• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A geothermal plant connectable to a geothermal well system and comprising at least two removable modules, at least two module bays and a pipework: - at least one of the removable modules having a heat exchanger; - the module bays including a supporting structure a supporting a removable module; - the pipework including a first pipe assembly being connectable to the first pipe system of the geothermal well at a first connecting end and a second pipe assembly being connectable to an existing facility pipework; - the module bays supporting the removable module having a heat exchangerbeing provided with a connecting interface for allowing the at least removable modules to be interconnected to the pipework.
    公开号:DK201870171A1
    申请号:DKP201870171
    申请日:2018-03-16
    公开日:2019-09-26
    发明作者:Kaster Martin
    申请人:Apmh Invest Iv Aps;
    IPC主号:
    专利说明:

    Geothermal plant connectable to a geothermal well.
    Summary
    The invention relates to a geothermal plant connectable to a geothermal well system and comprising at least two removable modules, at least two module bays and a pipework.
    Background
    A geothermal plant or a geothermal production facility has the ability to transform heat from the geothermal water (40-70°C) to hot water with district heating specifications (70-90°C).
    District heating plants can provide high efficiencies when the heat is distributed to the customer via a network of district heating pipes, preferably insulated pipes. District heating systems consist of a number of feed and return pipelines. Usually the pipes are installed underground but there are also systems having pipes arranged above ground level.
    Geothermal plants typically comprise a heat pump and at least one heat exchanger and by using one or a series of heat exchangers in combination with a heat pump, it is possible to extract energy from the geothermal water and to transfer the heat to the district heating water, thereby being heatable to a high temperature. The cooled geothermal water is hereafter filtered and re-injected in the ground, where the cooled geothermal water is reheated by the higher temperature of the underground.
    It is known within the technical field of geothermal plants comprising a number of individual modules to establish a geothermal plant having an number of modules to be installed at a specific location.
    One example of a geothermal plant is disclosed in US2010/0132390, which discloses a 4-pipe geothermal heat pump, where the additional two pipes and the associated switching and isolation control system allows for each modules in the modular system to be independently operated.
    DK 2018 70171 A1
    One of the disadvantages of this geothermal plant is that is does not reduce the foot print of the installation nor does it provide a modular system design, which can be accommodated into a city environment.
    The general object of the present invention is to provide a geothermal plant being connectable to an existing heating system geothermal plant and capable of being accommodated in a city environment to function as a decentral geothermal facility, and which may be readily connected to a city district heating facility pipework.
    A further object of the present invention is to provide a modular geothermal facility, which can be integrated in the city environment by having a reduced foot print compared to traditional geothermal facility.
    The above need and object together with numerous other needs and objects will be evident from below detailed description, are according to a first aspect of the present invention obtained by :
    - at least one of said removable modules having a heat exchanger;
    - said module bays including a supporting structure a supporting a removable module;
    - said pipework including a first pipe assembly being connectable to said first pipe system of said geothermal well at a first connecting end and a second pipe assembly being connectable to an existing facility pipework;
    - at least said module bays supporting a removable module having the heat exchanger having a connecting interface for allowing said at least removable modules to be interconnected to said pipework.
    The above mentioned geothermal plant has the advantage that the foot print is reduced significantly due the use of removable modules, which can be accommodated in the module bays being provided for supporting the removable modules.
    DK 2018 70171 A1
    The present geothermal plant minimizes many of the possible downsides with large local heating facilities due to a low impact to the surrounding, as it is possible to accommodate the geothermal plane in parks, recreational areas or in residential areas.
    By using a number of removable modules it is possible to accommodate a geothermal plant in an urban environment.
    The term “district heating”, “heat distribution” or “existing network” should in this context be understood as a heat networks or a system for distributing the heat generated in a centralized location.
    The term “bunker” should in this context be understood as a cellar construction or a basement, which is partially below the ground level of the geothermal plant.
    The term “removable module” should in this context be understood as an equipment module having the mechanical and/or electrical components arranged inside the module. The modules can be hoisted in an out of the geothermal plant during installation or removed dependent on the specific situation. The module would have a standard design to increase the change-out time and will furthermore enable high uptime and flexibility of the system.
    Detailed description
    Embodiments of the present invention will now be explained in further detail by reference to the schematic drawings .
    FIG. 1 shows a presently preferred embodiment of the geothermal plant of the invention, in the form of a bunker,
    FIG. 2 shows a cross-sectional view of the bunker and the pipework position beneath the supporting structure,
    DK 2018 70171 A1
    FIG. 3 shows a cross-sectional view of the bunker shown in FIG. 2 with some additional features,
    FIGS. 4-5 show the installation of the removable modules,
    FIG. 6 shows the modules of the systems being interconnected below facility walk ways,
    FIG. 7 shows a bunker setup for 2-well systems with a central heat pump,
    FIG. 8 shows a second geothermal plant,
    FIG. 9 shows a second embodiment of the geothermal plant having horizontal dual compressors installed inside the bunker, and
    FIG. 10 shows a third embodiment of the geothermal plant having a modular design and defined by a building at the facility.
    FIG. 1 shows the geothermal plant 100 according to the present invention where the geothermal plant is integrated in a city environment to enable local heat delivery. The geothermal plant 100 comprises a bunker 11 established by digging into the ground the excavated soil having been used to create the bunker 11. The plant 100 provides an advantages effect of reducing the noise level generated by the geothermal plant as the bunker will function as a sound barrier in relation to the surrounding. By using the soil to build the bunker a minimum of soil will have to be removed during the installation of the geothermal plant. The height of the geothermal plant will depend on the height of the modules to be discussed further below. The minimum estimated area required for the geothermal plant would often be in the range of: 28-30 metres x 23-26 metres ~ 645-780 square meters, preferably 29 metres by 24 metres ~ 700 square meters.
    DK 2018 70171 A1
    As will be evident from the figures, the present invention preferably in one embodiment is intended to appear as a bunker or as a cellar-construction to allow the geothermal plant to be arranged in an urban environment.
    As shown in FIG. 1, the shown bunker 11 can include an access element in the form of an access door 12. The geothermal plant is connected to a geothermal well 14 located adjacent to the bunker 12 and to a transfer pipeline 15 for transferring discharged cold geothermal water. The geothermal well is covered by an access hatch to prevent personnel from falling into the well itself.
    As can been seen the FIGS. 1-10, a number district heating pine lines 16 and at least one transfer line 15 for the cold geothermal water are connected to the geothermal plant 100, 200. The district heating pipe line 16 will form part of an existing heat distribution network also referred to as a heat network and the present geothermal plant will be interconnected to the existing distribution network. Within the system heat storage units may be installed to even out peak load demands.
    Turning now to FIGS. 2-3, the bunker 11 forms an exterior wall for the geothermal plant and the bunker surrounds removable modules, which are to be installed in the internal space formed by the soil removed during the construction of the bunker 11. The inner compartment 10 of the geothermal plant may as shown be formed by sheet piling driven into the ground, for providing an inner wall for obtaining stability prior to the step of accommodating the removable modules of the geothermal plant. The inner compartment 10 is formed by four inner walls 13, 13’ positioned in a rectangular or quadric geometry and the four inner walls provide the necessary stiffening needed for supporting and preventing the bunker hill from collapsing towards the inner compartment 10.
    The inner compartment of the bunker 11 has in the shown embodiment a height hg of 7-13 m, preferably 9-11 m and the exterior height of the bunker relative to the ground level G is approximately 4-5 m, whereas the distance between two opposite inner walls is in the range of 11-15 meters, preferably 1213 meters.
    DK 2018 70171 A1
    Pipework 20 includes a first pipe assembly 22 comprising a first pipe system 25 being connectable to the geothermal well 14 at a first connecting end and a second pipe assembly 24, which is connectable to an existing facility pipework, also referred to as district heating pine lines 16.
    The first pipe assembly 22 is connectable to the geothermal well 14 through the use of at least two first interconnecting pipelines 23. The second pipe assembly 24 is connectable to the district heating pine lines 16 through the use of at least two second interconnecting pipelines 25. The pipework 20 furthermore comprises a number of connecting flanges 26,27 for enabling a connection between the module bays 30 and the removable modules (not shown in figure 2-
    3).
    The module bays 30 have a supporting structure 32 for supporting the removable modules and the supporting structures 31 includes a number of upright guide elements 34 being connected to the supporting structure 31. The supporting structure 32 is resting on a number of supporting element 29 arranged on the base element 28 positioned in the lower part of the inner compartment
    10. The supporting structure provide the geothermal planet with a facility walkway for the personal operating the geothermal plant, but can also be used during service.
    As shown in FIG. 3 the internal compartment 10 has a number of access hatches 17 in the upper part of the inner compartment 10, and the hatches 17 can be opened by pivoting the hatches, hereby providing access for the removable modules to be hoisted and lowered into the bunker 11.
    As shown in FIGS. 4-5, the removable modules 40 of the geothermal plant are connected to the pipework 20, which has been installed at the bottom of the inner compartment of the bunker prior to installing the removable modules in the geothermal plant. All pipework and cabling between the removable modules 40 and corresponding control equipment is arranged and runs below the supporting structure 32, whereby the supporting structure 32 functions as a walk
    DK 2018 70171 A1 way inside the geothermal plant (building) and thereby eases the installation and servicing of the facility equipment.
    The geothermal plant 100 (facility) is based on a modular design enabling the removable modules, preferably corresponding in size to or fitting into standard 6 or 12 meters intermodal freight containers, to be assembled off-site and then transported e.g. by a truck 50 to the installation site of the geothermal plant in a lying down position. When the modules arrive, they are raised upright and installed vertically in the facility bunker with a hoisting unit 60 such as a mobile crane. After installation, the module transport frame is removed for allowing better access to the modules.
    As shown in FIG. 5, each of the removable modules 40 may comprise a module transport frame 42,44 including a first module frame 42 forming a permanent module frame and a second module frame 44 being a removable transport frame (crash frame). By using a module transport frame, which is removable it is possible to enable compact facility footprint.
    At least some of the removable modules 40 further comprise an electrical connections junction box positioned in the first module frame and a number of lifting eyes for hoisting the removable modules 40 during installation or service.The module components are mounted in vertical position for reducing the footprint of each of the removable modules.
    When the removable modules 40 are to be installed into the bunker facility, the modules are turned 90 degrees as can be seen in FIG. 4. The models are hereafter lowered into the bunker facility. The installation can be done together with local contractors who can be quickly mobilized to perform the installation of the geothermal plant.
    After a removable module is installed in the geothermal facility, the transport frame 44 is removed and the pipework 20 and electrical connections are interconnected to the equipment located inside the removable module.
    DK 2018 70171 A1
    Turning now to FIG. 6, the removable modules 40 are fitted into the bunker facility 11 by using a number of upright module guides 46 which may be similar to those used for guiding freight containers on a container ship. The modules guides 46 provide an easy and precise installation of the removable modules 40 . Each of the modules would preferably have an installation foot-print of about 3x3 meters and a module height of about 6-12 meters depending on the facility.
    In FIG. 7, the geothermal facility according to a second embodiment of the present invention has a geothermal well 14 been formed as a dual well cellar, a geothermal heat production facility (depicted to the right) and a geothermal reinjection facility 90 comprising an injection pump module 92 depicted to the right side in the FIG. 7.
    Each of the modules has a specific function and are interconnected, preferably exclusively at locations below the supporting structure. The shown geothermal facility includes nine individual equipment modules and a pipework being connected to a first district heating pipeline 161 for delivering heated water to the geothermal facility and a second district heating pipeline 162 for returning the water. The electronics and SCADA modules 301, 302 are located in a separate room 303 with HVAC. Pipework 20 between modules and electrical connections are located in a cellar below supporting structure forming the walkway grating and the removable modules. The removable modules are intended to be installed in a vertical position through the hatches in the upper part of the bunker 11. The other removable modules could be a compressor module 304, a condenser HEX 305, an evaporator HEX module 306, a pump module 307 for circulating the geothermal liquid, a pump module 308 for pumping the district heat water, a geothermal HEX module 309 and a filter unit module 310 for filtering the liquid being pump up from the underground.
    Now referring to FIG.8, a geothermal plant 300 having an reinjection facility 302 is positioned at the vicinity of the geothermal heat exchanging 304. The geothermal well comprises a geothermal production line 94 and a geothermal injec
    DK 2018 70171 A1 tion line 96. The geothermal plant 300 comprises of 2 sets of 3 individual equipment modules - one for each well pair.
    Each of the modules shown in FIG. 8 has a specific function and is interconnected below the supporting structure. The geothermal plant 300 includes nine individual equipment modules and a pipework connected to a first district heating pipeline 161 for delivering heated water to the geothermal facility and a second district heating pipeline 162 for returning the water.
    Pipework 20 between the modules and the electrical connections are located in the cellar below supporting structure forming the walkway grating and the removable modules, when the removable modules are installed in vertical position and installed/replaced through hatches in the upper part of the bunker 11.
    The electronics and SCADA modules 402 are located in a separate room 403 with HVAC. The other removable modules would be a pump module 401, a HEX module 404, an injection pump module 405, a HEX module 406, a pump module 407 for circulating the geothermal liquid, a heat transmission pump module 408, and two filter unit module 409, 410 for filtering the liquid being pump up from the underground.
    FIG. 9 shows a further embodiment of the geothermal plant having a horizontal dual compressors installed inside the bunker. Each of the removable modules having a compressor unit is arranged in a horizontal position.
    In the further embodiment of the present invention, the geothermal plant 200 comprises a evaporator unit 202, a condensator unit 204 and a compressor unit 206. The compressor unit 206 will be hoisted down through the access hatch 208 positioned in the upper part of the geothermal plant and the compressor unit 206 will be lowered down into the internal through the bunker 11. It should be noted that the geothermal well is not depicted in the FIG. 9 for the sake of simplicity.
    DK 2018 70171 A1
    The evaporator unit 202 will be placed on top of the condensator unit 204, which would be arranged between the evaporator unit 202 and the compressor unit 206. Preferably, the evaporator unit 202 will be dual evaporator unit, the condensator unit 204 will be a dual condensator unit type and the compressor unit 206 will be a dual compressor unit. A number of module splitters/dividers 210 may divide the individual modules 20, 204 and 226.
    The distance between the access hatch and the module bays 30 with the pipe flanges may be in the range of 10-15 m.
    FIG. 10 shows an alternative implementation of the geothermal plant, where geothermal facility have the same components as shown in FIG. 2, but with the difference that the bunker 11 is replaced by a conventional building wall structure or scaffold or the like.
    The skilled person would realize, that the module bays depicted in the figures of the present invention is not divided into a number of separate module-bays, but us depicted as one single structure.
    It is within the scope of the present invention, the module-bays can be delivered as separate module-bay sections to be assembled at the geothermal installation site. By having a number of separate module-bay sections, it is easier to handle the module bays prior to a assembling step of the module-bays. Each of the module-bays is provided with means allowing the module-bays to be interconnected with one another.
    Although the invention has been described above with reference to a number of specific and advantageous embodiments, it is understood that the present invention is by no means limited to the above disclosure of the above described advantageous embodiments, as the features of the above embodiments may be combined to provide additional embodiments. The additional embodiments are all construed to be part of the present invention. Furthermore, the present invention is to be understood compassed by any equivalent or similar structure as described above and also to be encompassed by the scope limited by the below claims defining the protective scope of the present patent application.
    DK 2018 70171 A1
    Reference numbers
    In the following is given a list of reference numbers that are used in the detailed description of the invention.
    geothermal plant 100, 200, 300 ground level G inner compartment 10 bunker 11 access door 12 inner wall 13 13’ geothermal well 14 transfer pipe line 15 district heating pipeline 16, 161, 162 access hatch 17 pipework 20 first pipe assembly 22 first interconnecting pipeline 23 second pipe assembly 24 second interconnecting pipelines 25 connecting flanges 26,27 base element 28 supporting element 29 module bays 30 supporting structure 32 guide element 34 removable modules 40, 401,40, 403, 404, 405, 406, 407, 408, 409 first module frame 42 second module frame 44 module guide 46 tapper guide end 47 truck 50 hoisting unit 60 geothermal reinjection facility 90 injection pump module 92
    DK 2018 70171 A1 evaporator unit 202 condensator unit 204 compressor unit 206 access hatch 208 reinjection facility 302 geothermal heat exchanging 304
    权利要求:
    Claims (10)
    [1] Claims
    1. A geothermal plant (100,200,300) connectable to a geothermal well (400) and comprising at least two removable modules (40), at least two module bays (30) and a pipework (20):
    - at least one of said removable modules (40) including a heat exchanger;
    - said module bays (30) including a supporting structure supporting a respective one of said removable modules;
    - said pipework including a first pipe assembly being connectable to said first pipe system of said geothermal well at a first connecting end and a second pipe assembly being connectable to an existing facility pipework;
    - said module bay(s) (30) supporting said removable module(s) that include a heat exchanger being provided with a connecting interface for allowing said at least one removable module(s) having a heat exchanger to be connected to said pipework.
    [2] 2. A geothermal plant according to claim 1, wherein said geothermal plant further comprises a bunker (11) for surrounding the removable modules (40).
    [3] 3. A geothermal plant according to claim 1 or 2, said removable modules (40) being divided into a first set of removable modules and a second set of removable modules, wherein said first set of removable modules (40) includes a heat exchanger.
    [4] 4. A geothermal plant according to any previous claims, wherein each of said removable modules (40) comprises an module transport frame including a first module frame (42) forming a permanent module frame and a second module frame (44) being a removable transport frame.
    [5] 5. A geothermal plant according to any previous claims, said supporting structure comprising a number of upright module guides (46) for guiding
    DK 2018 70171 A1 said removable modules (40) on installation thereof into said respective module bays (30).
    [6] 6. A geothermal plant according to any previous claims, said pipework (20) including a number of connecting flanges (26,27).
    [7] 7. A geothermal plant according to claim 2, said plant further comprising a number of hatches being provided at a first vertical distance above said supporting structure, preferably in the range of 10-15 m.
    [8] 8. A geothermal plant according to any of the previous claims, said first pipe assembly (22) including a second connecting end with a first connecting flange being located at the opposite end of said second connecting end for interconnecting said first pipe assembly (22) .
    [9] 9. A geothermal plant according to any of the previous claims, said geothermal well comprises a geothermal production line (94) and geothermal injection line (96).
    [10] 10. A modular geothermal installation comprising a number of removable modules, a number of bay modules, a geothermal well and a pipe network;
    - each removable module having a number of electrical and/or mechanical components
    - each bay modules having a supporting structure, wherein said supporting structure forms a first support level for supporting each of the removable modules;
    - said bay modules being provided for receiving the removable modules.
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    同族专利:
    公开号 | 公开日
    HRP20210081T1|2021-03-05|
    HUE052438T2|2021-04-28|
    PL3540331T3|2021-05-17|
    EP3540331B1|2020-11-04|
    EP3540331A1|2019-09-18|
    DK180226B1|2020-08-24|
    EP3540331B8|2020-12-23|
    ES2847573T3|2021-08-03|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    NZ248730A|1992-10-02|1996-03-26|Ormat Ind Ltd|High pressure geothermal power plant with primary steam turbine and at least one power plant module having low pressure turbine|
    US20100132390A1|2008-09-18|2010-06-03|Multistack Llc|Variable four pipe heatpump chiller|
    US20110224942A1|2010-03-11|2011-09-15|Kidwell John E|GPS-tracking ground heat exchanger performance test instrumentation network supporting a plurality of wireless portable GPS-based enthalpy-based GHE performance test instrumentation systems|
    US9677778B2|2010-04-20|2017-06-13|Climacool Corp.|Modular chiller unit with dedicated cooling and heating fluid circuits and system comprising a plurality of such units|
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    法律状态:
    2019-09-26| PAT| Application published|Effective date: 20190917 |
    2020-08-24| PME| Patent granted|Effective date: 20200824 |
    优先权:
    申请号 | 申请日 | 专利标题
    DKPA201870171A|DK180226B1|2018-03-16|2018-03-16|Geothermal plant that can be connected to a geothermal well|DKPA201870171A| DK180226B1|2018-03-16|2018-03-16|Geothermal plant that can be connected to a geothermal well|
    HUE19162822A| HUE052438T2|2018-03-16|2019-03-14|Geothermal plant connectable to a geothermal well|
    PL19162822T| PL3540331T3|2018-03-16|2019-03-14|Geothermal plant connectable to a geothermal well|
    EP19162822.1A| EP3540331B8|2018-03-16|2019-03-14|Geothermal plant connectable to a geothermal well|
    ES19162822T| ES2847573T3|2018-03-16|2019-03-14|Geothermal installation connectable to a geothermal well|
    HRP20210081TT| HRP20210081T1|2018-03-16|2021-01-18|Geothermal plant connectable to a geothermal well|
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