimethyl ether, fuel oil, wood chips, landfill gas garbage, hexane, hydrocarbons or any other combustible substance (for example, fossil fuel or biomass) to add heat to the working fluid on a hot side of a working fluid cycle, and a
Petition 870190103250, of 10/14/2019, p. 88/149
82/114 cold side heat sink (eg water) to remove heat from the working fluid on a cold side of the working fluid cycle.
[0156] Figures 24 and 25 show pumped thermal systems configured in generation mode. In some examples, thermal systems pumped in this document can be modified by using the two additional heat exchangers 40 and 41, the four additional valves 19a, 19b, 19c and 19d, a heat sink (for example, a water cooling system) ; water from a freshwater reservoir such as a river, a lake or a reservoir; saltwater from a saltwater reservoir such as a sea or an ocean; air cooling using radiators, fans / blowers, convection; or a heatsink environmental heat such as earth / soil, cold air, etc.) 42, and a heat source (for example, a combustion chamber with a fuel-oxidizing mixture) 43. The heat source 43 can exchange heat with a first of the two additional heat exchangers 40, and the heat sink 42 can exchange heat with one second of the two additional heat exchangers 41. The heat source 43 can be used to exchange heat with the working fluid 20.
[0157] The heat source 43 can be a source of combustion heat. In some instances, the combustion heat source may comprise a combustion chamber to burn a combustible substance (for example, a fossil fuel, a synthetic fuel, municipal solid waste (MSW) or biomass). In some cases, the combustion chamber can be separated from the heat exchanger 40. In some cases, the heat exchanger 40 can
Petition 870190103250, of 10/14/2019, p. 89/149
83/114 understand the combustion chamber. The heat source 43 can be a source of residual heat, such as, for example, residual heat from a power plant, from an industrial process (e.g., furnace discharge).
[0158] In some examples, a solar heater, a combustion heat source, a residual heat source or any combination thereof can be used to heat the hot side heat storage fluid and / or the working fluid. In one example, the working fluid can be heated directly using any of these heat sources. In another example, the hot-side heat storage fluid (or HTS medium) can be heated using any of these heat sources. In another example, the hot-side heat storage fluid (or HTS medium) can be heated in parallel with the working fluid using any of these heat sources.
[0159] The thermal systems pumped in figures 24 and 25 can be operated as hybrid systems. For example, valves 19a, 19b, 19c and 19d can be used to switch between two modes. When the valves are in the first position, the system can operate as a pumped thermal storage system (for example, closed system in charge / discharge mode). In this configuration, the working fluid 20 (for example, argon or air) can exchange heat with an HTS medium (for example, molten salt) in the hot side heat exchanger 2 and with a CTS medium (for example, hexane) in the cold side heat exchanger 4. When the valves are in a second position, the system can operate as a power generation system (for example,
Petition 870190103250, of 10/14/2019, p. 90/149
84/114 example, open system in generation mode). In this configuration, heat exchangers 2 and 4 can be bypassed, and working fluid 20 can exchange heat with the combustion chamber 43 on the hot side heat exchanger 40 and with heat sink 42 on the side heat exchanger. cold 41. Any description of configuration and / or design of heat transfer processes (eg heat transfer in heat exchangers) made in this document in relation to pumped thermal systems can also be applied to hybrid pumped thermal systems, and vice -version. For example, heat sink 42, heat source 43, heat exchangers 40 and 41 and / or the amount of heat transferred on the cold side and / or the hot side can be configured to decrease or minimize the generation of associated entropy with heat transfer processes and / or to maximize system efficiency.
[0160] In some implementations, hybrid systems can operate in storage and generation modes simultaneously. For example, valves 19a, 19b, 19c and 19d can be configured to allow a given room
between one rate of flow of fluid in job To the changers in heat 40 and 41 and a fee flow of fluid working for the changers in heat 2 and 4.
Alternatively, hybrid systems can operate exclusively in storage mode, or exclusively in generation mode (for example, as a peak natural gas installation). In some cases, the division between modes can be selected based on system efficiency, available electrical input (eg
Petition 870190103250, of 10/14/2019, p. 91/149
85/114 example, based on availability), desired electrical power output (for example, based on load demand), etc. For example, thermal efficiency of an ideal system (that is, assuming isentropic compression and expansion processes, ideal heat transfer processes) operating exclusively in generation mode can be the thermal efficiency of a working fluid being subjected to a Brayton cycle ideal. In some instances, thermal efficiencies in hybrid development systems (eg, exclusive and / or split operation) may be at least about 10%, at least about 20%, at least about 30%, at least at least about 40%, at least about 50%, at least about 60%, or more.
[0161] Heat source 43 can be used to exchange heat with an HTS medium (for example, a molten salt). For example, combustion heat source 43 can be used to heat the HTS 21 medium. In some instances, instead of using combustion heat source 43 to exchange heat in heat exchanger 40 or exchange heat directly between flue gases combustion of the combustion heat source and the working fluid, the combustion heat source 43 can be used to heat the HTS 21 medium between the two HTS tanks 7 and 6.
[0162] Figure 26 is a schematic flow diagram of hot side recharging in a heat cycle pumped through heating by heat source 43 (e.g., combustion heat source, residual heat source). In one example, the heat source 43 is a residual heat source, such as a residual heat source from a refinery or other processing facility. In
Petition 870190103250, of 10/14/2019, p. 92/149
86/114 For example, heat source 43 is obtained by burning natural gas in order to ensure the delivery of electricity even if the pumped thermal system runs out of charged storage media. For example, recharging the hot-side storage media using the heat source 43 can provide an advantage over recharging using electricity or other resources (for example, the price of electricity over time can be very high). The heat source 43 can be used to heat the HTS 21 medium from the Ti temperature in the tank 7 to the Ti ⁺ temperature in the tank 6. The HTS medium can then be used in the CFX 2 to exchange heat with the working fluid in one cycle. of discharge, such as, for example, the discharge cycles in figures 20 and 21.
[0163] In some cases, such as, for example, when the CTS medium is a combustible substance such as a fossil fuel (for example, hexane or heptane), burning of the CTS medium stored in CTS tanks (for example, in tanks 8 and 9) can be used to provide thermal energy to heat the HTS medium as shown, for example, in figure 26 or for operating the cycles in the configurations shown, for example, in figures 24 and 25.
[0164] Developing systems may be able to operate both in an electricity-only storage cycle (comprising heat transfer with an HTS medium and a CTS medium below room temperature) and in a thermal engine for the ambient cycle, where , in a discharge mode, heat is introduced from the HTS medium into the working fluid and discarded into the environment instead of the CTS medium. This ability can enable the use
Petition 870190103250, of 10/14/2019, p. 93/149
87/114 of heating the HTS with combustible substances (for example, as shown in figure 26) or the use of solar heating of the HTS (for example, as shown in figure 19). Heat rejection to the environment can be implemented using, for example, the discharge cycles in figures 20 and 21. In some cases, heat can be rejected into the environment with the help of ITS 61 or intermediate 62.
[0165] Aspects of the disclosure can be combined synergistically. For example, systems capable of operating in either an electricity-only storage cycle or in a thermal engine for an ambient cycle may comprise a stove. Any description regarding such hybrid systems without a stove can be readily applied to hybrid systems with a stove in at least some configurations. In some instances, hybrid systems can be implemented using, for example, the parallel valve configuration in figure 24. For example, the current flow heat exchangers 4 in figures 20 and 21 can be implemented like the counter current heat exchangers 67 to exchange heat with the environment, and can be used in combination with the cold side countercurrent heat exchangers 4 of the disclosure.
[0166] In some implementations, the systems in this document can be configured to enable switching between different disclosure cycles using a shared set of valves and tubes. For example, the system can be configured to switch between the electricity charge cycle only (as shown, for example, in
Petition 870190103250, of 10/14/2019, p. 94/149
88/114 figure 15), the electricity-only discharge cycle (as shown, for example, in figure 16), and the thermal engine for the ambient cycle (as shown in figure 21).
Pumped Thermal Systems With Pressure Regulation Energy Control [0167] In one aspect of the development, the pressure of working fluids in pumped thermal systems can be controlled to achieve energy control. In one example, the energy supplied to a closed system in charge mode and / or the energy extracted from the closed system in discharge and / or generation mode (for example, input / output working using axis 10) is proportional to the molar or mass flow rate of the circulating working fluid. The mass flow rate is proportional to the density, area and speed of flow. The flow speed can be kept fixed in order to achieve a fixed axis speed (for example, 3,600 rpm or 3,000 rpm according to mains requirements of 60 and 50 Hz respectively). Thus, as the pressure of the working fluid changes, the mass flow rate and energy can change. In one example, as the mass flow rate increases in a discharge and / or generation mode, more charge must be added to the system to maintain a constant speed of the rotating axis, and vice versa. In another example, if the load is reduced during operation in a discharge and / or generation mode, the reduced load can cause the axle speed to increase, thereby increasing the mass flow rate. For some period of time, before the heat stored in the thermal capacity
Petition 870190103250, of 10/14/2019, p. 95/149
89/114 of the heat exchangers by themselves being dissipated, this increased mass flow rate can result in an increase in the energy delivered, thereby increasing the shaft speed. Axis speed and energy can continue to increase uncontrollably, resulting in uncontrolled operation of the rotary axis. In some instances, pressure regulation can enable control, and thus stabilization of uncontrolled operation, by adjusting the amount (for example, density) of working fluid circulating according to system requirements. In an example where spindle speed (and turbocharging, such as a turbine, attached to the spindle) starts uncontrolled operation, a controller can reduce the mass of circulating working fluid (eg mass flow rate) in order to decrease the energy delivered, in turn decreasing the axis speed. Pressure regulation can also allow for an increase in mass flow rate in response to an increase in load. In each of these instances, the flow rates of the HTS and CTS media through the heat exchangers can be matched to the thermal capacity of the working fluid passing through the heat exchangers.
[0168] In some instances, the working fluid pressure in the closed system can be varied when using an auxiliary working fluid tank in fluid communication with the closed system. In this configuration, energy input / output can be decreased by transferring the working fluid from the closed loop loop to the tank, and energy input / output can be increased by transferring the working fluid from the tank to the loop loop.
Petition 870190103250, of 10/14/2019, p. 96/149
90/114 closed. In one example, when the working fluid pressure is decreased, less heat can be transferred between the thermal storage tanks on the hot and cold sides of the system as a result of the decreased mass flow rate and less energy can be introduced into the system. system or produced by it.
[0169] As the pressure of the working fluid is varied, the compression ratios of turbomachinery components can remain substantially unchanged. In some cases, one or more operating parameters and / or configurations (for example, variable stators, axis speed) of turbomachinery components can be adjusted in response to a change in working fluid pressure (for example, to achieve a desired system performance). Alternatively, one or more pressure reasons may
change in response to a change in pressure of fluid in job. [0170] In some cases, cost reduced and / or < consumption in parasitic energy reduced can be reached using The
energy control setting in relation to other settings (for example, using a throttle valve to control the flow of working fluid). In some instances, variation in working fluid pressure while keeping the temperature and flow rate constant (or almost constant) can result in negligible entropy generation. In some instances, an increase or decrease in system pressure can result in changes, for example, in turbomachinery efficiencies.
Petition 870190103250, of 10/14/2019, p. 97/149
91/114 [0171] Figure 27 shows an example of a pumped thermal system with energy control. The temperature of the working fluid on the hot and cold sides of the system can remain constant or almost constant over a given period of time regardless of the mass flow rate of the working fluid because of the large heat capacities of heat exchangers 2 and 4 and / or the hot and cold side thermal storage media in tanks 6, 7, 8 and 9. In some instances, the flow rates of HTS and CTS media through heat exchangers 2 and 4 are varied in accordance with a change in working fluid pressure in order to keep temperatures in heat exchangers and working fluids optimized for longer periods of time. Thus, pressure can be used to vary the mass flow rate in the system. One or more auxiliary tanks 44 filled with working fluid 20 (for example, air, argon or argon-helium mixture) may be in fluid communication with a hot (for example, high pressure) side of the pumped thermal system and / or with a cold side (for example, low pressure) of the pumped thermal system. In some examples, the auxiliary tank may be in fluid communication with the working fluid adjacent to a compressor 1 inlet and / or adjacent to a compressor 1 outlet. In some examples, the auxiliary tank may be in fluid communication with the working fluid adjacent to a turbine inlet 3 and / or adjacent to a turbine 3 outlet. In additional examples, the auxiliary tank may be in fluid communication with the working fluid in one or more system locations (for example , at one or more locations on the pressure side
Petition 870190103250, of 10/14/2019, p. 98/149
92/114 of the system, on the low pressure side of the system or in any combination thereof). For example, the auxiliary tank can be in fluid communication with the working fluid on one side of high pressure and on one side of low pressure of the closed cycle. In some cases, fluid communication on the high pressure side can be provided after the compressor and before the turbine. In some cases, fluid communication on the low pressure side can be provided after the turbine and before the compressor. In some instances, the auxiliary tank may contain working fluid at an intermediate pressure at high and low system pressures. The working fluid in the auxiliary tank can be used to increase or decrease the amount of the working fluid 20 circulating in the closed cycle of the pumped thermal system. The amount of working fluid circulating in the closed loop can be decreased by pouring the working fluid from the high pressure side of the closed loop into the tank via a fluid path containing a valve or mass flow controller 46, thereby loading the tank 44. The amount of working fluid circulating in the closed loop loop can be increased by pouring the working fluid from the tank to the low pressure side of the closed loop loop through a fluid path containing a valve or mass flow controller 45, thereby discharging the tank 44.
[0172] Energy control on a larger time scale can be implemented by changing the working fluid pressure and adjusting the flow rates of the hot 21 and cold 22 thermal storage fluids
Petition 870190103250, of 10/14/2019, p. 99/149
93/114 through heat exchangers 2 and 4, respectively.
[0173] In some examples, flow rates of thermal storage media 21 and / or 22 can be controlled (for example, by a controller) to maintain a given heat exchanger inlet and outlet temperatures. In some examples, a first controller (s) can be provided to control the flow rates (e.g., mass flow rates) of thermal storage media, and a second controller can be provided to control the mass flow rate (for example, by controlling mass, mass flow rate, pressure, etc.) of the working fluid.
Pumped Thermal Systems With Pressure Closed Motor / Generator [0174] In another aspect of the disclosure, pumped thermal systems with a pressure closed motor / generator are provided. The pressure-terminated engine / generator can be provided as an alternative for configurations where an axle (also crankshaft in this document) penetrates a working fluid containment wall (where it can be exposed to one or more pressure differentials in relation to to connect to a motor / generator outside the working fluid retaining wall. In some cases, the shaft may be exposed to working fluid pressures and temperatures in the low pressure part of the working fluid cycle, the high pressure part of the working fluid cycle or both. In some cases, crankshaft seal (s) capable of maintaining the pressures that the crankshaft is exposed on the inside of the fluid retaining wall
Petition 870190103250, of 10/14/2019, p. 100/149
94/114 work can be difficult to manufacture and / or difficult to maintain. In some cases, a rotating seal between high and low pressure environments can be difficult to achieve. Thus, coupling the compressor and turbine to the engine / generator can be challenging. In some implementations, the motor / generator can therefore be placed entirely within the low pressure part of the working fluid cycle, in such a way that the outer wall of the pressure vessel or working fluid containment does not need to be drilled .
[0175] Figure 28 shows an example of a thermal system pumped with a generator closed with pressure 11. The motor / generator is closed inside the pressure vessel or working fluid containment wall (shown as dashed lines ) and only the power supply conductors 49 penetrate the pressure vessel. A thermal insulation wall 48 is added between the motor / generator 11 and the working fluid in the low pressure part of the cycle. The technical requirements for achieving a proper seal through the thermal insulation wall may be less stringent because the pressure is the same on both sides of the thermal insulation wall (for example, both sides of the thermal insulation wall can be located in the low pressure part of the cycle). In one example, the low pressure value can be about 10 atm (1.01325 MPa). In some cases, the engine / generator can be adapted for operation at high surrounding pressures. An additional thermal insulation wall 50 can be used to create a seal between the outlet of the compressor 1 and the inlet of the turbine 3 at the
Petition 870190103250, of 10/14/2019, p. 101/149
95/114 high cycle pressure. In some instances, placing the motor / generator on the cold side of the pumped thermal systems can be beneficial for the operation of the motor / generator (for example, cooling a superconducting generator).
Pumped Thermal Systems With Variable Stator Pressure Ratio Control [0176] An additional aspect of the disclosure concerns pressure control in working fluid cycles of pumped thermal systems when using variable stators. In some instances, the use of variable stators in turbomachinery components can allow pressure ratios in working fluid cycles to be varied. The variable compression ratio can be obtained by having mobile stators in the turbomachinery.
[0177] In some cases, pumped thermal systems (for example, the systems in figures 17 and 18) can operate at the same compression ratio in both the loading and unloading cycles. In this configuration, heat can be rejected (for example, to the environment) in section 38 in the charge cycle and in section 39 in the discharge cycle, where the heat in section 38 can be transferred at a lower temperature than can heat in section 39. In alternative configurations, the compression ratio can be varied by switching between the charge cycle and the discharge cycle. In one example, variable stators can be added to both the compressor and the turbine, thus allowing the compression ratio to be adjusted. The ability to vary the compression ratio between loading and unloading modes can enable heat to be rejected only at the lowest temperature (for example, heat can be rejected in the section
Petition 870190103250, of 10/14/2019, p. 102/149
96/114 in the charge cycle, but not in section 39 in the discharge cycle). In some instances, most (or all) of the heat discharged into the environment is transferred at a lower temperature, which can increase the efficiency of the complete cycle of the system.
[0178] Figure 29 is an example of variable stators in a compressor / turbine pair. The compressor 1 and the turbine 3 can both have variable stators, so that the compression ratio for each can be adjusted. Such an adjustment can increase full cycle efficiency.
[0179] Each of the compressor and the turbine can include one or more stages of compression. For example, the compressor and / or the turbine may have multiple rows of repetition features distributed along its circumference. Each compression stage can comprise one or more rows of resources. The rows can be arranged in a given order. In one example, each of the compressor 1 and the turbine 3 comprises a sequence of a plurality of input guide vanes 51, a first plurality of rotors 52, a plurality of stators 53, a second plurality of rotors 52 and a plurality of outlet guide vanes 54. Each plurality of features can be arranged in a row along the circumference of the compressor / turbine. The configuration (for example, direction or angle) of stators 53 can be varied, as shown in figure 29.
[0180] The compressor / turbine pair can be matched. In some cases, a compressor outlet pressure can be approximately equal to a turbine inlet pressure, and a compressor inlet pressure can be approximately
Petition 870190103250, of 10/14/2019, p. 103/149
97/114 approximately equal to the turbine outlet pressure; thus, the pressure ratio through the turbine can be equal to the pressure ratio through the compressor. In some cases, inlet / outlet pressures and / or pressure ratios may differ by a given amount (for example, to consider a pressure drop in the system). The use of variable stators in both the compressor and the turbine may allow the compressor and the turbine to remain mated as the compression ratio is varied. For example, using variable stators, compressor and turbine operation can remain within proper operating conditions (for example, within a given range or at a given point on their respective operating maps) as the compression ratio is varied. Operation within given ranges or at given points on turbomachinery operation maps can allow turbomachinery efficiencies (for example, isentropic efficiencies) and resulting full cycle storage efficiency to be maintained within a desired range. In some implementations, the use of variable stators can be combined with other methods to vary the compression ratios (for example, variable axis rotation speed, turbomachine stage contour, gears, power electronics, etc.).
Pumped Thermal System Units Comprising Pumped Thermal System Subunits [0181] An additional aspect of the disclosure concerns loading and unloading rate control over a total maximum load / energy input range for maximum discharge / energy output when building
Petition 870190103250, of 10/14/2019, p. 104/149
98/114 pumped thermal system units comprised of pumped thermal system subunits. In some instances, pumped thermal systems may have a minimum energy input and / or output (for example, minimum energy input and / or minimum energy output) above 0% of the maximum energy input and / or output (for example , maximum energy input and / or maximum energy output), respectively. In such cases, a single unit by itself may be able to continuously ram from the minimum energy input to the maximum energy input and from the minimum energy output to the maximum energy output, but may not be able to continuously ram from the input of minimum energy to the minimum energy output (that is, of the minimum energy input to the zero energy input / output, and from the zero energy input / output to the minimum energy output). An ability to continuously ramp from the minimum energy input to the minimum energy output can enable the system to continuously ramp from the maximum energy input to the maximum energy output. For example, if both the output energy and the input energy can be turned down all the way to zero during operation, the system may be able to continuously vary the energy consumed or supplied across a range of the maximum input ( for example, acting as a load on the mains) for maximum output (for example, acting as a generator on the mains). Such functionality can increase (for example, more than double) the continuously ramping range of the pumped thermal system. Increasing the continuously ramped range of the pumped thermal system can be
Petition 870190103250, of 10/14/2019, p. 105/149
99/114 advantageous, for example, when continuously stripping energy range is used as a metric to determine the value of mains assets. In addition, such functionality can enable the development systems to understand variable load, variable generation, intermittent generation or any combination thereof.
[0182] In some implementations, compound pumped thermal system units comprised of multiple pumped thermal system subunits can be used. In some cases, each subunit may have a minimum energy input and / or output above 0%. Continuous ramping of energy from the maximum energy input to the maximum energy output may include combining a given number of subunits. For example, an adequate number (for example, sufficiently large) of subunits may be necessary to achieve continuous ramping. In some examples, the number of subunits can be at least about 2, 5, 10, 20, 30, 40, 50, 100, 200, 500, 750, 1,000 and others. In some examples, the number of subunits is 2, 5, 10, 20, 30, 40, 50, 100, 150, 200, 250, 300, 350, 400, 450, 500, 550, 600, 650, 700, 750 , 800, 850, 900, 950, 1,000 or more. Each subunit can have a given energy capacity. For example, each subunit may have an energy capacity that is less than about 0.1%, less than about 0.5%, less than about 1%, less than about 5%, less than about 10 %, less than about 25%, less than about 50%, or less than about 90% of the total energy capacity of the compound pumped thermal system. In some cases, different subunits may have different energy capacities. In some instances, a
Petition 870190103250, of 10/14/2019, p. 106/149
100/114 subunit has an energy capacity of about 10 kW, 100 kW, 500 kW, 1 MW, 2 MW, 5 MW, 10 MW, 20 MW, 50 MW, 100 MW or more. Continuous ramping of energy from the maximum energy input to the maximum energy output may include controlling each subunit energy input and / or output (e.g., energy input and / or energy output) separately. In some cases, subunits can be operated in opposite directions (for example, one or more subunits can operate in power input mode, while one or more subunits can operate in power output mode). In one example, if each pumped thermal system subunit can be continuously ramped between a maximum energy input and / or output to below about 50% of the maximum energy input and / or output, respectively, three or more of such subunits pumped thermal system units can be combined into a composite pumped thermal system unit that can be ramped continuously from the maximum input energy to the maximum output energy. In some implementations, the composite pumped thermal system may not have a fully continuous range between the maximum input energy and the maximum output energy, but it may have an increased number of operating points in this range compared to a non-composite system.
Energy Storage System Units Comprising Energy Storage System Subunits [0183] An additional aspect of the disclosure concerns charging and discharging rate control over a maximum charging / energy input range
Petition 870190103250, of 10/14/2019, p. 107/149
101/114 for maximum discharge / energy output when building composite energy storage system units comprised of energy storage system subunits. In some examples, energy storage systems may have a minimum energy input and / or output (for example, minimum energy input and / or minimum energy output) above 0% of the maximum energy input and / or output ( for example, maximum energy input and / or maximum energy output), respectively. In such cases, a single unit by itself may be able to continuously ram from the minimum energy input to the maximum energy input and from the minimum energy output to the maximum energy output, but may not be able to continuously ram from the input of minimum energy to the minimum energy output (that is, of the minimum energy input to the zero energy input / output, and from the zero energy input / output to the minimum energy output). An ability to continuously ramp from the minimum energy input to the minimum energy output can enable the system to continuously ramp from the maximum energy input to the maximum energy output. For example, if both the output energy and the input energy can be turned down all the way to zero during operation, the system may be able to continuously vary the energy consumed or supplied across a range of the maximum input ( for example, acting as a load on the mains) for maximum output (for example, acting as a generator on the mains). Such functionality can increase (for example, more than double) the continuously ramping range of the
Petition 870190103250, of 10/14/2019, p. 108/149
102/114 energy storage. Increasing the continuously ramping range of the energy storage system can be advantageous, for example, when continuously ramping energy range is used as a metric to determine the value of mains assets. In addition, such functionality can enable the development systems to understand variable load, variable generation, intermittent generation or any combination thereof.
[0184] In some implementations, composite energy storage system units comprised of multiple energy storage system subunits can be used. In some examples, any energy storage system having energy input / output characteristics that can benefit from a composite configuration can be used. In some examples, systems having power input and / or power output characteristics that can benefit from a composite configuration may include various storage and / or power generation systems such as, for example, gas power plants natural or combined cycle, fuel cell systems, battery systems, compressed air energy storage systems, pumped hydroelectric systems, etc. In some cases, each subunit may have a minimum energy input and / or output above 0%. Continuous ramping of energy from the maximum energy input to the maximum energy output may include combining a given number of subunits. For example, an adequate number (for example, sufficiently large) of subunits can be
Petition 870190103250, of 10/14/2019, p. 109/149
103/114 necessary to achieve continuous ramp. In some examples, the number of subunits can be at least about 2, 5, 10, 20, 30, 40, 50, 100, 200, 500, 750, 1,000 and others. In some examples, the number of subunits is 2, 5, 10, 20, 30, 40, 50, 100, 150, 200, 250, 300, 350, 400, 450, 500, 550, 600, 650, 700, 750 , 800, 850, 900, 950, 1,000 or more. Each subunit can have a given energy capacity. For example, each subunit may have an energy capacity that is less than about 0.1%, less than about 0.5%, less than about 1%, less than about 5%, less than about 10 %, less than about 25%, less than about 50%, or less than about 90% of the total energy capacity of the composite energy storage system. In some cases, different subunits may have different energy capacities. In some examples, a subunit has an energy capacity of about 10 kW, 100 kW, 500 kW, 1 MW, 2 MW, 5 MW, 10 MW, 20 MW, 50 MW, 100 MW or more. Continuous ramping of energy from the maximum energy input to the maximum energy output may include controlling each subunit energy input and / or output (e.g., energy input and / or energy output) separately. In some cases, subunits can be operated in opposite directions (for example, one or more subunits can operate in power input mode, while one or more subunits can operate in power output mode). In one example, if each energy storage system subunit can be continuously ramped between a maximum energy input and / or output to below about 50% of the maximum energy input and / or output, respectively, three or more of such
Petition 870190103250, of 10/14/2019, p. 110/149
104/114 energy storage system subunits can be combined into a composite energy storage system unit that can be continuously ramped from maximum input energy to maximum output energy. In some implementations, the composite energy storage system may not have a fully continuous range between the maximum input energy and the maximum output energy, but it may have an increased number of operating points in this range compared to a non-composite system. .
Control Systems [0185] The present disclosure provides computer control systems (or controllers) that are programmed to implement methods of the disclosure. Figure 30 shows a 1901 computer system (or controller) that is programmed or otherwise configured to regulate various process parameters of storage and / or energy recovery systems disclosed in this document. Such process parameters can include temperatures, flow rates, pressures and changes in entropy.
[0186] The 1901 computer system includes a central processing unit (CPU, also processor and computer processor in this document) 1905, which can be a single-core or multi-core processor, or a plurality of processors for processing parallel. The 1901 computer system also includes memory or 1910 memory location (for example, random access memory, read-only memory, flash memory), the 1915 electronic storage unit (for example, hard disk), the
Petition 870190103250, of 10/14/2019, p. 111/149
105/114 1920 communication (for example, network adapter) to communicate with one or more other 1925 systems and peripheral devices, such as cache, other memory, data storage and / or electronic display adapters. Memory 1910, storage unit 1915, interface 1920 and peripheral devices 1925 are in communication with CPU 1905 via a communication bus (continuous lines), such as a motherboard. The 1915 storage unit can be a data storage unit (or data repository) for storing data. The 1901 computer system can be operationally coupled to a 1930 computer network (network) with the help of the 1920 communication interface. The 1930 network can be the Internet, an internet and / or extranet, or an intranet and / or extranet that is in communication with the Internet. The 1930 network in some cases is a telecommunication and / or data network. The 1930 network can include one or more computer servers, which can enable distributed computing, such as cloud computing. The 1930 network, in some cases with the help of the 1901 computer system, can implement a non-hierarchical network, which can enable devices coupled to the 1901 computer system to behave like a client or a server.
[0187] The 1901 computer system is coupled with a 1935 energy storage and / or recovery system, which can be as described earlier or elsewhere in this document. The 1901 computer system can be coupled with various operations of 1935 system units, such as flow regulators (for example,
Petition 870190103250, of 10/14/2019, p. 112/149
106/114 valves), temperature sensors, pressure sensors, compressor (s), turbine (s), electric switches and photovoltaic modules. The 1901 system can be coupled directly to the 1935 system or be a part of it, or it can communicate with the 1935 system through the 1930 network.
[0188] The 1905 CPU can execute a sequence of machine-readable instructions, which can be incorporated into a program or software. Instructions can be stored in a memory location, such as 1910 memory. Examples of operations performed by the 1905 CPU may include retrieval, decoding, execution and recording on the opposite side.
[0189] Continuing with reference to figure 30, the storage unit 1915 can store files, such as triggers, libraries and saved programs. The 1915 storage unit can store user-generated programs and registered sessions, as well as output (s) associated with the programs. The 1915 storage unit can store user data such as, for example, user preferences and user programs. The 1901 computer system may in some cases include one or more additional data storage units that are external to the 1901 computer system, such as located on a remote server that is communicating with the 1901 computer system through an intranet or the Internet.
[0190] The 1901 computer system can communicate with one or more remote computer systems via the 1930 network. For example, the 1901 computer system can communicate with a remote computer system from a
Petition 870190103250, of 10/14/2019, p. 113/149
107/114 user (for example, operator). Examples of remote computer systems include personal computers, whiteboards or tablets, phones, smart phones or personal digital assistants. The user can access the 1901 computer system through the 1930 network.
[0191] Methods as described in this document can be implemented using machine executable code (for example, computer processor) stored in an electronic storage location on the 1901 computer system, such as, for example, in 1910 memory or on the 1915 electronic storage unit. Machine-executable or machine-readable code can be provided in the form of software. During use, the code can be executed by the 1905 processor. In some cases, the code can be retrieved from the 1915 storage unit and stored in the 1910 memory for ready access by the 1905 processor. In some situations, the 1915 electronic storage unit can deleted, and machine executable instructions are stored in 1910 memory.
[0192] The code can be precompiled and configured for use with a machine having a processor adapted to execute the code, or it can be compiled during execution time. The code can be provided in a programming language that can be selected to enable the code to run in a precompiled mode or as it is compiled.
[0193] Aspects of the systems and methods provided in this document, such as the 1901 computer system, can be incorporated into programming. Various aspects of technology
Petition 870190103250, of 10/14/2019, p. 114/149
108/114 can be thought of as products or articles of manufacture typically in the form of machine executable code (or processor) and / or associated data that is loaded into or incorporated into a machine-readable media type. Machine executable code can be stored in an electronic storage unit, such as memory (for example, read-only memory, random access memory, flash memory) or a hard drive. Storage-type media can include some or all of the tangible memory of computers, processors or the like, or associated modules of the same, such as various semiconductor memories, tape drives, disk drives and more, which can provide non-transitory storage at any time for software programming. All or parts of the software from time to time may be transmitted via the Internet or several other telecommunication networks. Such communications, for example, can enable software to be loaded from one computer or processor to another; for example, from a management server or host computer to an application server's computer platform. Thus, another type of media that can load the software elements includes optical, electrical and electromagnetic waves, as used through physical interfaces between local devices, through wired and optical landline networks and through various air links. . The physical elements that carry such waves, such as wired or wireless links, optical links or the like, can also be considered as media loading the software. As used in this
Petition 870190103250, of 10/14/2019, p. 115/149
109/114 document, unless limited to tangible non-transitory storage media, terms such as computer or machine-readable media refer to any medium that participates in providing instructions to a processor for execution.
[0194] Consequently, a machine-readable medium, such as computer executable code, can take many forms, including, but not limited to, a tangible storage medium, a carrier wave medium, or physical transmission medium. Non-volatile storage media includes, for example, optical or magnetic disks, just like any of the storage devices on any computer or the like, as can be used to implement databases, etc. shown in the drawings. Volatile storage media includes dynamic memory, as does main memory on a computer platform like this. Tangible transmission media include coaxial cables, copper wires and optical fibers, including wires that comprise a bus within a computer system. Transmission media for carrier waves may take the form of electrical or electromagnetic signals, or acoustic or light waves such as those generated during radio frequency (RF) and infrared (IR) data communications. Common forms of computer-readable media, therefore, include, for example: a floppy disk, a floppy disk, hard disk, magnetic tape, any other magnetic media, a CD-ROM, DVD or DVD-ROM, any other optical media, tape perforated card paper, any other physical media with hole patterns, a RAM, a ROM, a
Petition 870190103250, of 10/14/2019, p. 116/149
110/114
PROM and EPROM, a FLASH-EPROM, any other chip or memory cartridge, a carrier wave carrying data or instructions, cables or links carrying a carrier wave like this, or any other medium on which a computer can read code and / or data programming. Many of these forms of computer-readable media can be involved in loading one or more strings of one or more instructions into a processor for execution.
III. Illustrative Power Generation System [0195] Figure 31 illustrates a power generation system that includes shared hot-side thermal storage 160 and shared cold-side thermal storage 161. Shared hot-side thermal storage 160 can include a hot thermal storage tank (HTS) 106 and an HTS tank 107. HTS tanks 106 and 107 can be configured to retain, dispense and / or receive an HTS 121 medium. Shared hot side thermal storage 160 can also include a flow supply HTS 132 configured to receive a flow of HTS 121 medium from the HTS tank 106 and an HTS return flow 133 configured to send a flow of the HTS medium to the HTS 107 tank. Shared cold-side thermal storage 161 may comprise a tank cold thermal storage (CTS) 108 and a CTS 109 tank. CTS 108 and 109 tanks can be configured to retain, dispense and / or receive a CTS medium 1 22. Shared cold-side thermal storage 161 may also include a CTS 137 supply stream configured to receive a CTS 122 medium flow from the CTS 10 9 tank and a CTS 136 return flow configured to send a medium flow
Petition 870190103250, of 10/14/2019, p. 117/149
111/114
CTS 122 for the CTS 108 tank.
[0196] The power generation system may also include a plurality of energy subunits 140. Each energy subunit may include a Brayton system as described with reference to other figures and description here, except that thermal media stores may be outside of individual energy subunits 140 and shared across the plurality of energy subunits 140. For example, an energy subunit 140 may include a generator 11 configured to generate electrical energy, a compressor 1, a hot-side heat exchanger 2, a turbine 3, a cold side heat exchanger 4 and a working fluid 20 circulating in a closed loop path. The closed loop path may include a working fluid circulating in sequence through the compressor, the hot side heat exchanger, the turbine and the cold side heat exchanger. A stove 5 can also be included in the closed loop path. Examples and additional details of energy subunits are shown in at least Figures 2, 3, 6, 7, 13, 14, 15, 16, 20, 21, 22, 23, 24, 25, 27 and 28, and described in this document in relation to each of the figures identified above. Figures 2, 3, 6, 7, 13, 14, 15, 16, 20, 21, 22, 23, 24, 25, 27 and 28 are illustrative only, and other fluids, components and / or fluid paths may be gifts. Some components, such as a hot or cold side heat exchanger, can be replaced by other components that serve a similar thermal purpose. Each of the fluids, components and / or fluid paths identified above
Petition 870190103250, of 10/14/2019, p. 118/149
112/114 can be the same or similar to closed cycle elements described above (for example, Brayton cycle), such as working fluid 20, compressor 1, hot-side heat exchanger 2, turbine 3, exchanger of cold side heat 4 and the stove 5.
[0197] Each energy subunit 140 can also include a configurable valve arrangement to be in a connected state or in an isolated state. The valve arrangement may include valves 142a, 142b, 142c and 142d. In the connected state the valve arrangement can be configured to connect the energy subunit 140 to the supply flow HTS 132, the return flow HTS 133, the supply flow CTS 137 and the return flow CTS 136. For example, the arrangement can be configured to open the respective valves 142a - 142d for a given energy subunit and connect the hot side heat exchanger 2 to the supply flow HTS 132 and the return flow HTS 133 and to connect the heat exchanger from cold side 4 to supply flow CTS 137 and return flow CTS 136. Hot side valves 142a and 142b can be connected to a hot side heat exchanger 2, and each hot side valve 142a and 142b can be connected or switchable to allow the HTS 121 medium to flow countercurrently for a given mode of operation (i.e., loading or unloading). The cold side valves 142c and 142d can be connected to a cold side heat exchanger 4, and each cold side valve 142c and 142d can be connected or switchable to allow the CTS 122 medium to flow in countercurrent for a given flow mode. operation (ie loading or unloading).
Petition 870190103250, of 10/14/2019, p. 119/149
113/114 [0198] In the isolated state, the valve arrangement can be configured to isolate the energy subunit 140 from the supply flow HTS 132, the return flow HTS 133, the supply flow CTS 137 and the flow return CTS 136. For example, the valve arrangement can be configured to close valves 142a - 142d to a respective energy sub-unit and isolate the hot-side heat exchanger 2 from the supply flow HTS 132 and the return flow HTS 133 and to isolate the cold side heat exchanger 4 from the supply flow CTS 137 and the return flow CTS 136.
[0199] Each energy subunit 140 may also include an electric bus 150 electrically coupled to each generator 11 of each energy subunit 140 of the plurality of energy subunits. The electrical bus 150 can be configured to charge electrical energy generated by each generator 11 to an electrical node 152. For example, the electrical bus 150 can carry DC energy, AC energy, or preferably three-phase AC energy at 60 - 600 Hz. The node electrical 152 can comprise a frequency converter and the frequency converter can be configured to convert electrical energy charged by the electrical bus 150 into electrical energy for distribution to a mains system; for example, converting the energy to 60 Hz.
[0200] The power generation system may additionally comprise one or more CTS 155 heat exchangers configured to remove excess heat from the CTS 122 medium. The CTS 155 heat exchangers can be, for example, a
Petition 870190103250, of 10/14/2019, p. 120/149
114/114 cooling tower or a radiator. In one embodiment, a CTS 155 heat exchanger can be coupled to the CTS 108 tank. In another embodiment, a CTS 155 heat exchanger can be coupled to the CTS 136 return flow.
[0201] Advantages of the power generation system revealed using power subunits versus a large power generation system include less time required to initialize the system, continued power generation in the event that a power subunit fails and cancellation of transient phenomenon out of phase. In addition, the energy subunits can be used in parallel or in sequence (or in some combination), thus allowing to vary energy levels. Output energy can be low or high frequency.
IV. Conclusion [0202] Although several aspects and modalities have been revealed in this document, other aspects and modalities will be apparent to those skilled in the art. The various aspects and modalities disclosed in this document are for the purpose of illustration and are not intended to be limiting, with the true scope and spirit being indicated by the following claims.

权利要求:
Claims (8)
[1]
1. Power generation system characterized by the fact that it comprises:
a hot side thermal store comprising a first hot thermal storage tank (HTS), a second HTS tank, a HTS medium, a configured HTS source stream receives a flow of the HTS medium from the first HTS tank, a stream the return of HTS configured to send a flow from the HTS medium to the second HT S tank;
a cold side thermal store comprising a first cold thermal storage tank (CTS), a second CTS tank, a CTS medium, a CTS source stream configured to receive a flow of the CTS medium from the second CTS tank, a stream from the return CTS configured to send a flow from the CTS medium to the first CTS Tank;
a plurality of subunits of power, each subunit of power comprising:
a generator configured to generate electricity, a compressor, a heat exchanger on the hot side, a turbine, a heat exchanger on a cold side, a working fluid circulating in a closed cycle path, in which the closed cycle path comprises, in sequence, the compressor, the heat exchanger on the hot side, the turbine, and the heat exchanger on the cold side, and a valve arrangement configurable to be in a connected state or in an isolated state, where in the connected state the valve arrangement is configured to connect the heat exchanger on the hot side to the power source stream
Petition 870190060213, of 06/27/2019, p. 12/15
[2]
2/3
HTS and the HTS return stream and to connect the cold side heat exchanger to the CTS source stream and the CTS return stream, where in the isolated state, the valve arrangement is configured to isolate the hot side heat exchanger from the stream HTS source and HTS return stream and to isolate heat from the cold side exchanger of the CTS supply flow and the CTS return flow; And an electric bus electrically coupled to each generator of each power subunit of the plurality of power subunits, where the electric bus is configured to transport the electric energy generated by each generator to an electric node.
2. Power generation system, according to claim 1, characterized by the fact that each power subunit of the plurality of energy subunits still comprises a recuperator, in which the closed cycle path of each power subunit of the plurality of energy energy subunits In addition, it comprises, in sequence, the compressor, the stove, the heat exchanger on the hot side, the turbine, the stove, and the heat exchanger on the cold side.
[3]
3. Power generation system, according to claim 1, characterized by the fact that it also comprises a CTS heat exchanger, in which the CTS heat exchanger is configured to remove heat from the CTS medium.
[4]
4. Power generation system, according to claim 3, characterized by the fact that the CTS heat exchanger is coupled to the first CTS tank.
[5]
5. Power generation system, according to claim 3, characterized by the fact that the exchanger
Petition 870190060213, of 06/27/2019, p. 13/15
3/3 CTS heat is coupled to the CTS return flow.
[6]
The power generation system of claim 3, characterized by the fact that the CTS heat exchanger comprises a cooling tower.
[7]
The power generation system of claim 3, characterized by the fact that the CTS heat exchanger comprises a radiator.
[8]
8. Power generation system, according to claim 1, characterized by the fact that the electrical node comprises a frequency converter, in which the frequency converter is configured to convert the electrical energy carried by the electrical bus to electrical energy for the distribution of a power grid system.

类似技术:

---

公开号 | 公开日 | 专利标题

---

US10428694B2|2019-10-01|Pumped thermal and energy storage system units with pumped thermal system and energy storage system subunits

---

AU2017387788B2|2020-08-13|Use of external air for closed cycle inventory control

---

BR112019013453A2|2019-12-31|modular thermal storage

---

AU2017386955B2|2020-08-20|Variable pressure inventory control of closed cycle system with a high pressure tank and an intermediate pressure tank

---

AU2017386233B2|2020-10-29|Storage of excess heat in cold side of heat engine

---

BR112019013447A2|2019-12-31|closed loop power generation system pump control

---

BR112019013625A2|2020-01-21|variable pressure turbine

同族专利:

---

公开号 | 公开日

---

EP3563042A4|2020-08-19|

---

AU2020294244A1|2021-01-28|

---

US20200025076A1|2020-01-23|

---

WO2018125638A3|2018-08-16|

---

AU2017386262A1|2019-07-18|

---

WO2018125638A2|2018-07-05|

---

CA3087034A1|2018-07-05|

---

AU2017386262B2|2020-09-24|

---

US20210054785A1|2021-02-25|

---

US10830134B2|2020-11-10|

---

US20180187597A1|2018-07-05|

---

US10436109B2|2019-10-08|

---

CN207513700U|2018-06-19|

---

CN110546351A|2019-12-06|

---

EP3563042A2|2019-11-06|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US1576019A|1924-07-18|1926-03-09|Zimetbaum Samuel|Molding apparatus|

---

US1758567A|1927-08-12|1930-05-13|Frank C Fernandez|Method and apparatus for making frozen confections|

---

US1881965A|1931-08-08|1932-10-11|Peterson Ezra Moroni|Apparatus for making frozen confections|

---

US2065974A|1933-12-23|1936-12-29|Marguerre Fritz|Thermodynamic energy storage|

---

US2172910A|1935-07-12|1939-09-12|Ag Fuer Technische Studien|Power plant|

---

US2203731A|1937-01-25|1940-06-11|Ag Fuer Technische Studien|Means for regulating and starting thermal power plants|

---

US2171253A|1938-10-22|1939-08-29|Gen Motors Corp|Tubular radiator|

---

US2246513A|1939-10-28|1941-06-24|Charles A Hammond|Mold for making cellular cores for radiators|

---

US2319995A|1941-04-07|1943-05-25|Tech Studien Ag|Overload working method for thermal power plants|

---

US2336178A|1941-05-08|1943-12-07|Tech Studien Ag|Thermal power plant|

---

US2414170A|1941-12-10|1947-01-14|Ag Fuer Technische Studien|Method for the regulation of the output of thermal power plants|

---

US2446108A|1942-02-27|1948-07-27|Tech Studien Ag|Power plant working with a hot gaseous medium|

---

US2454358A|1943-05-18|1948-11-23|Sulzer Ag|Output regulation of circuit type gas-turbine plants|

---

US2453886A|1943-10-11|1948-11-16|Tech Studien Ag|Thermal power plant and its working medium, with method of operation|

---

US2566817A|1948-12-09|1951-09-04|Leader Electric Company|Mold for making plastic grids|

---

US2689680A|1949-06-16|1954-09-21|Rolls Royce|Means for regulating the characteristics of multistage axialflow compressors|

---

US2697326A|1951-04-30|1954-12-21|Ca Nat Research Council|Reactor with adjustable stator blades|

---

NL89878C|1951-06-04|1900-01-01|

---

US2791204A|1951-08-16|1957-05-07|Smith Corp A O|Water heater utilizing heat of crystallization|

---

US2788195A|1952-08-29|1957-04-09|Karmazin John|Condenser and method of making same|

---

US2820348A|1953-08-11|1958-01-21|Techische Studien Ag F|Utilizing intermittently produced waste heat|

---

US2911792A|1956-03-06|1959-11-10|Philips Corp|Thermodynamic apparatus with closed pipe system|

---

NL274928A|1961-02-20|

---

CH384941A|1961-05-25|1965-02-26|Escher Wyss Ag|A device having a working fluid reservoir for changing the pressure level in a closed gas turbine system with a working fluid circuit|

---

US3152442A|1962-05-04|1964-10-13|Richard J Rowekamp|System for converting solar energy into useful energy|

---

GB992941A|1963-11-29|1965-05-26|Bristol Siddeley Engines Ltd|Improvements in rotary bladed compressors and turbines|

---

US3537517A|1968-03-29|1970-11-03|Gen Electric|Heat dissipating assembly|

---

GB1275753A|1968-09-14|1972-05-24|Rolls Royce|Improvements in or relating to gas turbine engine power plants|

---

AT308772B|1970-11-06|1973-07-25|Waagner Biro Ag|Method and device for generating peak power|

---

US3955359A|1973-06-20|1976-05-11|Westinghouse Electric Corporation|Bearing temperature system failure detection apparatus suitable for use in power plants and like apparatus|

---

US3897170A|1974-01-09|1975-07-29|Arthur Darvishian|Wind motor|

---

US4126291A|1974-10-18|1978-11-21|California Injection Molding Co., Inc.|Injection mold for elongated, hollow articles|

---

CH599460A5|1975-12-23|1978-05-31|Bbc Brown Boveri & Cie|

---

US4024908A|1976-01-29|1977-05-24|Milton Meckler|Solar powered heat reclamation air conditioning system|

---

US4054124A|1976-04-06|1977-10-18|Knoeoes Stellan|Solar radiation collection system|

---

US4124061A|1976-11-01|1978-11-07|Rockwell International Corporation|Thermal energy storage unit|

---

US4117682A|1976-11-01|1978-10-03|Smith Otto J M|Solar collector system|

---

US4089744A|1976-11-03|1978-05-16|Exxon Research & Engineering Co.|Thermal energy storage by means of reversible heat pumping|

---

US4110987A|1977-03-02|1978-09-05|Exxon Research & Engineering Co.|Thermal energy storage by means of reversible heat pumping utilizing industrial waste heat|

---

US4094148A|1977-03-14|1978-06-13|Stone & Webster Engineering Corporation|Thermal storage with molten salt for peaking power|

---

US4158384A|1977-08-18|1979-06-19|Brautigam Robert F|Heat storage system|

---

DE2810890A1|1978-03-13|1979-09-27|Messerschmitt Boelkow Blohm|THERMAL STORAGE|

---

US4215553A|1978-06-26|1980-08-05|Sanders Associates, Inc.|Energy conversion system|

---

US4405010A|1978-06-28|1983-09-20|Sanders Associates, Inc.|Sensible heat storage unit|

---

DE2904232A1|1979-02-05|1980-12-18|Hans Michael Dipl Ing Woerwag|Thermal power station - combines cooling and working process to lower upper temp. level thus making it independent of outside coolant source|

---

NL7905277A|1979-07-05|1981-01-07|Doomernik Bv|ACCUMULATOR FOR STORING HEAT OR COLD.|

---

DE2928691A1|1979-07-16|1981-02-12|Mohamed Omar Ing Grad Jannoun|Exhaust steam condensation heat utilisation - uses condenser as evaporator and feed heater as condenser for refrigerating gas|

---

US4444024A|1981-08-04|1984-04-24|Mcfee Richard|Dual open cycle heat pump and engine|

---

US4628692A|1980-09-04|1986-12-16|Pierce John E|Solar energy power system|

---

DE3118101A1|1981-04-16|1983-02-03|Ellrich, Wolfgang, Dipl.-Ing., 2000 Braak|Power/heat feedback|

---

US4715576A|1981-07-15|1987-12-29|Corning Glass Works|Apparatus for forming a flexible mask|

---

US4670205A|1981-07-15|1987-06-02|Corning Glass Works|Method of forming a mask|

---

US4362290A|1981-07-17|1982-12-07|Westminster Marketing, Inc.|Mold for plastic needlepoint sheet|

---

JPS5815702A|1981-07-21|1983-01-29|Mitsui Eng & Shipbuild Co Ltd|Hot water storage electricity generation equipment|

---

US4727930A|1981-08-17|1988-03-01|The Board Of Regents Of The University Of Washington|Heat transfer and storage system|

---

US4430241A|1982-07-01|1984-02-07|Olin Corporation|Mixed nitrate salt heat transfer medium and process for providing the same|

---

US4438630A|1982-09-07|1984-03-27|Combustion Engineering, Inc.|Method and system for maintaining operating temperatures in a molten salt co-generating unit|

---

US4523629A|1982-09-30|1985-06-18|The United States Of America As Represented By The United States Department Of Energy|Method and apparatus for operating an improved thermocline storage unit|

---

US4643212A|1984-03-28|1987-02-17|Chicago Bridge & Iron Company|Hot liquid thermal energy storage tank and method|

---

US4566668A|1984-03-29|1986-01-28|Koppenberg Bruce G|Apparatus for casting concrete|

---

US4583372A|1985-01-30|1986-04-22|At&T Technologies, Inc.|Methods of and apparatus for storing and delivering a fluid|

---

JPH03286103A|1990-04-03|1991-12-17|Zenshin Denryoku Eng:Kk|Steam turbine power generator|

---

US5160689A|1990-11-16|1992-11-03|Revlon Consumer Products Corporation|Apparatus and method for manufacturing cosmetic products|

---

DE4121460C2|1991-06-28|1993-05-06|Deutsche Forschungsanstalt Fuer Luft- Und Raumfahrt E.V., 5300 Bonn, De|

---

US5131231A|1991-08-02|1992-07-21|Allied-Signal|Method for operating a closed Brayton engine and engine adapted for use with method|

---

EP0630449B1|1992-03-02|1997-05-07|Dayco Products, Inc.|Belt construction formed mainly of thermoplastic material and method of making the same|

---

US7937930B1|1992-08-07|2011-05-10|The United States Of America As Represented By The Secretary Of The Navy|Semiclosed Brayton cycle power system with direct heat transfer|

---

US5653670A|1992-09-04|1997-08-05|Endelman; Ken|Exercise apparatus|

---

US5644928A|1992-10-30|1997-07-08|Kajima Corporation|Air refrigerant ice forming equipment|

---

IL108546A|1994-02-03|1997-01-10|Israel Electric Corp Ltd|Compressed air energy storage method and system|

---

JP2611185B2|1994-09-20|1997-05-21|佐賀大学長|Energy conversion device|

---

IL118982A|1996-07-30|2000-02-17|Hazan Haim|Water heater and storage tank|

---

GB2340911B|1998-08-20|2000-11-15|Doncasters Plc|Alloy pipes and methods of making same|

---

JP3512349B2|1999-01-29|2004-03-29|株式会社大協精工|Mold for columnar rubber element|

---

CN1154791C|1999-04-28|2004-06-23|联邦科学及工业研究组织|Thermodynamic apparatus|

---

US20030131623A1|2001-09-05|2003-07-17|Suppes Galen J.|Heat pump using phase change materials|

---

DE10039246C2|2000-08-11|2002-06-13|Atz Evus|Process for converting thermal energy into mechanical work|

---

EP1390681A4|2001-05-02|2007-12-26|Aquatherm Ind Inc|Overmolding insert for heat exchanger|

---

DE10122959A1|2001-05-11|2002-11-21|West Pharm Serv Drug Res Ltd|Method for producing a piston for a pharmaceutical syringe or a similar item includes a step in which surplus of the inert foil cap on the piston body is separated in a punching unit|

---

US6634410B1|2001-08-28|2003-10-21|John H. Wilson|Mold apparatus and method|

---

US6606860B2|2001-10-24|2003-08-19|Mcfarland Rory S.|Energy conversion method and system with enhanced heat engine|

---

US6532745B1|2002-04-10|2003-03-18|David L. Neary|Partially-open gas turbine cycle providing high thermal efficiencies and ultra-low emissions|

---

US7078825B2|2002-06-18|2006-07-18|Ingersoll-Rand Energy Systems Corp.|Microturbine engine system having stand-alone and grid-parallel operating modes|

---

US6749011B2|2002-08-09|2004-06-15|Sunonwealth Electric Machine Industry Co., Ltd.|Heat sink|

---

US6644062B1|2002-10-15|2003-11-11|Energent Corporation|Transcritical turbine and method of operation|

---

US20050126171A1|2002-11-01|2005-06-16|George Lasker|Uncoupled, thermal-compressor, gas-turbine engine|

---

US6796123B2|2002-11-01|2004-09-28|George Lasker|Uncoupled, thermal-compressor, gas-turbine engine|

---

US6701711B1|2002-11-11|2004-03-09|The Boeing Company|Molten salt receiver cooling system|

---

DE10254797B4|2002-11-22|2004-11-18|GEA Luftkühler GmbH|heat exchangers|

---

US7051529B2|2002-12-20|2006-05-30|United Technologies Corporation|Solar dish concentrator with a molten salt receiver incorporating thermal energy storage|

---

DE10260535A1|2002-12-21|2004-07-08|Mtu Aero Engines Gmbh|Process for the production of heat exchanger tubes consisting of half tubes or tubes for recuperative exhaust gas heat exchangers|

---

US20060248886A1|2002-12-24|2006-11-09|Ma Thomas T H|Isothermal reciprocating machines|

---

US6907923B2|2003-01-13|2005-06-21|Carrier Corporation|Storage tank for hot water systems|

---

US7086231B2|2003-02-05|2006-08-08|Active Power, Inc.|Thermal and compressed air storage system|

---

US8671686B2|2003-02-05|2014-03-18|Active Power, Inc.|Systems and methods for providing backup energy to a load|

---

US20050034847A1|2003-08-11|2005-02-17|Robert Graham|Monolithic tube sheet and method of manufacture|

---

US7028481B1|2003-10-14|2006-04-18|Sandia Corporation|High efficiency Brayton cycles using LNG|

---

US20070269297A1|2003-11-10|2007-11-22|Meulen Peter V D|Semiconductor wafer handling and transport|

---

US8403613B2|2003-11-10|2013-03-26|Brooks Automation, Inc.|Bypass thermal adjuster for vacuum semiconductor processing|

---

WO2005087305A1|2004-03-12|2005-09-22|Agency For Science, Technology And Research|Methods and moulds for use in fabricating side-ported microneedles|

---

EP1577548A1|2004-03-16|2005-09-21|Abb Research Ltd.|Apparatus and method for storing thermal energy and generating electricity|

---

US8424284B2|2004-05-20|2013-04-23|Gilbert Staffend|High efficiency positive displacement thermodynamic system|

---

CN1778986B|2004-06-02|2015-08-19|应用材料公司|For the method and apparatus of sealed chamber|

---

GB2416463B|2004-06-14|2009-10-21|Weatherford Lamb|Methods and apparatus for reducing electromagnetic signal noise|

---

US7188478B2|2004-09-13|2007-03-13|General Electric Company|Power generation system and method of operating same|

---

WO2006059498A1|2004-11-30|2006-06-08|Matsushita Electric Industrial Co., Ltd.|Heat exchanger and method of producing the same|

---

US7267086B2|2005-02-23|2007-09-11|Emp Advanced Development, Llc|Thermal management system and method for a heat producing system|

---

GB0506006D0|2005-03-23|2005-04-27|Howes Jonathan S|Apparatus for use as a heat pump|

---

JP5151014B2|2005-06-30|2013-02-27|株式会社日立製作所|HEAT PUMP DEVICE AND HEAT PUMP OPERATION METHOD|

---

US8863547B2|2006-04-05|2014-10-21|Ben M. Enis|Desalination method and system using compressed air energy systems|

---

DE102006022783A1|2006-05-16|2007-05-03|Ed. Züblin Ag|Large volume heat accumulator for heat accumulator for again warming of compressed air, consists of two caps placed over one another which possess form of perpendicularly standing pipe with rounded caps at ends|

---

JP4322902B2|2006-08-10|2009-09-02|川崎重工業株式会社|Solar power generation equipment and heat medium supply equipment|

---

JP5116277B2|2006-09-29|2013-01-09|株式会社半導体エネルギー研究所|Semiconductor device, display device, liquid crystal display device, display module, and electronic apparatus|

---

ITMI20062046A1|2006-10-24|2008-04-25|Iveco Motorenforschung Ag|MOTOR SYSTEM WITH HEAT RECOVERY SYSTEM AND RELATIVE HEAT RECOVERY METHOD|

---

US7685820B2|2006-12-08|2010-03-30|United Technologies Corporation|Supercritical CO2 turbine for use in solar power plants|

---

US8261552B2|2007-01-25|2012-09-11|Dresser Rand Company|Advanced adiabatic compressed air energy storage system|

---

MX2009009627A|2007-03-08|2009-11-26|Univ City|Solar power plant and method and/or system of storing energy in a concentrated solar power plant.|

---

US7603858B2|2007-05-11|2009-10-20|Lawrence Livermore National Security, Llc|Harmonic engine|

---

FR2916101B1|2007-05-11|2009-08-21|Saipem Sa|INSTALLATION AND METHODS FOR STORAGE AND RESTITUTION OF ELECTRICAL ENERGY|

---

PL2220343T3|2007-10-03|2013-11-29|Isentropic Ltd|Energy storage apparatus and method for storing energy|

---

FR2922608B1|2007-10-19|2009-12-11|Saipem Sa|INSTALLATION AND METHOD FOR STORING AND RETURNING ELECTRIC ENERGY USING PISTON GAS COMPRESSION AND RELIEF UNIT|

---

WO2009064378A2|2007-11-09|2009-05-22|Ausra, Inc.|Efficient low temperature thermal energy storage|

---

JP2009121786A|2007-11-19|2009-06-04|Ihi Corp|Cryogenic refrigerator and control method for it|

---

WO2009074803A1|2007-12-11|2009-06-18|Isentropic Limited|Valve|

---

EP2235448B1|2007-12-26|2020-07-22|Carrier Corporation|Refrigerant system with intercooler and liquid/vapor injection|

---

RU2476687C2|2008-03-28|2013-02-27|Мицубиси Хеви Индастрис, Лтд.|Method to control turbine plant and turbine plant|

---

EP2304196A4|2008-05-02|2014-09-10|United Technologies Corp|Combined geothermal and solar thermal organic rankine cycle system|

---

US7870746B2|2008-05-27|2011-01-18|Expansion Energy, Llc|System and method for liquid air production, power storage and power release|

---

GB0810391D0|2008-06-06|2008-07-09|Isentropic Ltd|Fluid servo and applications|

---

ES2363455T3|2008-07-16|2011-08-04|Abb Research Ltd.|SYSTEM OF STORAGE OF THERMOELECTRIC NERGY AND METHOD OF STORAGE OF THERMOELECTRIC ENERGY.|

---

ES2424137T5|2008-08-19|2020-02-26|Abb Schweiz Ag|Thermoelectric energy storage system and procedure for storing thermoelectric energy|

---

US8833079B2|2008-09-18|2014-09-16|Douglas W. P. Smith|Method and apparatus for generating electricity|

---

NO331154B1|2008-11-04|2011-10-24|Hamworthy Gas Systems As|System for combined cycle mechanical operation in cryogenic condensation processes.|

---

US20110262269A1|2008-11-20|2011-10-27|Etv Energy Ltd.|Valves for gas-turbines and multipressure gas-turbines, and gas-turbines therewith|

---

US8661777B2|2009-01-19|2014-03-04|Yeda Research Development Co. Ltd|Solar combined cycle power systems|

---

US8522552B2|2009-02-20|2013-09-03|American Thermal Power, Llc|Thermodynamic power generation system|

---

CA2653643C|2009-02-26|2010-08-31|Westport Power Inc.|Pressure control system and method|

---

US20120017622A1|2009-03-06|2012-01-26|Osaka Gas Co., Ltd.|Solar Light Absorption Material and Heat Absorption/Accumulation Material and Solar Light Absorption/Control Building Component Using the Same|

---

DE202009018043U1|2009-03-09|2010-12-02|Rawema Countertrade Handelsgesellschaft Mbh|Heat storage system|

---

EP2241737B1|2009-04-14|2015-06-03|ABB Research Ltd.|Thermoelectric energy storage system having two thermal baths and method for storing thermoelectric energy|

---

US8136358B1|2009-05-22|2012-03-20|Florida Turbine Technologies, Inc.|Heat reservoir for a power plant|

---

US9657966B2|2009-06-01|2017-05-23|Solarreserve|Single bi-temperature thermal storage tank for application in solar thermal plant|

---

US20110259007A1|2009-06-05|2011-10-27|Mitsubishi Heavy Industries, Ltd.|Concentrated solar power gas turbine and concentrated-solar-power-gas turbine power generation equipment|

---

EP2275649B1|2009-06-18|2012-09-05|ABB Research Ltd.|Thermoelectric energy storage system with an intermediate storage tank and method for storing thermoelectric energy|

---

EP2293407A1|2009-09-08|2011-03-09|Converteam Technology Ltd|Power transmission and distribution systems|

---

CA2814454A1|2009-10-13|2011-09-01|Wayne Thomas Bliesner|Reversible hydride thermal energy storage cell optimized for solar applications|

---

US8613195B2|2009-09-17|2013-12-24|Echogen Power Systems, Llc|Heat engine and heat to electricity systems and methods with working fluid mass management control|

---

JP5205353B2|2009-09-24|2013-06-05|株式会社日立製作所|Heat pump power generation system|

---

EP2312129A1|2009-10-13|2011-04-20|ABB Research Ltd.|Thermoelectric energy storage system having an internal heat exchanger and method for storing thermoelectric energy|

---

US8347629B2|2009-10-30|2013-01-08|General Electric Company|System and method for reducing moisture in a compressed air energy storage system|

---

US8596068B2|2009-10-30|2013-12-03|Gilbert Staffend|High efficiency thermodynamic system|

---

US20110100010A1|2009-10-30|2011-05-05|Freund Sebastian W|Adiabatic compressed air energy storage system with liquid thermal energy storage|

---

JP5356983B2|2009-11-18|2013-12-04|大陽日酸株式会社|Cryogenic refrigeration apparatus and operation method thereof|

---

KR101370843B1|2009-12-14|2014-03-25|이동학|Device for discharging heat|

---

WO2011077248A2|2009-12-23|2011-06-30|Goebel, Olaf|Combined cycle solar power generation|

---

US8484986B2|2010-02-19|2013-07-16|Phase Change Storage Llc|Energy storage systems|

---

EP2362070A1|2010-02-19|2011-08-31|Siemens Aktiengesellschaft|Drive device for pivoting adjustable vanes of a turbomachine|

---

WO2011104556A2|2010-02-24|2011-09-01|Isentropic Limited|Improved heat storage system|

---

US10094219B2|2010-03-04|2018-10-09|X Development Llc|Adiabatic salt energy storage|

---

JP6068332B2|2010-05-06|2017-01-25|ヒートマトリクス グループ ビー．ヴィ．|Heat exchanger tube plate, heat exchanger, and method of manufacturing heat exchanger tube plate|

---

US20110289941A1|2010-05-28|2011-12-01|General Electric Company|Brayton cycle regasification of liquiefied natural gas|

---

EP2390473A1|2010-05-28|2011-11-30|ABB Research Ltd.|Thermoelectric energy storage system and method for storing thermoelectric energy|

---

US9927157B2|2010-06-02|2018-03-27|Dwayne M. Benson|Integrated power, cooling, and heating device and method thereof|

---

EP2400120A1|2010-06-23|2011-12-28|ABB Research Ltd.|Thermoelectric energy storage system|

---

EP2580554B1|2010-07-12|2019-01-16|Siemens Aktiengesellschaft|Thermal energy storage and recovery device and system having a heat exchanger arrangement using a compressed gas|

---

GB201012743D0|2010-07-29|2010-09-15|Isentropic Ltd|Valves|

---

US20120039701A1|2010-08-12|2012-02-16|Nuovo Pignone S.P.A.|Closed Cycle Brayton Cycle System and Method|

---

US20120055661A1|2010-09-03|2012-03-08|Peter Feher|High temperature thermal energy storage system|

---

WO2012040110A2|2010-09-20|2012-03-29|State Of Oregon Acting By And Through The State Board Of Higher Education On Behalf Of Oregon State University|A system and method for storing energy and purifying fluid|

---

US20120080161A1|2010-10-04|2012-04-05|Edmund Joseph Kelly|Thermal storage system|

---

EP2441926A1|2010-10-14|2012-04-18|ABB Research Ltd.|Thermo electric energy storage system|

---

EP2441925A1|2010-10-14|2012-04-18|ABB Research Ltd.|Waste heat recovery system|

---

US8739533B2|2010-12-02|2014-06-03|Or Yogev|Solar augmented wind turbine for stable and dispatchable utility scale power generation|

---

GB201104867D0|2011-03-23|2011-05-04|Isentropic Ltd|Improved thermal storage system|

---

HU229826B1|2011-03-23|2014-09-29|Matyas Gutai|Thermal energy system for heating a building and/or maintaining heat balance of building|

---

EP2532843A1|2011-06-09|2012-12-12|ABB Research Ltd.|Thermoelectric energy storage system with an evaporative ice storage arrangement and method for storing thermoelectric energy|

---

US20120319410A1|2011-06-17|2012-12-20|Woodward Governor Company|System and method for thermal energy storage and power generation|

---

US20130019770A1|2011-07-22|2013-01-24|Halliburton Energy Services, Inc.|Device for perforating a material comprising a tail-locking charge case|

---

US9745899B2|2011-08-05|2017-08-29|National Technology & Engineering Solutions Of Sandia, Llc|Enhancing power cycle efficiency for a supercritical Brayton cycle power system using tunable supercritical gas mixtures|

---

US20130045388A1|2011-08-16|2013-02-21|Jon Carl Thenhaus|Materials and methods for manufacturing polyculture equipment|

---

EP2570759A1|2011-09-15|2013-03-20|Siemens Aktiengesellschaft|Thermal energy storage and recovery arrangement|

---

EP2574740A1|2011-09-29|2013-04-03|Siemens Aktiengesellschaft|Assembly for storing thermal energy|

---

EP2594753A1|2011-11-21|2013-05-22|Siemens Aktiengesellschaft|Thermal energy storage and recovery system comprising a storage arrangement and a charging/discharging arrangement being connected via a heat exchanger|

---

KR101345106B1|2011-12-20|2013-12-26|한국기계연구원|Heat engine based on transcritical rankine cycle with improved exergy efficiency and method thereof|

---

US9048694B2|2012-02-01|2015-06-02|Abb Research Ltd|DC connection scheme for windfarm with internal MVDC collection grid|

---

RU2012104762A|2012-02-10|2013-08-20|Александр Петрович Самойлов|METHOD FOR STORAGE, STORAGE AND RETURN OF MECHANICAL ENERGY AND INSTALLATION FOR ITS IMPLEMENTATION |

---

GB2499618A|2012-02-22|2013-08-28|Isentropic Ltd|Screen valve|

---

US9347690B2|2012-04-02|2016-05-24|Alliance For Sustainable Energy, Llc|Methods and systems for concentrated solar power|

---

DE102012007129A1|2012-04-10|2013-10-10|Rolls-Royce Deutschland Ltd & Co Kg|Guide vane adjusting a gas turbine|

---

GB2501476A|2012-04-23|2013-10-30|Isentropic Ltd|A piston assembly|

---

GB201207114D0|2012-04-23|2012-06-06|Isentropic Ltd|Improved thermal energy storage apparatus|

---

GB2501687B|2012-04-30|2014-12-10|Isentropic Ltd|Improvements relating to the transmission of energy|

---

GB2501683A|2012-04-30|2013-11-06|Isentropic Ltd|Energy storage apparatus|

---

GB201207497D0|2012-04-30|2012-06-13|Isentropic Ltd|Valve control|

---

WO2013164653A1|2012-05-02|2013-11-07|Remenyi Peter|Method for cooling air and apparatus to perform the method|

---

KR20150008911A|2012-05-23|2015-01-23|후아웨이 테크놀러지 컴퍼니 리미티드|Method, system and device for switching wavelength of multi-wavelength passive optical network |

---

US9003796B2|2012-06-05|2015-04-14|General Electric Company|Heat recovery using organic rankine cycle|

---

NO337357B1|2012-06-28|2016-03-29|Nest As|Plant for energy production|

---

EP2698506A1|2012-08-17|2014-02-19|ABB Research Ltd.|Electro-thermal energy storage system and method for storing electro-thermal energy|

---

US8820083B2|2012-09-26|2014-09-02|Supercritical Technologies, Inc.|Thermodynamic cycle with compressor recuperation, and associated systems and methods|

---

WO2014052927A1|2012-09-27|2014-04-03|Gigawatt Day Storage Systems, Inc.|Systems and methods for energy storage and retrieval|

---

US9376962B2|2012-12-14|2016-06-28|General Electric Company|Fuel gas heating with thermal energy storage|

---

EP2759679A1|2013-01-23|2014-07-30|Siemens Aktiengesellschaft|Thermal storage device for the utilisation of low temperature heat|

---

DE102013001569A1|2013-01-30|2014-07-31|Daimler Ag|Method for operating a waste heat utilization device|

---

WO2014146129A2|2013-03-15|2014-09-18|Transtar Group, Ltd|Distillation reactor module|

---

WO2014161065A1|2013-04-03|2014-10-09|Sigma Energy Storage Inc.|Compressed air energy storage and recovery|

---

GB201306146D0|2013-04-05|2013-05-22|Isentropic Ltd|Apparatus and method for storing energy|

---

DE202013004654U1|2013-05-17|2014-08-18|Thomas Lauinger|Heat storage system|

---

US9863669B2|2013-05-31|2018-01-09|Mayekawa Mfg. Co., Ltd.|Brayton cycle type refrigerating apparatus|

---

US9482117B2|2013-05-31|2016-11-01|Supercritical Technologies, Inc.|Systems and methods for power peaking with energy storage|

---

FR3011626B1|2013-10-03|2016-07-08|Culti'wh Normands|THERMODYNAMIC SYSTEM FOR STORAGE / ELECTRIC POWER GENERATION|

---

US20150113940A1|2013-10-25|2015-04-30|Mada Energie Ltd|Systems, methods, and devices for liquid air energy storage in conjunction with power generating cycles|

---

KR20150089110A|2014-01-27|2015-08-05|김영선|Scalable ORC distribute electricity generation system |

---

GB201410086D0|2014-06-06|2014-07-23|Isentropic Ltd|Hybrid electricity storage and power generation system|

---

CA2953590A1|2014-06-30|2016-01-07|Kerbs Autotech Pty Ltd|An internal combustion engine heat energy recovery system|

---

US9803584B2|2015-04-01|2017-10-31|Briggs & Stratton Corporation|Combined heat and power system|

---

CN108778560A|2016-03-18|2018-11-09|西门子股份公司|Method of the manufacture for the improvement features in the core of casting|

---

US10260820B2|2016-06-07|2019-04-16|Dresser-Rand Company|Pumped heat energy storage system using a conveyable solid thermal storage media|

---

US10082045B2|2016-12-28|2018-09-25|X Development Llc|Use of regenerator in thermodynamic cycle system|

---

US11053847B2|2016-12-28|2021-07-06|Malta Inc.|Baffled thermoclines in thermodynamic cycle systems|

---

US10233787B2|2016-12-28|2019-03-19|Malta Inc.|Storage of excess heat in cold side of heat engine|

---

US20180180363A1|2016-12-28|2018-06-28|X Development Llc|Modular Shell-and-Tube Heat Exchanger Apparatuses and Molds and Methods for Forming Such Apparatuses|

---

US10458284B2|2016-12-28|2019-10-29|Malta Inc.|Variable pressure inventory control of closed cycle system with a high pressure tank and an intermediate pressure tank|

---

US10233833B2|2016-12-28|2019-03-19|Malta Inc.|Pump control of closed cycle power generation system|

---

US20180185942A1|2016-12-29|2018-07-05|X Development Llc|High Temperature Casting and Electrochemical Machining Heat Exchanger Manufacturing Method|

---

US10221775B2|2016-12-29|2019-03-05|Malta Inc.|Use of external air for closed cycle inventory control|

---

US10280804B2|2016-12-29|2019-05-07|Malta Inc.|Thermocline arrays|

---

US10082104B2|2016-12-30|2018-09-25|X Development Llc|Atmospheric storage and transfer of thermal energy|

---

US10801404B2|2016-12-30|2020-10-13|Malta Inc.|Variable pressure turbine|

---

US10436109B2|2016-12-31|2019-10-08|Malta Inc.|Modular thermal storage|US10094219B2|2010-03-04|2018-10-09|X Development Llc|Adiabatic salt energy storage|

---

WO2014052927A1|2012-09-27|2014-04-03|Gigawatt Day Storage Systems, Inc.|Systems and methods for energy storage and retrieval|

---

CN106461293B|2014-06-10|2019-01-08|株式会社Lg化学|Heat recovery apparatus|

---

US11053847B2|2016-12-28|2021-07-06|Malta Inc.|Baffled thermoclines in thermodynamic cycle systems|

---

US10233833B2|2016-12-28|2019-03-19|Malta Inc.|Pump control of closed cycle power generation system|

---

US10233787B2|2016-12-28|2019-03-19|Malta Inc.|Storage of excess heat in cold side of heat engine|

---

US10458284B2|2016-12-28|2019-10-29|Malta Inc.|Variable pressure inventory control of closed cycle system with a high pressure tank and an intermediate pressure tank|

---

US10221775B2|2016-12-29|2019-03-05|Malta Inc.|Use of external air for closed cycle inventory control|

---

US10801404B2|2016-12-30|2020-10-13|Malta Inc.|Variable pressure turbine|

---

US10436109B2|2016-12-31|2019-10-08|Malta Inc.|Modular thermal storage|

---

DE102019210564A1|2019-07-17|2021-01-21|Siemens Aktiengesellschaft|Method for operating a storage facility and storage facility|

---

DE102019127431B4|2019-10-11|2021-05-06|Enolcon Gmbh|Thermal power storage with fixed bed heat storage and fixed bed cold storage and method for operating a thermal power storage|

---

WO2022002325A1|2020-06-29|2022-01-06|Stiesdal Storage Technologies A/S|Operation of a thermal energy storage system|

法律状态:
2021-10-13| B350| Update of information on the portal [chapter 15.35 patent gazette]|

---

2021-11-09| B06W| Patent application suspended after preliminary examination (for patents with searches from other patent authorities) [chapter 6.23 patent gazette]|

优先权:

---

申请号 | 申请日 | 专利标题

---

US15/396,461|US10436109B2|2016-12-31|2016-12-31|Modular thermal storage|

---

PCT/US2017/067049|WO2018125638A2|2016-12-31|2017-12-18|Modular thermal storage|

---