DE102007010642A1 - Generator arrangement, particularly for generation of electricity from solar radiation, has photoelectric module, thermoelectric module and heat transducer arrangement arranged partly in collector area for collection of heat energy - Google Patents

Abstract

The generator arrangement (20) has a photoelectric module, a thermoelectric module (28) and a heat transducer arrangement (32) arranged partly in a collector area (30) for the collection of heat energy from solar radiation. The heat transducer arrangement is provided for heat supply, where a heat transducer (43) serves for the heat dissipation of the thermoelectric module. An independent claim is also included for a method, particularly for the generation of electricity from solar radiation.

Description

The The invention relates to a generator arrangement and a method for Recovery of in particular electrical energy from solar radiation with a generator arrangement with at least one photoelectric module, a thermoelectric module and a heat exchanger assembly, wherein the photoelectric module, the thermoelectric module and the heat exchanger assembly at least partially in a collector room for the collection of heat energy from solar radiation, heat energy the photoelectric module and heat energy of the heat exchanger assembly arranged and opposite Solar radiation are exposed, the heat exchanger assembly for heat and at least one additional heat exchanger for heat dissipation the thermoelectric module is used, and at least one heat exchanger the heat exchanger assembly for absorption of heat energy from solar radiation a fluid medium for the exchange of heat energy having a compensation unit.

Out In the prior art are a number of different generator arrangements and method for obtaining electrical energy from solar radiation known. As is well known, photoelectric systems convert radiant energy the sun into electricity. This will be about 8% to 15% the irradiated solar energy is converted into electricity, while the rest as heat energy get lost. For the conversion of heat energy into electrical energy become so-called Peltier elements in thermoelectric plants used. By means of a Peltier element can from a temperature difference between a hot side and a cold side of the element a DC voltage be generated. Among other things, Peltier elements are used in solar panels used, with the warm side of the Peltier element of solar radiation is suspended. Furthermore, heat exchangers or heat exchangers for the production of heat energy known from solar radiation. heat exchangers which are used in solar panels are usually considered meandering coil formed and in a substantially black, with a transparent Slice covered room of a solar panel arranged. The Coil is made from a liquid heat transfer medium flowed through, wherein the heat transfer medium is heated by means of solar radiation. The recovered heat energy is often used to Production and storage of domestic hot water used in storage tanks.

to Achieving improved efficiencies in the recovery of electrical Energy from solar radiation are combinations of the aforementioned generator types known from the prior art. So are photoelectric modules on a rear facing away from the sun with thermoelectric Modules for converting the excess heat energy provided in electrical energy. Also are thermoelectric modules known with Peltier elements whose cold side by means of a formed from coils heat exchanger cooled to achieve a temperature difference or at night for use warmed up as a warm side become. All previously known combinations of generators for Extraction of energy from solar radiation have the disadvantage that the solar energy is not used optimally. Also, no constant, Uninterrupted power generation in the absence of sunshine or on the Sunshine duration to be ensured. There is often one too high control engineering effort to control media temperatures necessary to the energy transported by the sun's rays to use with a high degree of efficiency.

Of the The present invention is therefore based on the object, a generator assembly and a method for obtaining electrical energy from solar radiation to propose, which has a high efficiency, a consistent power generation ensures essentially without control engineering effort and makes economic sense.

These Task is achieved by a generator arrangement with the features of Claim 1 and by a method for obtaining electrical energy from solar radiation with the features of claim 11 solved.

at the generator assembly according to the invention for obtaining in particular electrical energy from solar radiation the generator arrangement has at least one photoelectric module, a thermoelectric module and a heat exchanger assembly, wherein the photoelectric module, the thermoelectric module and the The heat exchanger at least partially in a collector room for the collection of heat energy from solar radiation, heat energy the photoelectric module and heat energy of the heat exchanger assembly arranged and opposite Solar radiation are exposed, wherein the heat exchanger arrangement for supplying heat and at least one other heat exchanger for heat dissipation the thermoelectric module is used, and at least one heat exchanger the heat exchanger assembly for Absorption of heat energy from solar radiation a fluid medium for the exchange of heat energy having a compensation unit.

An increase in the efficiency results in particular from the exposure of the photoelectric module, the thermoelectric module and the heat exchanger assembly and the collector space against direct sunlight. In the case of solar radiation, it is thus easy to obtain electrical energy by means of the photoelectric module, the waste heat of the photoelectric module being collected in the collector space. The collector chamber also serves to generate heat from solar radiation, the heat exchanger assembly on the one hand exchanges heat energy with the compensation unit, thereby ensuring removal of excess heat energy in strong solar radiation and a supply of stored heat energy in the absence of solar radiation, and on the other hand heat energy in the collector chamber on a hot side of the thermoelectric module is transported. Thus, a high energy yield from solar radiation is achieved, and in the absence of solar radiation, the thermoelectric element by means of the heat exchanger assembly and the compensation unit can be supplied with heat energy. In particular, spiral heat exchangers, plate heat exchangers, countercurrent layer heat exchangers and other heat exchangers known from the prior art can serve as heat exchangers of the heat exchanger arrangement.

The for one Consistent generation of electrical energy necessary temperature difference between a hot side and a cold side of the thermoelectric module Among other things, by means of the heat exchanger for heat dissipation maintained on the cold side of the thermoelectric module. Also, the use of a fluid medium, such as water as a carrier the heat energy, allows a waiver of a high control engineering effort because a circulation of the medium due to temperature differences or gravity transmissions without the use of moving components can be done.

When it proves particularly advantageous if the heat exchanger arrangement at least one other heat exchanger for transmission the heat energy from direct solar radiation and the collector space to the thermoelectric Module has. So can a heat exchanger for the exchange of heat energy used between collector room and balancing unit and another Heat exchanger to the feeder the heat energy of the collector space can be used on the thermoelectric module. The exchange of heat energy between two heat exchangers can be done by the air in the collector chamber. Also is a direct feeder of heat energy out on the heat exchanger acting solar radiation on the thermoelectric module possible.

A Temperature difference at the thermoelectric module is then special easily adjustable when the thermoelectric module between the collector space and a refrigerator, which of the heat dissipation serves, is arranged and the heat exchanger for heat dissipation at the thermoelectric module in the refrigerator is arranged. The thermoelectric module can do this, among other things serve as part of a wall between the collector room and the refrigerator.

In an embodiment The generator arrangement can be a heat transfer surface of the heat exchanger for heat dissipation be many times bigger as a heat transfer surface of the heat exchanger for transmission the heat energy on the thermoelectric module. The heat exchanger surface on the cold side of the thermoelectric Module can be made so big that the cold side temperature is largely stable without the cold side temperature due to a power consumption or one of an internal resistance the thermoelectric module resulting heat development is significantly increased.

is the sun facing side of the collector room transparent and are the rest inner surfaces The collector room essentially black, can be exposed to sunlight a relatively high warming of the in the collector compartment located components or surfaces and the heat exchanger and thus a high absorption of heat energy from solar radiation be achieved.

One increased Efficiency of the generator arrangement is achieved in particular by that the sun-facing side of the collector space is a lens device for focusing the solar radiation on the heat exchanger assembly and / or having the photoelectric module. Thus, also heat transfer surfaces of the heat exchanger assembly substantially be formed smaller, which is a particularly compact design of the Generator arrangement allows.

In an embodiment the generator assembly, the compensation unit is a thermal energy storage exhibit. Is relatively strong heat energy in strong sunlight absorbed, this can in the heat energy storage stored and in the absence of solar radiation or at night of the heat exchanger arrangement or the thermoelectric module for generating electrical energy to be supplied.

In a further embodiment of the generator arrangement, the compensation unit can have a heat energy generator. For example, energy stored in biomass can be converted into heat energy by combustion and ensure power generation beyond the sunshine duration. Also, the so can produce te additional heat energy depending on the occurrence and need to be cached in the thermal energy storage.

A optimal matching of thermoelectric modules to each photoelectric Modules and heat exchangers can be enabled when the photoelectric module and the heat exchanger for absorption of heat energy from solar radiation in each case a collector space together with a thermoelectric module are arranged. The thermoelectric Modules are thus each with regard to the required temperature differences and / or the heat transfer surfaces on the regularly prevailing Temperatures in the respective collector rooms adaptable.

has the generator assembly comprises a frame assembly receiving the frame assembly, the generator arrangement can be modular. Training a flat Collector room and a subsequent to the collector room refrigerator is then very easy. Next you can the opposite exposed to the sun components of the generator assembly to achieve one raised Compared to efficiency be tracked automatically to the sun, with such Frame arrangements facilitate the installation of a tracking device.

at the method according to the invention for obtaining in particular electrical energy from solar radiation with a generator arrangement are at least one photoelectric Module and a thermoelectric module and a heat exchanger assembly at least partially in a collector room for the collection of heat energy arranged from solar radiation and are exposed to solar radiation, being an absorption of heat energy from solar radiation by means of the photoelectric module, thermoelectric module, the heat exchanger assembly and the collector space takes place and at least partially in the collector space is collected, wherein by means of the heat exchanger assembly the thermoelectric Module heat energy is supplied for generating electrical energy and waste heat of the Thermoelectric module by means of another heat exchanger for heat dissipation dissipated is, and wherein by means of a fluid medium, at least one heat exchanger the heat exchanger assembly an exchange of heat energy with a compensation unit. With such a method is the constant generation of electrical energy from solar radiation easily achievable with a particularly high efficiency.

In an embodiment The method may have a substantially constant temperature difference at the thermoelectric module between the heat exchanger assembly for supplying heat and the heat exchanger for heat dissipation be achieved by means of the compensation unit. The temperature difference can thus be independent from solar radiation in the range of a suitable difference level being held.

In a further embodiment The process can be essentially an evolving need adapted to electrical energy temperature difference at the thermoelectric Module between the heat exchanger assembly for heat supply and the heat exchanger for heat dissipation be achieved by means of the compensation unit. Because the temperature difference in the thermoelectric module, inter alia, by a connected thereto electrical consumer can be influenced, it is special advantageous if a temperature change on a cold side of the thermoelectric module with a temperature change on a hot side of the thermoelectric module to achieve a consistent temperature difference goes along.

The Method proves to be particularly advantageous when the compensation unit Thermal energy stores.

Unwanted power fluctuations in generating electrical energy can be safely avoided if the compensation unit by means of a heat generator heat energy the heat exchanger assembly supplies.

A particularly rapid achievement of high temperature levels is made possible when the solar radiation on the heat exchanger assembly and / or the photoelectric module focused by means of a lens device becomes.

Further advantageous embodiments of the method result from the feature descriptions of refer back to device claim 1 Dependent claims.

following become preferred embodiments of the invention with reference to the accompanying drawings.

It demonstrate:

1 a first embodiment of a generator assembly in a sectional view;

2 a second embodiment of a generator assembly in a sectional view;

3 a third embodiment of a generator assembly in a partial sectional view;

4 a fourth embodiment of the generator assembly in a plan view;

5 a fifth embodiment of a generator assembly in a plan view;

6 a sixth embodiment of the generator assembly in a plan view;

7 a seventh embodiment of the generator assembly in a plan view.

1 shows a generator assembly 20 with one of frame profiles 21 formed frame assembly 22 , wherein a collector unit 23 the generator assembly 20 between the frame profiles 21 is included. The collector unit 23 is over heat-insulated, water-filled pipes 24 with a compensation unit 25 connected. The compensation unit 25 is at a relative distance from the collector unit 23 positioned or positioned, which is indicated by the dashed line of the tubes 24 should be clarified. Next points the compensation unit 25 a thermal energy store 26 and an associated heat energy generator 27 , which are shown here only schematically, on. The heat energy generator 27 For example, it can be designed as a biogas plant or as a solid fuel-fired heating system and the heat energy storage 26 supply heat energy at intervals or at intervals. The generator arrangement 20 further has a thermoelectric module 28 which at least partially in a wall 29 intermediate a collector room 30 and a fridge 31 is arranged, and a heat exchanger assembly 32 and a photoelectric module, which is not visible in this illustration. The heat exchanger arrangement 32 is from one to the pipes 24 connected heat exchanger 33 with a meandering tube 34 and a heat exchanger 35 that on the thermoelectric module 28 this covering is arranged, formed.

surfaces 36 . 37 . 38 of the collector room 30 as well as the pipe 34 and lamellae 39 of the heat exchanger 35 are black, to promote absorption of heat energy from solar radiation or the transfer of heat energy. An upper cover of the collector room 30 is from a transparent pane 40 formed, with a lens arranged thereon 41 a plurality of lenses 42 that shows the incident solar radiation on the pipe 34 and the slats 39 focus. Another heat exchanger 43 with slats 44 is in the fridge 31 on the thermoelectric module 28 arranged and covers the module 28 from. A not directly visible heat exchanger surface of the slats 44 the heat transfer 43 is many times larger than a heat exchanger surface of the slats 39 the heat transfer 35 ,

The in the direction of the arrow 45 incident solar radiation is incident on the photoelectric module, not shown here, which gains electrical energy and surplus heat to the rear collector door space 30 emits. Further, the solar radiation for generating heat energy by means of the lenses 42 on sections of the pipe 34 and the heat exchanger 35 focused. The surfaces 36 . 37 . 38 of the collector room 30 In addition, contribute to the absorption of heat energy from solar radiation. The in the collector room 30 The heat energy is at an excess of heat energy by means of the heat exchanger 33 over the pipes 24 in the thermal energy storage 26 dissipated and in the absence of heat energy analogous to the collector room 30 from the thermal energy storage 26 returned and to air in the collector room 46 issued. The air heated by the heat absorption 46 flows according to the inclination of the collector unit 23 within the collector room 30 upwards into the area of the heat exchanger 35 , In the fridge 31 In contrast, heat dissipation takes place on the heat exchanger 43 , A necessary for the generation of electrical energy temperature difference can thus between a hot side 47 and a cold side 48 of the thermoelectric module 28 trained and maintained permanently.

2 shows a generator assembly 49 with a photoelectric module 50 , which partly together with a transparent pane 51 a cover 52 a collector room 53 forms. In the collector room 53 is a heat exchanger 54 on a thermoelectric module 55 and a heat exchanger 56 for the exchange of heat energy with a compensation unit of the generator arrangement, not shown here 49 arranged. A meandering under the photoelectric module 50 arranged pipe 57 of the heat exchanger 56 surmounted the photoelectric module 50 in its extension transverse to the plane of the drawing, so that the heat exchanger 56 , the thermoelectric module 55 and the photoelectric module 50 exposed to solar radiation. In order to ensure optimum solar radiation for effective energy absorption, a tracking device is shown schematically here 58 for automatically aligning the energy absorbing components of the generator assembly 49 on the respective position of the sun on a frame arrangement 59 assembled.

3 shows a generator assembly 60 in a partial section. Here has a heat exchanger arrangement 61 over a meandering tube 62 for the exchange of heat energy with a compensation unit, not shown generator arrangement 60 , where the pipe 62 of lamellae 63 which is for absorbing heat energy from solar radiation and transfer of heat energy to a hot side 64 a thermoelectric module 65 serve. A transfer of heat energy from a balancing unit to the hot side 64 of the thermoelectric module 65 is significantly accelerated due to the selected configuration of the heat exchanger assembly. Incidentally, the generator arrangement corresponds 60 the in 2 shown generator assembly 49 ,

4 shows a collector surface 66 a generator arrangement 67 in a schematic plan view. The collector surface 66 is from a frame arrangement 68 surrounded, which are the corresponding components of the generator assembly 67 supports. The collector surface 66 is partially from a photoelectric module 69 one from a tube 70 formed heat exchanger 71 for the exchange of heat energy with a compensation unit, not shown here, and a heat exchanger 72 which is on a thermoelectric module 73 is arranged, and a partially visible surface 74 a collector room 75 educated.

A generator arrangement 76 with two separate collector rooms 77 and 78 shows 5 , The collector rooms 77 and 78 each have collector surfaces 79 respectively. 80 on. The collector rooms 77 and 78 are each in individual separable frame 81 respectively. 82 a frame arrangement 83 supported. In the collector room 77 is a heat exchanger 84 for the exchange of heat energy with a compensation unit of the generator arrangement, not shown here 76 as well as a heat exchanger 85 a thermoelectric module 86 arranged. In the collector room 78 or the collector room 78 partially covering is a photoelectric module 87 and a heat exchanger 88 another thermoelectric module 89 arranged. The heat exchanger 85 and 88 are in shape and design respectively to the heat exchanger 84 or the photoelectric module 87 and in the respective collector rooms 77 respectively. 78 absorbed heat energy adapted to achieve a consistent, high temperature difference adapted.

A collector surface 90 a generator arrangement 91 with a lens device 92 is in 6 shown. The lens device 92 has a plurality of prism-shaped, in a longitudinal direction over a portion of the collector surface 90 extending lenses 93 and 94 on. The lenses 93 respectively. 94 are arranged so that the incident solar radiation on not visible here, behind the lenses 93 arranged pipe coils or a heat exchanger of a thermoelectric module behind the lenses 94 be focused.

One three collector surfaces 95 . 96 . 97 having generator assembly 98 shows 7 , The collector surfaces 95 and 97 each have heat exchangers 99 respectively. 100 for the exchange of heat energy with a compensation unit, not shown here, and heat exchangers 101 respectively. 102 and thermoelectric modules 103 respectively. 104 on. The collector surface 96 is from a photoelectric module 105 filled, with a not visible here thermoelectric module with a heat exchanger behind the photoelectric module 105 is arranged.

Claims (16)

Generator arrangement ( 20 . 49 . 60 . 67 . 76 . 91 . 98 ) for obtaining in particular electrical energy from solar radiation with at least one photoelectric module ( 50 . 69 . 87 . 105 ), a thermoelectric module ( 28 . 55 . 65 . 73 . 86 . 89 . 103 . 104 ) and a heat exchanger arrangement ( 32 . 61 ), wherein the photoelectric module, the thermoelectric module and the heat exchanger arrangement at least partially in a collector space ( 30 . 53 . 75 . 77 . 78 ) are arranged to collect heat energy from solar radiation, heat energy of the photoelectric module and heat energy of the heat exchanger arrangement and exposed to solar radiation, wherein the heat exchanger arrangement for supplying heat and at least one further heat exchanger ( 43 ) is used for heat dissipation of the thermoelectric module, and at least one heat exchanger ( 33 . 56 . 71 . 84 . 99 . 100 ) of the heat exchanger arrangement for absorbing heat energy from solar radiation, a fluid medium for exchanging heat energy with a compensation unit ( 25 ) having. Generator arrangement according to claim 1, characterized in that the heat exchanger arrangement ( 32 . 61 ) at least one further heat exchanger ( 35 . 54 . 72 . 85 . 88 . 101 . 102 ) for the transmission of heat energy from direct solar radiation and the collector space ( 30 . 53 . 75 . 77 . 78 ) on the thermoelectric module ( 28 . 55 . 65 . 73 . 86 . 89 . 103 . 104 ) having. Generator arrangement according to claim 1 or 2, characterized in that the thermoelectric module ( 28 . 55 . 65 . 73 . 86 . 89 . 103 . 104 ) between the collector space ( 30 . 53 . 75 . 77 . 78 ) and a cold room ( 31 ), which serves the heat dissipation, is arranged and the heat exchanger ( 43 ) is arranged to dissipate heat at the thermoelectric module in the refrigerator. Generator arrangement according to one of the preceding claims, characterized in that a heat transfer surface of the heat exchanger ( 43 ) for heat dissipation is many times greater than a heat transfer surface of the heat exchanger ( 35 . 54 . 72 . 85 . 88 . 101 . 102 ) for the transfer of heat energy to the thermoelectric module ( 28 . 55 . 65 . 73 . 86 . 89 . 103 . 104 ). Generator arrangement according to one of the preceding claims, characterized in that the sun-facing side of the collector space ( 30 . 53 . 75 . 77 . 78 ) is transparent and the remaining inner surfaces of the collector space are substantially black. Generator arrangement according to one of the preceding claims, characterized in that the sun-facing side of the collector space ( 30 . 53 . 75 . 77 . 78 ) a lens device ( 41 . 92 ) for focusing the solar radiation on the heat exchanger arrangement ( 33 ) and / or the photoelectric module. Generator arrangement according to one of the preceding claims, characterized in that the compensation unit ( 25 ) a heat energy store ( 26 ) having. Generator arrangement according to one of the preceding claims, characterized in that the compensation unit ( 25 ) a heat energy generator ( 27 ) having. Generator arrangement according to one of the preceding claims, characterized in that the photoelectric module ( 87 . 105 ) and the heat exchanger ( 84 . 99 . 100 ) for the absorption of heat energy from solar radiation in each case a collector space ( 77 ; 78 ) together with a thermoelectric module ( 86 . 89 . 103 . 104 ) are arranged. Generator arrangement according to one of the preceding claims, characterized in that the generator arrangement ( 20 . 49 . 60 . 67 . 76 . 91 . 98 ) a frame arrangement accommodating the generator arrangement ( 22 . 59 . 68 . 83 ) having. Method for obtaining in particular electrical energy from solar radiation using a generator arrangement ( 20 . 49 . 60 . 67 . 76 . 91 . 98 ), wherein at least one photoelectric module ( 50 . 69 . 87 . 105 ) and a thermoelectric module ( 28 . 55 . 65 . 73 . 86 . 89 . 103 . 104 ) and a heat exchanger arrangement ( 32 . 61 ) at least partially in a collector space ( 30 . 53 . 75 . 77 . 78 ) are arranged to collect heat energy from solar radiation and exposed to solar radiation, wherein an absorption of heat energy from solar radiation by means of the photoelectric module, the thermoelectric module, the heat exchanger assembly and the collector space is carried out and at least partially collected in the collector chamber, wherein by means of the heat exchanger assembly heat energy is supplied to the thermoelectric module for generating electrical energy and waste heat of the thermoelectric module by means of at least one further heat exchanger ( 43 ) is discharged for heat removal, and wherein by means of a fluid medium of at least one heat exchanger ( 33 . 56 . 71 . 84 . 99 . 100 ) of the heat exchanger arrangement an exchange of heat energy with a compensation unit ( 25 ) he follows. A method according to claim 11, characterized in that a substantially constant temperature difference at the thermoelectric module ( 28 . 55 . 65 . 73 . 86 . 89 . 103 . 104 ) between the heat exchanger arrangement ( 32 . 61 ) to the heat supply and the heat exchanger ( 43 ) for heat removal by means of the compensation unit ( 25 ) is achieved. A method according to claim 11, characterized in that a substantially adapted to an alternating need for electrical energy temperature difference at the thermoelectric module ( 28 . 55 . 65 . 73 . 86 . 89 . 103 . 104 ) between the heat exchanger arrangement ( 32 . 61 ) to the heat supply and the heat exchanger ( 43 ) for heat removal by means of the compensation unit ( 25 ) is achieved. Method according to one of claims 11 to 13, characterized in that the compensation unit ( 25 ) Stores heat energy. Method according to one of claims 11 to 14, characterized in that the compensation unit ( 25 ) by means of a heat generator ( 27 ) Heat energy of the heat exchanger arrangement ( 32 . 61 ) feeds. Method according to one of claims 11 to 15, characterized in that the solar radiation on the heat exchanger arrangement ( 32 ) and / or the photoelectric module by means of a lens device ( 41 . 92 ) is focused.