System and device for generating electricity with integrated circulation

专利摘要:
An apparatus for generating electricity comprises a solar collector (100) having a plurality of solar cells (38) and an MPPT device (600) alone or in combination with a DC / AC inverter (500) directly connected thereto, and a A plurality of heat dissipation plates (29) and a heat exchanger (26). The Wärmeableitplatten (29) are arranged between the solar cell (38) and the heat exchanger (26). The heat exchanger (26) is connected to a circulation system which allows a flow of refrigerant to flow through the heat exchanger (26). Each of the heat dissipation plates (29) has a first side in direct thermal contact with a corresponding solar cell (38) and an opposite second side in contact with the heat exchanger (26). The heat exchanger (26) has a plurality of coolant chambers (55) disposed adjacent to the heat dissipation plates (29). The first heat exchanger (26) has at least one second cooling chamber (56) disposed adjacent to the MPPT device (600) and / or the DC / AC inverter (500).
公开号:AT520904A2
申请号:T9307/2017
申请日:2017-09-18
公开日:2019-08-15
发明作者:Clyde Webb Roger；Anna Webb Maria
申请人:Qingdao Austech Solar Tech Co Ltd；
IPC主号:

专利说明:

TECHNICAL AREA
The present invention relates to an apparatus for generating electricity. In particular, this invention is initially directed to a photovoltaic solar collector with MPPT and / or inverter circuits mounted close to one another, in combination with heat dissipation plates and a heat exchanger with coolant chambers, the latter cooling the solar collector and the circuit in order to support the improvement of its efficiency. Second, this invention will be described with reference to a modular unit for mounting on a solar panel with an MPPT and / or inverter circuit mounted close together.
BACKGROUND
A "solar collector" is a set of photovoltaic solar cells that are electrically connected and mounted on a support structure. A photovoltaic module or solar collector is a packaged, coherent arrangement of solar cells. The solar panel can be used as part of a larger photovoltaic system for the generation and supply of electricity in commercial and private applications and such solar panels are therefore used worldwide.
A solar collector typically comprises a panel or an array of solar cells, an inverter and sometimes a battery and / or a solar tracking system or a solar tracker and connection wiring.
Under normal test conditions, each photovoltaic module is measured by its DC output power, which is typically between 100 and 320 watts. A disadvantage of a solar collector is that the efficiency of the solar collector decreases significantly with increasing temperature of the collecting surface. A conservative estimate by manufacturers (and used by some researchers) is that every 1 ° C increase in temperature corresponds to a 0.5% drop in efficiency. Based on our tests with standard 100 W solar panels, it is a more realistic estimate that whenever the cell temperature rises from 1 ° C to 25 ° C, the peak power will decrease by between 0.5% and 1.5%. If the cell temperature continues to rise, the efficiency is greatly reduced.
A solar collector is designed for operation with direct current (direct current or DC). Direct current cannot flow well over long distances. For example, up to 10% of a normal household photovoltaic system of the electrical energy given off by the panels or collectors can be lost through the wiring. In solar collector parks, in an attempt to reduce losses, many collectors are connected in series to form a larger group and generate a higher DC voltage to reduce long distance losses, but in such a system 5 - 8% can still get lost.
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- 2 MPPT (Maximum Power Point Tracking) devices are used to increase the output power of solar panels. In most conditions, the output power can only be increased by approximately 10%, but the MPMPT electronic device also consumes power during operation. Other devices commonly referred to as DC / AC inverters, such as Pure signal wave network connections, or network connections, have been implemented to convert the direct current supplied by the solar collectors into a high-voltage alternating current, which, because of the alternating current, can be delivered more easily over long distances. Large electronic devices are still experiencing losses.
Private and some smaller commercial solar power systems use some form of storage system and a DC / AC inverter system to be connected directly to the home network. All of these applications result in loss of electrical energy. With MPPT and mains connection devices, this loss occurs due to heat dissipation through the body and the mains connection of the devices, as well as through internal losses. An additional expense and additional costs of these devices are due to the heavy aluminum housing, which serves as a heat sink for dissipating the heat. These costs must also be viewed as negative returns. It is known that more electricity can be obtained from a series of solar cells by connecting them in series or by reducing the length of the connections by providing MPPT control for the individual cells or a small number of cells. This is discussed in paragraph [0031] of US Patent Publication No. 2014/0306540 (Wu et al.). One such solution is described in U.S. Patent No. 8,093,757 (Wolfs et al.), Which takes advantage of recent advances in low voltage electronics and uses maximum power tracking devices for very small groups of solar cells or for single cells to measure the output power of the array. Increase field. However, the Wolfs embodiment is primarily described with respect to a solar powered vehicle, in which the movement of the solar powered vehicle causes some form of cooling because the air flow flows over the solar cells.
Placing MPPT and inverter / grid connection devices closer to the DC output of the solar cells would improve efficiency, but the disadvantage is the temperature in such an environment. In the case of stationary solar modules of the type which is mounted on residential buildings and buildings, the temperature of the solar cell can be three times the ambient temperature. This means that at an ambient temperature of 20 ° C the cell temperature of a solar collector surface can already be over 60 ° C. This leads to difficulties in the arrangement of MPPT and inverter / grid connection devices in the immediate vicinity of solar cells. If solar collectors are installed in domestic and commercial situations, the MPPT and inverter device3 / 47 ···· ···· • · • · •
lines are typically mounted downstream of the collectors and their typical operating temperatures at these downstream locations are around 50-70 ° C. If the MPPT and inverter devices are installed near the high temperatures at which conventional solar modules are operated, this means that their internal temperature can be above 100 ° C, which significantly affects their efficiency and service life.
In addition, the losses are accumulated in conventional arrangements. For one, there are losses in the solar panels themselves, which were discussed in detail in connection with our earlier patent application No. PCT / AU2015 / 050309 from June 5, 2015, and for another there are additional losses due to the subsequent positioning of MPPT devices and / or direct current / AC inverter / power supply units.
One way to counter this is to mount MPPT and “Inverter / Grid Connect” devices near the DC output of the solar panel and to cool them. Any energy gain if the MPPT and inverter / grid connection devices are placed closer to the DC output must be considered in relation to the energy used to cool such devices. As such, there were no commercially viable cooling solutions, so it was common in the art to typically place MPPT and inverter devices much further downstream from the array of solar panels that required long DC wiring with the associated losses.
The present invention aims to provide an apparatus for generating electricity that improves or eliminates at least one of the shortcomings of the prior art.
SUMMARY OF THE INVENTION
In a first aspect, the present invention is an apparatus for generating electricity comprising:
a solar panel with multiple solar cells and an MPPT device alone or in combination with a direct current / alternating current inverter directly connected to it;
a plurality of first heat dissipation plates; and a first heat exchanger;
wherein the first heat dissipation plates are arranged between the solar collector and the first heat exchanger and the first heat exchanger is connected to a circulation system which is designed such that coolant can flow through the first heat exchanger and each of the first heat and each of the heat dissipation plates a first in direct thermal Contact with a corresponding side of the solar cells, and has a second side opposite / 47, which is in contact with the first heat exchanger, and wherein the first heat exchanger has a plurality of first coolant chambers, which are arranged next to the first heat dissipation plate and the first heat exchanger at least has a second coolant chamber which is arranged next to the MPPT device and / or the direct current / alternating current inverter.
A second heat dissipation is preferably arranged between the second coolant chamber and the MPPT device and / or a direct current / alternating current inverter.
The MPPT device and / or the direct current / alternating current inverter are preferably arranged in a housing in the first heat exchanger.
At least part of the heat exchanger is preferably made of plastic and the housing is integrally formed therein.
The outlet of the direct current / alternating current inverter is preferably a pure sine wave inverter.
Preferably, the AC output from the inverter is connected in series with the AC output of a similar device.
The device is preferably connected directly to an AC network.
Preferably, the heat exchanger has a plurality of supply pipes and discharge pipes for supplying and removing the coolant from the first coolant chambers, and the supply pipes and the discharge pipes are spaced from the first heat dissipation plates.
Each first heat dissipation plate preferably has at least one of this plurality of first coolant chambers assigned to it.
The supply pipelines are preferably used to discharge the coolant from a suction pipe in such a way that coolant which enters the respective first coolant chambers of adjacent first heat dissipation plates has essentially the same temperature.
The supply pipelines are preferably used for parallel supply, at substantially the same temperature, of the coolant from a suction pipe to the respective first coolant chambers from adjacent first heat dissipation plates.
Each first heat dissipation plate is preferably essentially square and has four of the first coolant chambers.
An expansion joint is preferably arranged between two adjacent first heat sinks.
The plurality of first heat dissipation plates are preferably arranged in a field arrangement with expansion joints in between.
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Preferably, the array of the plurality of first heat sink plates is formed from a single thin sheet of metal, each of the first heat sink plates being connected to each other by minimal connection.
The minimal connection is preferably a perforation or tab or a strip.
The first heat dissipation plates are preferably connected to the solar cells of the solar collector.
An electronic control unit is preferably electrically connected to the solar collector.
A pump arranged in the circulation system preferably circulates the coolant through the first heat exchanger.
A surface temperature sensor is preferably arranged on the solar collector and connected to the electronic control unit, such that the pump is operated above a predetermined temperature detected by the sensor.
The coolant emerging from the first heat exchanger preferably circulates through a second heat exchanger arranged in a water reservoir.
Thermal energy in the coolant is preferably transferred to the water contained in the storage container.
At least one thermoelectric module is preferably arranged between the first heat exchanger and at least one of the respective first heat dissipation plates, such that the opposite second side of the respective first heat dissipation plate is in direct contact with the thermoelectric module and at least one first coolant chamber of the first heat exchanger is adjacent to the thermoelectric module is arranged so that heat transfer can occur between the coolant fluid flowing through the first coolant chamber and the thermoelectric module.
Preferably, a heat difference between a first side of the thermoelectric module and an opposite second side thereof generates at least part of the electrical charge.
The plurality of first heat dissipation plates and the first heat exchanger are preferably formed in a modular unit which can be attached to the solar collector.
Preferably, the device is connected to a hot water system comprising at least one reservoir with at least one heating element for heating water, and electricity is supplied to the heating element. Preferably, the energy in the coolant is used to thermally aid in heating the water in the water reservoir. The hot water system is preferably also connected to a mains power supply.
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In a second aspect, the present invention is an apparatus for generating electricity comprising:
at least one solar collector with a plurality of solar cells and an MPPT device alone or in combination with a direct current / alternating current inverter directly connected to it; and a first heat exchanger;
the apparatus further comprising a plurality of first heat sink plates disposed between the solar panel and the first heat exchanger, and the first heat exchanger connected to a circulation system adapted to allow coolant to flow through the first heat exchanger, and each of the first heat sink plates has a first side that is in direct thermal contact with a corresponding one of the solar cells and an opposite second side that is in contact with the first heat exchanger, and wherein the first heat exchanger has a plurality of first coolant chambers and a plurality of supply pipelines and discharge pipelines, supply and withdraw the coolant to and from the first coolant chambers, each coolant chamber having an open end adjacent to one of the first heat dissipation plates and an opposite closed end and the supply piping and d The discharge pipes mentioned are spaced from the heat sinks, and the first heat exchanger has at least one second coolant chamber which is arranged next to the MPPT device and / or direct current / alternating current inverter.
A second heat dissipation is preferably arranged between the second coolant chamber and the MPPT device and / or a direct current / alternating current inverter.
The MPPT device and / or the direct current / alternating current inverter are preferably arranged in a housing in the first heat exchanger.
At least part of the heat exchanger is preferably made of plastic and the housing is integrally formed therein.
Each first heat dissipation plate is preferably assigned at least one of the plurality of first coolant chambers.
The supply and discharge pipelines are preferably arranged at or near the closed end of the first coolant chambers.
Preferably, the device is connected to a hot water system comprising at least one reservoir with at least one heating element for heating water, and electricity is supplied to the heating element. Preferably, the energy in the coolant is used to thermally aid in heating the water in the water reservoir. The hot water system is preferably also connected to a mains power supply.
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In another aspect, the present invention is an apparatus for generating electricity comprising:
at least one solar collector with a plurality of solar cells and an MPPT device alone or in combination with a direct current / alternating current inverter directly connected to it; and a first heat exchanger;
the apparatus further comprising a plurality of first heat sink plates disposed between the solar panel and the first heat exchanger, and the first heat exchanger connected to a circulation system capable of circulating coolant through the first heat exchanger, and wherein each of the first heat sink plates has a first Side that is in direct thermal contact with an associated solar cell, and an opposite second side that is in contact with the first heat exchanger, and the first heat exchanger to a plurality of first coolant chambers and a plurality of supply pipes and discharge pipes for supplying and removing coolant and from the first coolant chambers, each coolant chamber having an open end located adjacent to one of the first heat sink plates and an opposite closed end and the supply piping and said discharge pipes lines are arranged at a distance from the heat dissipation plates and the first heat exchanger has at least one second coolant chamber which is arranged next to the MPPT device and / or direct current / alternating current inverter.
A second heat dissipation is preferably arranged between the second coolant chamber and the MPPT device and / or a direct current / alternating current inverter.
The MPPT device and / or the direct current / alternating current inverter are preferably arranged in a housing in the first heat exchanger.
At least part of the heat exchanger is preferably made of plastic and the housing is integrally formed therein.
Preferably, the device is connected to a hot water system comprising at least one reservoir with at least one heating element for heating water, and electricity is supplied to the heating element. Preferably, this energy is used in the coolant to thermally assist the heating of the water in the water reservoir. The hot water system is preferably also connected to a mains power supply.
According to a further aspect, the present invention consists in a device for cooling a solar collector with a plurality of solar cells and an MPPT device alone or in combination with a direct current / alternating current inverter directly connected thereto, which device has a plurality of first heat dissipation plates and
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9 9 9 9 9 9
9 9 9 9 9 9 9 · «· · ····· ·· ···· · · · · · ·· ·· · · · · · ♦ ·
- 8 comprises a first heat exchanger; wherein the first heat dissipation plates are arranged in a field arrangement, each first heat dissipation plate having a first side that is suitable for contacting a respective solar cell, each first heat dissipation plate being arranged within the circumferential boundary of its associated solar cell and the first heat exchanger a plurality of first coolant chambers and has a plurality of supply pipes and discharge pipes suitable for supplying and removing coolant to and from the first coolant chambers, each first heat dissipation plate having at least one of the plurality of first coolant chambers associated therewith, each coolant chamber having an open end adjacent to it is arranged, and has an opposite closed end, and the feed pipes and the discharge pipes are spaced from the heat sink plates, and the first W has at least one second coolant chamber, which is arranged adjacent to the MPPT device alone or in combination with a direct current / alternating current inverter.
A second heat dissipation is preferably arranged between the second coolant chamber and the MPPT device and / or a direct current / alternating current inverter.
The MPPT device and / or the direct current / alternating current inverter are preferably arranged in a housing in the first heat exchanger.
At least part of the heat exchanger is preferably made of plastic and the housing is integrally formed therein.
At least one expansion gap or an expansion joint is preferably arranged between two adjacent heat dissipation plates.
The heat dissipation plates are preferably formed from a single thin metal sheet and are minimally connected to one another.
The supply pipelines are preferably used to supply the coolant from a suction pipe in parallel at substantially the same temperature to the respective first coolant chambers of adjacent heat dissipation plates.
Preferably, the device is connected to a hot water system comprising at least one reservoir with at least one heating element for heating water, and the electricity is supplied to the heating element. Preferably, the energy in the coolant is used to thermally aid in heating the water in the water reservoir. The hot water system is preferably also connected to a mains power supply.
According to a further aspect, the present invention consists of a modular unit for attachment to a solar collector with a plurality of solar cells, the modular unit comprising:
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9 'a heat exchanger with a suction pipe and an outlet pipe; and an MPPT device alone or in combination with a DC / AC inverter for direct connection to the panel;
a plurality of first heat dissipation plates formed in a mesh array with expansion joints therebetween;
wherein each of the first heat exchanger plates has a coolant side in contact with the first heat exchanger and an opposite connection side for direct thermal contact with a corresponding one of the solar cells, and the first heat exchanger has a plurality of first coolant chambers adjacent to the first heat dissipation plates, and each heat dissipation plate with at least one one of the plurality of first coolant chambers is associated, and the first heat exchanger has at least one second coolant chamber, which is arranged adjacent to the MPPT device alone or in combination with a direct current / alternating current inverter.
A second heat dissipation is preferably arranged between the second coolant chamber and the MPPT device and / or a direct current / alternating current inverter.
The MPPT device and / or the direct current / alternating current inverter are preferably arranged in a housing in the first heat exchanger.
At least part of the heat exchanger is preferably made of plastic and the housing is integrally formed therein.
Preferably, the heat exchanger has a plurality of supply pipes and discharge pipes in fluid communication between the first coolant chambers and the suction pipe and the outlet pipe, and the supply pipe and the discharge pipe are spaced apart from the first heat dissipation plates.
In a modular unit, the network arrangement includes the plurality of first heat dissipation plates formed from a single thin sheet of metal, each of which is connected to each other by a minimal connection.
Preferably the minimal connection is a perforation or tab.
The supply pipelines are preferably designed such that they supply a coolant fluid from a suction pipe in parallel to the coolant chambers at substantially the same temperature.
The modular unit is preferably connected to a circulation system, and a pump arranged in the circulation system is adapted to circulate the coolant through the first heat exchanger.
The modular unit is preferably connected to a hot water system which comprises at least one storage container with at least one heating element for heating water, and electricity is supplied to the heating element. Preferably the energy is in
10/47 the coolant used to thermally assist the heating of the water in the water reservoir. The hot water system is preferably also connected to a mains power supply.
has an inlet channel and an outlet pipe or an outlet channel in fluid communication with the first coolant chamber, the first heat dissipation plate having a first side being designed for thermal contacting of the corresponding solar cell, and an opposite second side facing the open end of the first coolant chamber and on the latter is formed in system, and the feed pipe and the first discharge pipe are arranged spaced from the first heat dissipation plate and the heat exchanger has at least one second coolant chamber, which is arranged adjacent to the MPPT device and / or the inverter / grid connection
A second heat sink is preferably arranged between the second coolant chamber and the MPPT device and / or the inverter.
The inverter is preferably a direct current / alternating current inverter.
The MPPT device and / or the inverter or converter are preferably arranged in a housing in the heat exchanger arrangement.
At least part of the heat exchanger arrangement is preferably made of plastic, and the housing is integrally formed therein.
Each of the first heat dissipation plates is preferably arranged in a network arrangement with expansion gaps or separating joints between them.
The network arrangement of the first heat dissipation plates is preferably formed from a single thin metal sheet, the heat dissipation plates being connected to one another by a minimal connection.
The minimal connection is preferably a perforation or tab or strip connection.
Each of the first cooling groups is preferably adapted to supply a coolant from a suction pipe via their respective supply pipes in parallel at substantially the same temperature.
Each of the first cooling groups preferably has discharge pipelines in order to supply the coolant in parallel to an outlet pipe or distributor.
The heat exchanger arrangement is preferably connected to a hot water system which has at least one storage container with at least one heating element for heating water, and electricity is supplied to the heating element. Preferably, the energy in the coolant is used to thermally aid in heating the water in the water reservoir. The hot water system is preferably also connected to a mains power supply.
BRIEF DESCRIPTION OF THE DRAWINGS
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1 shows a schematic view of a system for generating electricity according to a first embodiment;
Fig. 2 is a schematic view of the arrangement of heat sink plates used in the system shown in Fig. 1;
3 is a schematic view of the first heat exchanger and its associated coolant chambers of the embodiment shown in FIG. 1.
Fig. 4 is a schematic view of a conventional prior art solar collector used in a system for generating electricity according to that of Fig. 1;
5a is an enlarged cross-sectional detail of the first heat exchanger arrangement and its coolant chambers according to the embodiment of FIG. 1.
5b is an enlarged cross-sectional detail of a first heat exchanger assembly and its coolant chambers according to an alternative second embodiment that uses thermoelectric modules.
6 is an enlarged schematic view of a cooling arrangement on the solar panel junction box portion of the embodiment shown in FIG. 1.
7a shows an enlarged schematic view of some of the heat sinks shown in FIG. 2.
Figure 7b shows an enlarged schematic view of the adhesive detail of the center of a heat sink shown in Figure 7a attached to the photovoltaic layer of the embodiment shown in Figure 1.
Figure 7c shows an enlarged schematic view of the adhesive detail of two adjacent heat sink plates shown in Figure 7a attached to the photovoltaic layer of the embodiment shown in Figure 1.
FIG. 8 shows an enlarged schematic view of a single heat dissipation plate from the arrangement of plates shown in FIG. 2 with the arrangement of the coolant contact areas.
9 is an exploded perspective view of an alternative embodiment of a heat exchanger (coolant tubing unit) and an array of heat sink plates that form a modular unit that can be attached to a solar panel and used in the system of FIG. 1.
10 is an exploded segment of first and second production parts that can be assembled to form a coolant piping unit that forms part of the modular unit shown in FIG. 9.
FIG. 11 shows a top perspective view of two assembled production parts from FIG. 10.
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FIG. 12 shows a perspective bottom view of the two assembled production parts from FIG. 10.
13a shows an enlarged top view of the segment of the coolant piping unit shown in FIG. 10.
FIG. 13b shows a cross section of the segment of the coolant pipeline unit through AA in FIG. 13a.
13c shows a cross section of the segment of the coolant piping unit through BB in FIG. 13a.
14 shows an embodiment of a cooling arrangement for an MPPT circuit (device) in combination with a direct current / alternating current inverter circuit.
Fig. 15 shows the cooling arrangement for an MPPT circuit (device) in combination with the DC / AC inverter circuit of Fig. 14 in use with a heat exchanger used for cooling a solar panel.
16 is an elevation view of a solar thermal hot water unit using a heat exchanger for cooling a solar panel and an MPPT circuit (device) in combination with a DC / AC inverter circuit.
17 is a side view of a solar thermal hot water unit of FIG. 16.
FIG. 18 shows the heat exchanger of the cooling arrangement for the solar hot water unit from FIG. 16.
DESCRIPTION OF PREFERRED EMBODIMENTS
First, Figures 1 through 13c show a description of the preferred embodiments which are also disclosed in International Patent Publication No. WO / 2015/188226 (Application No. PCT / AU2015 / 050309). These embodiments relate to a system for generating electricity that includes a solar panel and an array of heat sink plates with heat exchangers attached thereto that provide increased power output.
These embodiments can be used with the particular arrangements of the present invention, which are further described in FIGS. 14-18.
Embodiment of International Patent Publication No. WO / 2015/188226
1 to 5a and 6 to 7c show a system 50 for generating electricity comprising a solar collector 100 and an arrangement 30 of heat dissipation plates 29 with a heat exchanger 26t attached to them. Heat dissipation plates 29 are arranged in a “grid arrangement”, as can best be seen in FIG. 2, and are spaced apart from one another in such a way that expansion gaps or joints 41 exist between them. A “cut-out” space 151 is provided in two of the tiles 29 so that they can be fitted around the electrical connection box 150 of the solar collector.
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The solar collector 100 is a conventional set of solar cells represented by the photovoltaic layer 200, which has twenty-four solar cells 38, a support layer 39 adhered thereto, and a glass protective layer 40. In this embodiment, the solar cells 38 have a customary size, namely 156 mm × 156 mm. The backside layer 39 is typically a thin plastic film or paint, the purpose of which is to protect the solar cells 38 from UV radiation, moisture and weather. However, layer 39 is deliberately thin so as not to cause any significant thermal insulation on cells 38.
Each heat dissipation plate 29, which is preferably made of a thin aluminum sheet (approximately 1 mm thick), is connected to a corresponding solar cell 38 via a thin layer 39 of the photovoltaic layer 200 and is therefore associated with it.
The solar collector 100 is electrically connected and mounted on a support structure and connected to an electronic control unit (ECU) 8 via lines 6. As shown in FIG. 4, the solar collector 100 has a collector frame 101. A battery (or bank of batteries) 12 is also connected to the ECU 8 via lines 10.
The system 50 also includes a circulation system including a first heat exchanger (water pipe exchanger) 26, a circulation pipe network 24, 25, a circulation pump 17 and a second heat exchanger 18 which is arranged in the water storage reservoir 19. Water or other coolant can be pumped through the circulation pipe network 24, 25 between the first heat exchanger 26 and the second heat exchanger 18.
The first heat exchanger 26 has a suction pipe 21 and an outlet pipe 22 and a plurality of pipes 23 extending therebetween. In Fig. 3 is water, which enters the suction pipe 21 via the inlet pipe 21 via the inlet 31 and leaves the outlet pipe 22 via the outlet 32, as indicated by arrow 22a.
In addition to the suction pipe 21 and the outlet pipe 22, the heat exchanger 26 has a plurality of pipes, namely the cold water pipe 222 and the hot water pipe 333, which are connected to coolant chambers 55 located therebetween. Each coolant chamber 55 has an “open end” that is next to a plate 29 is arranged, and an opposite closed end. Each pipe 222, 333 of the heat exchanger 26 comprises a “tubular element”, as can best be seen in FIG. 5a. The “tubular member” of tubing 222, 333 is the conduit through which the coolant is passed when heat exchanger 26 is used. The pipelines 222, 333 are connected to the chambers 55 via a fluid at or near their “closed end”. By locating tubing 222, 333 at a location spaced from heat dissipation plates 29, heat transfer between plates 29 and the coolant in tubing 222, 333 is minimal. This minimal heat transfer between the plates 29
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• · · · ···· and the coolant in the tubing 222, 333 can be improved by choosing an appropriate grade and thickness of a plastic that provides some degree of thermal insulation from which the heat exchanger 26 is made.
As best seen in FIG. 5a, each coolant chamber 55 is attached to the back of the photovoltaic layer 200 of the solar panel 100 via the heat sink assembly 29. In this embodiment, a conventional commercial solar collector 100 is used and aluminum heat dissipation plates 29 are arranged between the coolant chambers 55 and the solar cells 38 of the photovoltaic layer 200 and are in “direct thermal contact”.
In this description, “direct thermal contact” between a heat dissipation plate 29 and a corresponding solar cell 38 means that the plate 29 is connected to the solar cell 38 or its thin adjacent layer 39 by means of an adhesive 58, which can be, for example, an epoxy resin or a thermal plaster , The layer 39 and the adhesive 58 are so thin that they do not prevent substantial heat transfer between the plate 29 and its corresponding solar cell 38.
In this embodiment, four coolant chambers 55, their associated pipelines 222, 333 and the corresponding heat dissipation plate 29 are referred to as “cooling groups”. However, it should be understood that in other embodiments, the invention may use a different number of coolant chambers in each "cooling group" with their corresponding heat dissipation plate 29.
In this embodiment, the solar collector 100 is rated at 100 watts. Each heat dissipation plate 29 with its “cooling group” consisting of four coolant chambers 55 of the heat exchanger 26 has its “connection side” fixed accordingly and aligned with a corresponding solar cell 38 via the adjacent layer 39 on the rear layer 200 of the collector 100. The other side of each heat sink plate 29, i.e. its "cooling side" communicates with the coolant chambers 55, i.e. it is in contact with the heat exchanger 26.
The cold water pipeline 222 ensures that water (coolant) with substantially the same temperature from the suction pipe 21 enters each “cooling group” of coolant chambers 55, which are assigned to each heat dissipation plate 29, and that at an elevated temperature from the chambers 55 via the discharge pipelines 333 escaping water (coolant) to which outlet pipe 22 is led. This essentially guarantees "a linear discharge of heat".
It should be noted that the coolant chambers 55 are cavities, the size of which is substantially larger than the pipes 222, 333 emanating from them. In this embodiment, the coolant chambers 55 are, for example, 40 mm × 40 mm × 5 mm, while the pipes 222, 333 have an inner diameter of about 4 mm. Chambers 55, which are open to cool the plates 29, ensure that the flowing through the chambers 55
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Water is in direct contact with the plates 29 and efficient heat transfer takes place between them.
Fig. 8 schematically shows a square heat dissipation plate 29, typically about 155 mm x 155 mm. In use, it would be placed over a corresponding solar cell 38 that forms layer 200. Four areas 29ca are shown, one of which is shaded, each centrally located in a respective quadrant of the heat dissipation plate 29. Each of these areas 29ca is approximately 40 mm × 40 mm, namely approximately 1600 mm ² . Each area 29 _ca represents both the “open end” of the coolant chamber 55 and the “contact surface” on the heat dissipation plate 29, which is contacted directly by the coolant fluid that flows through the respective coolant chamber 55. Each region 29ca comprises at least a quarter of the surface of the quadrant of the heat dissipation plate 29 on which it is arranged. Contact areas of this size are effective to ensure that the cooling effect extends to all areas of the "plate quadrant", while the internal cavity height of each cooling chamber 55 is approximately 5 mm.
By ensuring that the heat dissipation plates 29 are somewhat smaller than the associated solar cells 38 with which they are connected and with which they are in thermal contact, a “gap” can be provided between each heat dissipation plate 29 in the “network arrangement”. Since the heat dissipation plates 29 have gaps between them, the heat transfer from one heat dissipation plate 29 to another is minimized, and expansion and contraction of each plate 29 is essentially independent of the surrounding plates 29. Preferably, a continuous gap at the circumferential boundary of the plates 29 would be desirable, but if heat dissipation plates 29 are “minimally connected” by perforations or tabs 49, the heat transfer between the heat dissipation plates 29 is still minimized 29i and the plates 29 can still individually expand and contract. In this specification, "minimally connected" means that the length of the gaps 41 between adjacent plates 29 is substantially greater than the length of the strips 49 or any other connection that would connect them.
As can be seen in FIG. 7 a, the “network array” 30 of the heating plates 29 is made from a single aluminum sheet for easier production. Each heat dissipation plate 29 has a very small opening 401 in its center. When the heat dissipation plate 29 is connected to the layer 39 via a corresponding solar cell 38 using adhesive 58, the opening 401 enables the excess adhesive 55a to pass through, as shown in FIG. 7b is. In the single-sheet “network arrangement” 30, tabs 49 are used in order to minimally connect the heat sinks 29 at the peripheral boundary between the heat sinks. Excess adhesive 58b can pass through the gap 41 next to the tab or the strip 49, as in FIG. 7c
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- ΐ (Γ is shown. The tab 49 is shown bent or wrinkled, but it is understood that the tab 49 could be shaped differently.
Adhesive 304 is used to connect heat exchanger (water pipe exchanger) 26 to plate assembly 29 via coolant chambers 55. The heat sink tiles or plates 29 should preferably have a maximum size of about 155 mm x 155 mm in order to avoid damage or failure of their corresponding somewhat larger solar cell 38 to which they are connected. This is because the different materials of the solar cells 38 and the plates 29 expand and contract at different speeds. Gaps 41 between the panels 29 are required but can be filled with adhesive to allow expansion and shrinkage. In this embodiment, since a plate 29 is slightly smaller than the respective solar cell 38 to which it is connected, the circumference of each plate 29 lies within the circuit boundary of the corresponding twenty-four solar cells 38 on the opposite front side of the layer 200.
As can be seen in FIG. 5a, the coolant chamber 55 is formed by chamber housing parts 305 which are connected to the pipes 222, 333 of the heat exchanger 26 and are also arranged on the rear of the heat dissipation plate 29 by means of adhesive (binder) and are connected to it. A cooling pipe rack 303 connects the pipe structure. In use, coolant that flows through the heat exchanger 26 enters a coolant chamber 55 via the cold water pipeline 222 and exits via the hot water pipeline 333. The heat transfer takes place between the heat dissipation plate 29 and the coolant flowing through the coolant chamber 55.
The surface temperature sensor 5 arranged on the solar collector 200 detects a temperature change in the “photovoltaic operating surface” of the collector layer 200. The sensor 5 is connected to the ECU 8. The pump 17 is connected to the ECU 8 via a power cable 9, so that its operation can be controlled thereby.
When a predetermined temperature is reached in use, for example about 28 ° C, the ECU 8 turns the water circulation pump 17 on, causing coolant to flow through the pipe 24 into the first heat exchanger 26 through the back of the plate layer 200 and circulate through pipes 222, 333, coolant chambers 55 and tube 25 and the heat exchanger 18 in the water tank 19. The “coolant” in the heat exchanger 26 causes a heat difference to occur in the arrangement of the heat dissipation plates 29 and to extract heat by moving over the front hot side to the rear cold side is pulled off.
In addition, remotely located secondary coolant chambers 56 are in fluid interaction in the electrical connection box 150 via 222A and 333A. Secondary coolant chambers 56 reduce the heat located in box 150, which houses the electrical connections of the solar collector.
17/47
The heat generated is dissipated via the first heat exchanger 26 and the pipe network 24, 25 from the rear of the solar collector and circulated by the pump 17, so that it is pumped through the second heat exchanger unit 18, whereby the “thermal energy” of the circulating coolant into a tank 19 is transferred with water 20, which increases its temperature for future use.
Coolant is supplied to the entire first heat exchanger 26 through the suction pipe 21 and is also fed individually to each “cooling group” of the coolant chambers 55 via the cold water channel or the cold water pipe line 222 and leaves the coolant chambers 55 via the hot water pipe line 333 and the outlet pipe 22. In the entire photovoltaic layer 200 and the first heat exchanger 26, a substantially uniform linear heat dissipation is achieved. This is because each “cooling group” cools its respective solar cell 38 “independently” with its heat dissipation plate 29. This essentially independent cooling in combination with minimal heat transfer between adjacent heat dissipation plates 29 and therefore adjacent “cooling groups” ensures that heat from a “hot spot” in a solar cell 38 is not distributed to other solar cells 38 in the layer 200. This essentially contributes to an improved efficiency of the output power of the collector. In addition, the substantially independent expansion and contraction of each of the heat sink plates 29 means that the associated solar cells 38 are stressed less, thereby minimizing the likelihood of cracking and fatigue of the solar cells 38.
It must also be understood that the system 50 is specifically designed to eliminate hot spots or overheating in the entire solar panel 200, resulting in greatly increased electrical performance within a solar radiation environment and a solar panel with improved electrical performance.
In the above embodiment, the "coolant" is preferably water, but it may include conventional coolant additives such as ethylene glycol or other heat transfer media commonly used in air conditioning systems or in the engine cooling of automobiles. However, the coolant can be replaced with a commercially available gas.
In the above embodiment, the tubing assemblies of heat exchanger 26 including tubing 222, 333 and chamber members 305 are preferably made of plastic, but in other embodiments may be made of other suitable materials.
A heat exchanger system similar to system 50, using coolant chambers 55 and heat sink plates 29, has been prototyped and tested to determine the improvement in the efficiency of the solar panel output, which can allow the coolant to contact the heat sink plates directly. A monocrystalline 100 W18 / 47
··
···· ····
Solar cell from SOLRAISER ™, model no. the SPM-ST100 W, which has an array or array of 24 solar cells, was first tested in daylight outdoors without a heat exchanger array. Without cooling and at an ambient temperature of about 26 ° C, the temperature of the solar cell was typically about 73 ° C and only about 25 W was generated. When the heat exchanger system similar to System 50 was attached to this collector and the collector was cooled at an ambient temperature of around 26 ° C, the temperature of the solar cell was typically reduced to 23 ° C and the collector produced an additional 70 W.
9 to 13 show a second embodiment, which allows the important components of the previously described first embodiment, namely the coolant pipes 222, 333, which comprise the coolant chambers 55 of the heat exchanger 26 and the heat dissipation plates 29, as a modular unit 123 construct that can be easily assembled alone and attached to a solar panel 100 to be used in a system similar to the first embodiment.
The main components of this modular unit 123 consist of two integrated production parts, namely the coolant piping (CGU) 126 and the heat dissipation arrangement (HSTA) 130.
For ease of reference, the assembly of the first primary production part is shown in FIGS. 10 through 13c, which show only a segment of the CGU 126 that would form a single "cooling group" consisting of four coolant chambers 55m and their associated tubing 222m, 333m and the respective heat dissipation plate of the arrangement 129.
The CGU 126 is preferably designed as an assembly of two plastic components, the first component 126a and the second component 126b, which together form coolant chambers 55m and supply and discharge pipelines 222m, 333m and other connecting pipelines 223.
The CGU 126 not only includes coolant tubing 222m, 333m, 223 and coolant chambers 55m, it also includes the electrical distribution box case 150m for a solar panel 100 of the previous embodiment.
The second primary production part, namely the HSTA 130, is preferably a single sheet of thin aluminum. It can be formed, punched, pressed, perforated and cut out in one step or possibly chemically etched. The HSTA 130 comprises the arrangement of the field of heat dissipation plates 29 which are “minimally connected” by perforations or tabs or strips.
The CGU 126 and the HSTA 130 are permanently connected to each other to form a complete unit, namely the modular unit 123. This modular unit 123 can be manufactured and packaged separately to add additional equipment to the Son19 / 47.
• fr fr »·· ···· ·· fr • · • fr • for fr • fr ··· · · Fri. * »For fr fr · fr • ·· *
to provide the collector 100, either at the level of the finished products or as a supplement to collectors 100 that are already in operation.
The significant improvement in the efficiency of the power output of the present invention regardless of whether the arrangement shown in the first or second embodiment is used has several reasons. First, the use of heat dissipation plates 29, which are spaced apart from one another without connection or only with “minimal connection or contact”, ensures that there is very little heat transfer between them. This means that “hotspot” heat or heat from a heat accumulation is not easily transferred from a solar cell 38 to a neighboring cell via adjacent heat dissipation plates 29. Second, the heat transfer from each solar cell 38 through a "cooling group" is essentially independent of the heat transfer from neighboring solar cells 38, with the primary heat transfer between the cooling chambers 55 and a corresponding heat dissipation plate 29 in any cooling group. Third, since the feed pipe and discharge pipe 222, 333 are spaced from the surface of the heat dissipation plate 29, there is very little heat transfer between the plates 29 and the pipes 222, 333.
In the first embodiment mentioned above, as shown in FIG. 5 a, the plate 29 is arranged between a cell 38 of the solar collector 100 and coolant chambers 55. In an alternative embodiment, as shown in FIG. 5b, however, the use of a thermoelectric module 1 and a heat dissipation pad 27 is added to the embodiment shown in FIG. 5a. In the embodiment of FIG. 5 b, thermoelectric modules 1 have a first side thereof in direct contact with the heat dissipation plate 29 and an opposite side lies (in direct contact) on the heat dissipation pad 27. Opposing edges of the thermoelectric module 1 and the heat dissipation pad 27 are arranged under the stepped regions 42 of the chamber elements 305. In this embodiment, the coolant that flows through the coolant chamber 55 runs over the heat dissipation pad 27.
When the arrangement of FIG. 5b is used in the system 50 of the first embodiment, the thermoelectric modules 1 are connected to the ECU 8 via lines (not shown). The heat difference between a first side of the thermoelectric modules (against the heat dissipation plates 29) and the opposite second side thereof generates an electrical charge which is conducted to the battery 12 via the above-mentioned lines, not shown. This electrical charge generation is similar to the embodiment described in International Patent Publication No. WO 2015/039185 (Webb et al.). In this embodiment shown in FIG. 5 b, however, the coolant flowing through the coolant chambers 55 provides improved cooling in comparison to the state of the art / technology, as a result of which a potentially increased heat difference and thus a larger amount of electrical charge generated by the thermoelectric modules 1 provided.
In the above-mentioned embodiments, the components of the heat exchanger arrangement and the heat dissipation plates could either be attached to the solar panels during manufacture or retrofitted to existing solar panels. The components of the heat exchanger arrangement and the heat dissipation plates could be provided in the form of a “modular unit”.
Particular embodiments of the present invention
14 and 15 show a specific embodiment of a combination of MPPT (Maximum Power Point Tracking) and pure signal wave AC network connection circuit that can be used with the previously described embodiments of the system 50 shown in FIGS. 1 to 13c.
As best seen in Fig. 14, both the MPPT device (MPPT circuit) 600 in conjunction with a direct current / alternating current inverter (signal wave network connection circuit only) 500 are thermally connected to the coolant chambers via an electronic heat sink (aluminum heat sink) 104 56a of the heat exchanger 26a, thereby providing heat dissipation (thermal dissipation) for electronic components 110 connected to solar cells 38a of the solar collector 100a. Additional coolant chambers 56b are located on both sides of the circuit 500, 600 and, together with coolant chambers 56a, form a group of “cooling chambers” that cool the surroundings of the circuit 500, 600.
Preferably, the heat exchanger 26a has its “coolant piping unit” made of plastic and the “circuit housing” in which the MPPT circuit 600 and the inverters 500 are integrally formed in the coolant piping unit, as are the cooling chambers 56a. The electronic heat sink 104 is arranged between the MPPT circuit 600 and the inverter 500 and the cooling chamber 56a.
The array or array of solar cells 38a provides direct electrical current directly to the MPPT circuit 600, which is in physical, thermal contact and in close proximity to the emerging direct current connections. This means that the MPPT circuit 600 and the DC / AC inverter 500 are connected directly to the DC output of the solar cells 38a.
The MPPT circuit maximizes the PV performance of the array of solar cells 38a. The MPPT circuit 600 then supplies the maximum direct current to the direct current / alternating current inverter 500, which converts the direct current into high-voltage alternating current, which is supplied to the alternating current output 108. This allows the solar collector 100a to then be in series with other similar collectors 100a (of the same type)
21/47 • · · · · ···· _ 21 * - ·· ··· · ··.
can be connected, eliminating all other forms of storage, high power conversion and other high loss electrical devices, including batteries.
Since the MPPT circuit 600 and the inverter 500 are thermally connected to the coolant chambers 56a, they are cooled by a coolant that circulates through the heat exchanger 26a and passes through the chambers 56a.
The heat exchanger 26a is preferably a heat exchanger that also cools the solar cells of the solar collector 100a, as shown in FIG. 15. The heat exchanger 26a has a cold water pipeline 222b and a discharge pipeline 333b. The supply of water (coolant) via the suction pipe 21a, see arrow 225, through the cold water line 222b ensures that the cooling chambers (cooling group for the circuit) 56a, 56b, the MPPT device 600 and the inverter (grid connection) 500 are associated, have essentially the same temperature. Water flows through these chambers 56a, 56b, see water path arrow 226, 227, and exits via outlet channel 333b to outlet pipe 22a.
It should be understood that the collector 100a, solar cells 38a, and heat exchanger 26a of this particular embodiment of the previously described solar collector 100, solar cells 38, and heat exchanger 26 (or CGU 126) of the system 50 using coolant chambers 55 and heat dissipation plates 29I described in the previous are similar. The difference in this embodiment is that the present MPPT device 600 and the inverter (grid connection) device 500 are accommodated in a “circuit housing”, which is provided in one piece in the heat circuit or circuits. Such an arrangement provides high-voltage alternating voltage and a pure sine wave which can be connected in parallel with other collectors 100a equipped with the same technology. The MPPT circuit 600 and the inverter 500 must be designed to accommodate the maximum capacity of the solar collector 100a, such as 250 watts , to manage something. In addition, since the system 50 includes a heat exchanger 26a for cooling the solar panel 100a, there is an excess cooling capacity that can be quickly adjusted to serve as cooling for the MPPT circuit 600 and the inverter circuit 500.
By installing a "grid connection" in the inverter 500, each solar collector 100a can be used individually or connected in series. In this description, the term “inverter / grid connection” means an inverter that has an AC grid connected to it.
By providing a series of cooled collectors 100a, each of which has its own MPPT device 600 with a DC / AC inverter / grid connection 500, which is also cooled by the same coolant as the solar cell 38
22/47
cools, it is possible to achieve a number of advantages over conventional solar panels. These advantages are as follows:
• You can eliminate the need for power storage systems. • You can use the network as a passive storage system.
• You minimize or eliminate DC losses through cabling.
• They enable the use of lighter high-voltage cables • They can be connected directly to any socket.
• You can eliminate other electronic management systems.
• When many collectors 100a are connected, the system automatically provides redundancy (if one collector fails, the entire system continues to run), and • The effects of weak and strong interacting collectors can be minimized to reduce performance deficiencies.
Providing a single heat exchanger 26a that cools both the solar cells 38a and the MPPT circuit 600 and the inverter (grid connection) circuit 500 means that a single pump can be used to circulate coolant.
In a special application, the MPPT circuit 600 described in FIG. 14, which is combined with the inverter (grid connection) 500 and is cooled via cooling chambers 56a, 56b of the heat exchanger 26a, can be used with a solar thermal hot water unit.
16 to 18, a “solar thermal hot water unit” includes a hot water tank 700, a photovoltaic thermal solar panel 100b, and a supporting frame structure 710. The solar panel 100b has a heat exchanger 26b that is similar to the previously described heat exchanger 26a provide cooling of the solar cells 38b and for cooling an MPPT circuit 600 and a DC / AC inverter circuit 500.
A further (second) heat exchanger 701 and an electric heating element 702 of the heating device 703 are also installed in the hot water tank 700, which is connected via 708 together with the MPPT circuit 600 and the inverter 500 to the AC network, which AC in exchange with network cables 708 supplied via connection cable 709. When the electrical heating element 702 is in operation (turned on), high voltage alternating current is supplied via the main power cable 708 and the MPPT circuit 600 and the inverter or converter 500 via the connecting cable 709. When the water heater 702 is turned off, the high voltage alternating current from the MPPT circuit 600 and the inverter 500 is connected directly to the external high voltage alternating current network via the network connection 708, 709. Another thermal / 47
• · · · • · · · · · • · · · • · · · ·
Support for heating the water in the tank 700 is provided by heated circulating coolant provided by the heat exchanger 26b.
The coolant circulates throughout the cooling system by means of the pump 706 and a further external cooling mechanism (a third heat exchanger) 707 is used. The heat exchangers 707 and the pump 706 are preferably positioned in the return coolant line 705.
While in the embodiments described above with reference to FIGS. 14 to 18, both the MPPT circuit 600 and the DC / AC inverter circuit 500 are described in combination, it is understood that one or the other in the proposed cooling solutions are separate can be used. This means that one or both of these circuits can be cooled by the same heat exchanger arrangement used for cooling solar collectors.
The present invention enables the MPPT circuitry 600 and the DC / AC inverter 500 to be placed on the solar panel, either alone or in combination.
The terms "include" and "including" (and their grammatical variations) as used herein are used in a broad sense and not in the sense of "consisting only of".

权利要求:
Claims (17)
[1]
claims:
1. An apparatus for generating electricity, comprising:
a solar collector (100) with a plurality of solar cells (38) and an MPPT device (600) alone or in combination with a direct current / alternating current inverter (500) directly connected thereto;
a plurality of first heat dissipation plates (29); and a first heat exchanger (26);
wherein the first heat dissipation plates (29) are arranged between the solar collector (100) and the first heat exchanger (26) and the first heat exchanger (26) is connected to a circulation system (50), which is designed to a coolant flow through the first heat exchanger (26) flow and each of the first heat sink plates (29) has a first side in direct thermal contact with a corresponding one of the solar cells (38), and an opposite second side in direct contact with the first heat exchanger (26), and wherein the first heat exchanger (26) has a plurality of first coolant chambers (55) which are arranged adjacent to the first heat dissipation and the first heat exchanger (26) has at least one second coolant chamber (55) which the MPPT device (600) and / or the DC / AC inverter (500) is arranged adjacent.
[2]
2. The apparatus of claim 1, wherein a second heat sink between the second coolant chamber (56) and the MPPT device (600) and / or a DC / AC inverter (500) is arranged.
[3]
3. The apparatus of claim 1, wherein in the heat exchanger (26) a plurality of supply pipe (222) and discharge pipe (333) for supplying and discharging the coolant to and from the first coolant chambers (55) and the supply pipes (222) and the discharge pipelines (333) are formed at a distance from the first heat dissipation plates (29).
[4]
4. The apparatus of claim 3, wherein the supply pipe (222) for supplying the coolant from a suction pipe (21) so that in the respective first coolant chambers (55) of adjacent first heat dissipation plates (29) coolant supplied is substantially at the same temperature located.
[5]
5. The device according to claim 1, wherein coolant emerging from the first heat exchanger (26) circulates through a second heat exchanger (18) arranged in a storage container containing water.
[6]
6. The device according to claim 1, wherein at least one thermoelectric module (1) between the first heat exchanger (26) and at least one of the respective first heat dissipation plates (29) is arranged such that the opposite second side of the respective
25/47 ·· ·· · · ···· ···· ······· · · • · · · ··· · · • · · · ····· ·· ♦ · · · · · · · ·
- 25 * -.........
the first heat dissipation plate (29) is in direct contact with the thermoelectric module (1), and at least one first coolant chamber (55) of the first heat exchanger (26) is adjacent to the thermoelectric module (1) in such a way that heat transfer between the through the first Coolant chamber (55) flowing coolant fluid and the thermoelectric module (1) can occur.
[7]
7. A device for generating electricity, comprising at least one solar collector (100) with a plurality of solar cells (38) and an MPPT device (600) alone or in combination with a direct current / alternating current inverter (500) directly connected thereto; and a first heat exchanger (26);
the apparatus further comprising a plurality of first heat dissipation plates (29) disposed between the solar panel (100) and the first heat exchanger (26), and the first heat exchanger (26) is connected to a circulation system that is adapted to allow coolant to flow through the first heat exchanger (26), and wherein each of the first heat sink plates (29) has a first side in direct thermal contact with a corresponding one of the solar cells (38) and an opposite second side that mates with the is in contact with the first heat exchanger (26), and wherein the first heat exchanger (26) has a plurality of first coolant chambers (55) and a plurality of supply pipes (222) and discharge pipes (333) that supply and discharge coolant to the first coolant chambers (55) discharge it, each coolant chamber (55) having an open end adjacent to one of the first heat dissipation plates (29 ) and has an opposite closed end and the feed pipes (222) and the said discharge pipes (333) are arranged at a distance from the heat dissipation plates (29), and the first heat exchanger (26) has at least one second coolant chamber, which is located next to the MPPT -Device (600) and / or the direct current / alternating current inverter (500) is arranged.
[8]
8. Device for cooling a solar collector (100) with a plurality of solar cells (38) and an MPPT device (600) alone or in combination with a direct-current / alternating-current inverter (500) directly connected to it, which device has a plurality of first Has heat dissipation plates (29) and a first heat exchanger (26); the first heat dissipation plates (29) being arranged in a grid array, each of the first heat dissipation plates (29) having a first side suitable for contacting a corresponding solar cell (38), each first heat dissipation plate (29) within the peripheral boundary of its corresponding solar cell ( 38) and the first heat exchanger (26) has a plurality of first coolant chambers (55) and a plurality of supply pipelines (222) and discharge pipelines (333) which are used for supplying and discharging a coolant to the associated first coolant chambers (55) and out of these
26/47 ·· ·· · · ···· ···· ······· · · ···· · · · · · • · · · ····· ·· ····· · ····
- 26 * - *** · ·· ·, each coolant chamber (55) having an end corresponding to its first heat dissipation plate (29) open and an opposite closed end, and are the supply pipes (222) and the discharge pipes (333) spaced from the heat sink plates (29) and the first heat exchanger (26) has at least one second coolant chamber located adjacent to the MPPT device (600) alone or in combination with a DC / AC inverter (500).
[9]
9. Modular unit (123) for attachment to a solar collector (100) with a plurality of solar cells (38), the modular unit comprising:
a heat exchanger (26) with a suction pipe (21) and an outlet pipe (22); and an MPPT device (600) alone or in combination with a direct current / alternating current inverter (500) which is connected directly to the solar collector (100) and a plurality of first heat dissipation plates (29) which are arranged in a grid field with expansion joints in between ( 41) are arranged;
wherein each of the first heat sink plates (29) has a coolant side in contact with the first heat exchanger (26) and an opposite connection side for direct thermal contact with a corresponding one of the solar cells (38), and the first heat exchanger (26) has a plurality of first coolant chambers (55) , which are arranged adjacent to the first heat dissipation plates (29), and each first heat dissipation plate (29) has at least one of the plurality of respectively assigned first coolant chambers (55), and the first heat exchanger (26) has at least one second coolant chamber (55) , which is arranged adjacent to the MPPT device (600) alone or in combination with a direct current / alternating current inverter (500).
[10]
10. Modular unit (123) according to claim 9, wherein a second heat sink between the second coolant chamber (55) and the MPPT device (600) and / or a direct current / alternating current inverter (500) is arranged.
[11]
11. The modular unit (123) according to claim 9, wherein the heat exchanger (26) comprises a plurality of supply pipes (222) and discharge pipes (333) in fluid communication between the first coolant chambers (55) and the suction pipe (21) and the outlet pipe (22) and the feed pipe (222) and the discharge pipe (333) are spaced from the first heat dissipation plates (29).
[12]
12. The modular unit (123) of claim 11, wherein the supply piping (222) is configured to supply coolant in parallel from an intake manifold to the coolant chambers (55) at substantially the same temperature.
[13]
13. The modular unit (123) according to claim 9, wherein the modular unit (123) is connected to a circulation system and a pump (17) arranged in the circulation system is adapted to circulate the coolant through the first heat exchanger (26).
27/47 ····
[14]
14. A heat exchanger arrangement for cooling a solar collector (100) with a plurality of solar cells (38) and an MPPT device (600) alone or in combination with a directly connected inverter / network (500), the arrangement comprising a plurality of first Cooling groups, each first cooling group being adapted for substantially independent heat transfer from a respective solar cell (38); each first cooling group having a first heat sink (29), at least one first coolant chamber (55) having an open end and an opposite closed end, and at least one inlet channel (31) and one outlet channel (23) in fluid communication with the first coolant chamber (55) , wherein the first heat sink plate (29) has a first side adapted to thermally contact the corresponding solar cell (38) and an opposite second side facing the open end of the first coolant chamber (55) and in abutment The first heat exchanger (26) has at least one second coolant chamber (55), which is adjacent to the MPPT device ((MPPT device ()) and the inlet channel (31) and the outlet channel (23) are arranged at a distance from the first heat dissipation plate (29). 600) and / or the inverter / grid connection (500) is arranged.
[15]
15. Modular unit (123) according to claim 9, wherein the MPPT device (600) and / or the inverter (500) are connected to a hot water system, which is provided at least one reservoir (19) with at least one heating element for heating water , and electricity is supplied to the heating element.
[16]
The modular unit (123) of claim 15, wherein the energy in the coolant is used to provide thermal support for heating the water in the water reservoir (19).
[17]
17. The heat exchanger arrangement as claimed in claim 14, in which the MPPT device (600) and / or the inverter (500) are connected to a hot water system which has at least one storage container (19) with at least one heating element for heating water and from the solar collector (100) generated electricity is supplied to the heating element.

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KR20190057091A|2019-05-27|

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法律状态:
2021-12-15| REJ| Rejection|Effective date: 20211215 |

优先权:

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申请号 | 申请日 | 专利标题

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AU2016903823A|AU2016903823A0|2016-09-22|System And Apparatus For Generating Electricity With Integrated Circuitry|

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PCT/AU2017/051012|WO2018053579A1|2016-09-22|2017-09-18|System and apparatus for generating electricity with integrated circuitry|

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