奥地利专利AT510629A1 SOLAR COLLECTOR

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专利摘要:
The invention relates to a solar collector (1) comprising a collector housing (2), an absorber (3) arranged therein and traversed by a heat carrier fluid (13) for receiving solar radiation (28), a return line (6) leading to the absorber (3) a from the absorber (3) outgoing flow line (7). In this case, a pump (14) for circulating a heat transfer fluid (13) through the absorber (3) is arranged on or at least partially within the collector housing (2).
公开号:AT510629A1
申请号:T1855/2010
申请日:2010-11-11
公开日:2012-05-15
发明作者:Herbert Huemer
申请人:Xolar Renewable Energy Group Gmbh；
IPC主号:

专利说明:

- 1 -
The invention relates to a solar collector according to the preamble of claim 1 and to a method for operating a solar thermal reflector according to the preamble of claim 19.
Solar collectors are used in ever increasing proportions for the purpose of domestic water heating or space heating, which is due both to increasing environmental awareness as well as economic considerations.
By default, pumps for circulating a heat transfer fluid through solar panels are part of a so-called solar station and this is usually protected against the weather in a building, generally housed in a boiler room, where the solar collector system is coupled with other thermal equipment parts and the controller is located. From this integration of the solar panels in a hot water supply system or heating system, the reliability of a solar collector depends largely as a disadvantage in the installation of such solar stations is an addition to the actual collector installation required installation effort and space requirements.
The object of the invention is to provide a solar collector, which can be mounted with little effort and also put into operation.
The object of the invention is achieved by a solar collector with the characterizing features of claim 1. The arrangement of the circulating pump for the heat transfer fluid on or in the solar collector allows to dispense with its own solar station within a building, thereby reducing the cost of installation and commissioning of a solar system equipped with it. By integrating the pump on or in the solar collector, the degree of prefabrication is higher and problems with the circulation of the heat transfer fluid due to possible errors during installation of the solar station. * * · «« «« »· · * * * · · * * · * * · · *« # Be switched off from the beginning. The weather protection for the pump is given in the interior by the sealing of the solar collector.
By an embodiment of the solar collector according to claim 2 with a recooling function, the components of the solar collector in stagnation, ie in the absence of heat consumption by the heat consumer, significantly lower temperatures, which is why the components of the solar collector can be made using materials that lower requirements for temperature resistance are sufficient and therefore can be much cheaper than conventional high temperature resistant materials.
The simple control of the valve according to claim 3 based on the return temperature of the heat consumer to the solar collector circulated heat transfer fluid is a simple and reliable solution, as falls below a limit temperature obviously a heat demand on the heat consumer is present or heat storage capacity is free or exceeding the limit temperature no heat demand is present and the heat carrier fluid heated by the absorber is pumped to the recooling heat exchanger.
Controller and valve can be formed in the simplest case by a thermostatically controlled 3/2-way valve in which a switching position connects the return line with the absorber and a second switching position connects the absorber with the heat exchanger and the thermostat causes the switching between the two switching positions , It is important that the thermostat detects the temperature of the heat transfer fluid in the return line. Once the heat consumer, such as a hot water tank or a buffer has reached its maximum temperature, the temperature in the return line is correspondingly high and switches the valve of heat delivery to the heat consumer to heat dissipation through the heat exchanger.
The power supply of the pump according to claim 4 by a photovoltaic module arranged on the solar collector causes operation of the pump only with sufficient solar radiation, and promotes this heat for hot water or space heating purposes to the heat consumer, in the absence of heat demand, the pump, the heat transfer fluid to an optionally existing recooling heat exchanger promote. If there is no or insufficient solar radiation, the inadequate power supply will cause the pump to stop and extend its service life, since it will only operate if heat is to be supplied either to the heat consumer or to the recooled heat exchanger. The arrangement of the circulating pump on or in the solar collector and its power supply by a solar array arranged photovoltaic ikmodul causes the solar collector to a certain extent self-regulating in all operating conditions and thus has a high reliability, since in stagnation case an autonomous recooling is given and overheating problems be avoided. Furthermore, the commissioning of such a solar collector is very simple, since only the flow line and the return line must be connected to the heat consumer, and can be completely dispensed with the installation of power supply lines or control lines. Such a solar collector is universally applicable with high reliability and also allows easy commissioning of a solar collector system.
An arrangement of the recooled heat exchanger according to claim 5 is advantageous because a convection flow is formed by its warm surface and the generally existing inclination of a solar collector relative to the horizontal, which promotes the heat dissipation at the back of the solar collector. Furthermore, this does not reduce the area available for radiation absorption and power generation at the front,
The design of the solar collector according to claim 6 prevents unwanted heat dissipation from the solar collector, during normal operation with heat delivery to the heat consumer and prevents heat exchange between the absorber and the recooling heat exchanger. The thermal insulation can, as in conventional solar collectors of a mineral material, preferably mineral wool exist, but due to the lower stagnation temperature can be transferred to organic insulation materials or polymer foams with a temperature resistance of about 100 ° C.
An advantageous relationship between structural complexity and effectiveness of the heat exchanger is caused by an embodiment according to claim 7. Since the recooling heat exchanger can emit heat both by convection and heat radiation, it is possible to carry out this smaller than the absorber surface and still sufficient cooling of the heat transfer fluid is achieved. The recooling heat exchanger may also be formed by a part of the rear wall of the collector housing, to which, similar to the absorber, a line carrying the heat transfer fluid is fastened, whereby a good heat transfer is provided. Furthermore, it is possible that in a solar collector arrangement comprising a solar collector according to the invention, the other solar collectors can be designed as conventional collectors, since the circulation of the heat transfer fluid can be accomplished by a pump of the solar collector according to the invention. In the case of stagnation, the excess heat of the entire solar collector arrangement can be discharged via the recooling heat exchanger of the solar collector according to the invention.
In an embodiment according to claim 8, the dissipated amount of heat is maximized and the temperature can be kept even lower in stagnation case.
The design of the solar collector according to claim 9 is advantageous, since this represents a balanced compromise between sufficient power generation for safe supply of the pump and the lowest possible loss of absorber surface.
The power connection between the photovoltaic module and pump can advantageously be carried out according to claim 10 via a pulse control, which activates the pump only in pulses and thereby the power consumption can be minimized. Due to the inertia of the heat transfer fluid this flows in the lines even after switching off the pump for a short period of time. This makes it possible to make the active surface of the photovoltaic modules smaller and accumulate the resulting in the pulse pauses current in a power storage, such as an accumulator or a capacitor until the next pump pulse.
The embodiment of the control device according to claim 11 makes it possible for a user of a solar collector according to the invention or other persons to transmit state data of the solar collector, in particular the flow temperature or its energy yield, for example using a public mobile radio network. Saving such data for later evaluation can also be carried out by means of suitable memory devices.
Due to the lower in the case of stagnation temperature of the components of the solar collector this can be advantageously carried out according to claim 12, which can be used on less expensive materials in the production. -5-
The design of the solar collector according to claim 13 allows a structurally simple realization of the already described, automatic, autonomous control of the solar collector with respect to the change between normal operation and stagnation case.
Since the temperature of the heat transfer fluid in the branch of the return line is generally lower than in the branch of the supply line, the formation of the collector according to claim 14 is advantageous and the temperature load for the pump is thereby substantially lower.
Another measure for easier installation and commissioning of a solar collector according to the invention consists in the embodiment according to claim 15, whereby the separate installation of a surge tank in the boiler room or other spaces outside the Soiarkoilektors can be omitted. Preferably, the expansion tank is also disposed within the collector housing. The compensating vessel serves to accommodate a volume change associated with the temperature change of the heat transfer fluid.
A further facilitation of the commissioning of a solar collector according to the invention is achieved according to claim 16, since the collector can be made ready for operation without the use of filling pumps. The filler neck can in particular also be arranged on the compensating vessel described above.
An embodiment according to claim 17 is structurally advantageous because the safety valve can be used at the same time for filling the solar collector and the expansion tank at the filler neck. In addition to the safety valve can connect a line that opens into a collecting vessel, so that any leaking heat transfer fluid can not escape unhindered into the environment or eintre-th in a roof drainage,
An inventive solar collector can advantageously also be connected in a solar collector arrangement according to claim 18 with further solar collectors, which may be conventional solar collectors. In an embodiment with a recooling heat exchanger, the maximum number of conventional solar collectors without a heat exchanger depends on the maximum possible heat dissipation of the recooled heat exchanger on the solar collector according to the invention, wherein an upper maximum temperature must not be exceeded. -6-
The invention further relates to a method for operating a solar collector according to claim 19, according to which a pump for circulating the heat transfer fluid is arranged on or at least partially within the collector housing. This can be dispensed with a separate solar station within a building.
Furthermore, according to claim 20 in the heat transfer fluid when exceeding a limit temperature in the return line valve controlled by the absorber are passed through a heat exchanger in a recirculating cooling circuit and the pump are powered by a solar collector arranged on the photovoltaic module with power. This also causes the autonomous and self-powered operation of such a solar collector, are avoided in the damage due to overheating due to the automatic re-cooling.
The solar collector according to the invention can be operated in particular as a so-called low-flow collector, in which a relatively low flow rate of the heat transfer fluid is set, about 20 liters per square meter and hour, which is a relatively high flow temperature available in a short time.
For a better understanding of the invention, this will be explained in more detail with reference to the following figures.
Each shows in a highly schematically simplified representation:
Fig. 1 is a view of a solar collector according to the invention;
2 shows a section through a solar collector according to the invention in the installed position along line II - II.
3 shows a solar collector arrangement comprising a solar collector according to the invention as well as a conventional solar collector in parallel connection or series connection.
By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, the disclosures contained throughout the description can be mutatis mutandis to identical parts with the same reference numerals or the same component designations transferred. Also, the location information chosen in the description, such as above, below, on the side, etc., to those immediately described as well as * * 1 * * * *% ··························· 9 < • 9 9 9 9 7-figured figure and are to be transferred to the new situation in a change in position. Furthermore, individual features or combinations of features from the different exemplary embodiments shown and described can also represent independent, inventive or inventive solutions. All statements on ranges of values in the description of the present invention should be understood to include any and all sub-ranges thereof, e.g. the indication 1 to 10 should be understood to include all sub-ranges, starting from the lower limit 1 and the upper limit 10, i. all subregions begin with a lower limit of 1 or greater and end at an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1 or 5.5 to 10.
Fig. 1 shows a view of a solar collector 1, which is suitable for the conversion of solar radiation into thermal energy and is connected to a not dargesteiften heat consumers. The solar collector 1 comprises a collector housing 2, in which an absorber 3 is arranged, which is exposed to the solar radiation. The collector housing 2 may be designed like a frame, whereby a frame collector is formed, or for example, be carried out like a trough, whereby a so-called bucket collector is formed. The solar radiation facing the front side 4 of the solar collector 1 is preferably provided with a cover 5, which reduces heat losses of the solar collector 1.
In operation, the absorber 3 is flowed through by a heat transfer fluid and this is heated, wherein the absorber 3 can be designed as a surface or plate absorber or as a tube absorber. From the heat consumer, for example in the form of a water heating system or a heating system performs a return line 6 to the absorber 3 and the absorber 3 a flow line 7 to the heat consumer. In Fig. 1, the absorber 1 is formed as a flat collector, in which the solar radiation from an absorber sheet 8, which is formed for example from an aluminum foil or copper foil, is added. At the absorber plate 8 is shown in Fig. 1 meandering or harp-like absorber 9, through which the heat transfer fluid is passed, welded, whereby an optimal heat transfer from the absorber plate 8 is given to the absorber 9. The flow through the solar collector 1 with heat transfer fluid is indicated by black arrowheads.
The temperature changes of the heat transfer fluid occurring during operation cause a change in volume, which is compensated by means of an optional expansion tank 10. -8th-
This compensating vessel 10 may preferably be provided as part of the solar collector 1 and in particular be connected in the installation position of the solar collector 1 highest point of the absorber 3 and the return line 6 or the flow line 7. Furthermore, for filling the Koliektorkreislaufes a filler neck 11 may be provided which allows easy filling of the heat transfer fluid circuit. The filler neck 11 may further advantageously be provided with a safety valve 12, which protects the collector circuit from damaging overpressures. The filler neck 11 can also be arranged separately from the expansion tank 10 as an alternative to the representation in FIG. 1, but is preferably also connected at the highest point of the collector circuit.
In the expansion tank 10, the heat transfer fluid 13 is indicated, which fills the return line 6, the absorber line 9 and the flow line 7, so the complete collector circuit.
The solar collector 1 further comprises a pump 14, with which the heat transfer fluid 13 is transported through the collector circuit. In the illustrated embodiment, the pump 14 is arranged in the branch of the return line 6, with which the heat transfer fluid to be heated 13 is supplied to the absorber 3. Since the temperature of the heat transfer fluid 13 before the absorber 3 is generally lower than after the absorber 3, the thermal load for the pump 14 is thereby lower. The pump 14 is preferably designed as a centrifugal pump, with low-energy versions are preferably used,
The pump is preferably arranged so that it is easily accessible by its attachment outside of the collector housing 2 or through an opening in the latter, in order to facilitate an optionally required maintenance. Furthermore, an arrangement in the expansion tank 10 is possible.
The solar collector 1 may further advantageously comprise a recooling heat exchanger 15, with the excess heat that can no longer be absorbed by the heat consumer, can be delivered to the outside environment. This state in the absence of heat loss is also called Stagnationszustand and is in conventional solar collectors often in this state, the circulation of the heat transfer fluid 13 is terminated in order to avoid overheating of the heat consumer and the associated installation. While in conventional collector systems at this standstill of the heat transfer fluid, the temperatures of the collector constituent parts can assume very high values, such a designed solar collector 1 -9-
the heat transfer fluid 13 is guided by the absorber 3 through the recooling heat exchanger 15, whereby a recooling circuit 16 is formed within the solar collector 1 with which the temperature of the heat transfer fluid 13 is lowered.
The Rückkühlwärmetauscher 15 is parallel to the absorber 3 in the return line 6 and integrated with the flow line 7 and the pump 14 is located within the recirculating circuit 16. The recooling heat exchanger 15 is connected to or with a first line connection 17 with the flow line 7 and a second line connection 18 is connected to the return line 6 of the solar collector 1 and is passed to the recirculation of the heat transfer fluid 13 of this from the first line connection 17 on the flow line 7 in the direction of the second line connection 18 on the return line 6, wherein the heat exchanger 15 gives off heat to the outside environment and thereby the temperature of the heat transfer fluid 13 is lowered.
The Rückkühiwärmetauscher 15 can be similar to an absorber 3, for example, with a bordering on the outside environment heat exchanger surface to which a heat transfer fluid leading line 13 is attached with good, thermal contact.
Alternatively, the absorber 3 or the recooling heat exchanger 15 can also be designed as a plate heat exchanger, in which the heat transfer fluid is guided between two closely spaced parallel plates and not in a line of small cross-section.
The recooling heat exchanger 15 is arranged in the illustrated embodiment on the back 19 of the solar collector 1 and shown in dashed lines. The effective area of the back-cooling heat exchanger 15 may be made smaller than the absorber area, as e.g. is shown schematically in Fig. 1, but it is also possible to maximize the useful for the heat dissipation surface by the Rückkühiwärmetauscher extends substantially over the entire back 19 or at least 100% corresponds to the absorber surface.
Whether the heat transfer fluid 13 is guided from the absorber 3 via the feed line 7 to the heat consumer or is guided by the absorber 3 in the recirculating circuit 16 through the Rückkühiwärmetauscher 15 is preferably controlled by a valve 20 which is controlled temperature-dependent. In this case, by means of a temperature sensor 21 or a temperature sensor, the temperature of the heat transfer fluid 13 in the return line • ♦ * * · -10- 6 found and if this is below a certain limit temperature, the supply line of the absorber 3 connected to the return line 6 and thereby from the heat consumer supplied heat transfer fluid 13 is heated in the absorber 3 and returned via the feed line 7 back to the heat consumer or if the detected temperature is above a limit temperature, the recooling heat exchanger 15 connected to the absorber 3 and in the recirculating circuit 16, the absorbed radiation from the absorber 3 to the recooling heat exchanger 15 and from this given off as waste heat to the outside environment.
In the illustrated embodiment, the valve 20 is arranged at the position of the second line connection 18, it is alternatively also possible to arrange the valve 20 at the position of the first line connection 17 or to provide a valve on both the first line connection 17 and the second line connection 18, which can also be switched back to the inlet of the absorber 3 between a guide of the heat transfer fluid 13 via the feed line 7 to the heat consumer or via the recooling heat exchanger 15.
In order to activate the recooling heat exchanger 15, the valve 20 is brought into a recooling position, for which purpose a regulator 22 is provided. This controller 22 may be an independent component, but the control function may also be contained in the valve 20 or in the temperature sensor 21. For example, the valve 20 can be designed as a 3/2 thermostatic valve, which measures the temperature of the heat transfer fluid 13 in the return line 6 directly or indirectly. Another possibility of the controller 22 is that the temperature sensor 21 is designed as a thermostat and depending on the temperature present in the return line 6 activates an actuator of the valve 20 or changes the drive direction of an actuator.
The valve 20 may also be referred to as a reversing valve, since it has only two showings in the simplest case, but it is also a design as a mixer valve conceivable through which the absorber 3 supplied heat transfer fluid 13 in a variable distribution of the return line 6, ie from the heat consumer and mixed together by the recooling heat exchanger 15. In particular, an embodiment of the controller 20 using temperature-sensitive bimetals is possible.
The pump 14 is, as already mentioned, arranged within the recooling circuit 16, that is, as shown in FIG. 1, disposed between the second line connection 18 and the drain 3, but alternatively may also be arranged between the absorber 3 and the first Line connection 17 may be arranged.
So that the temperature sensor 21 is not in the influence of the recooling circuit 16, but actually measures the temperature in the return line 6, the temperature sensor 21 is arranged at a distance 23 from the recooling circuit 16, for example as shown in Fig. 1, just outside the collector housing 2, thereby it is in contact with the outside environment and cools down during the recooling operation, ie when the recooling circuit 16 is activated, as a result of which the limit temperature is not reached, the valve 20 is switched over and then heat transfer fluid 13 is returned to the absorber 3 from the return line 6. Should this have a temperature above the limit temperature, it is immediately switched back to the recooling operation. As a result, an automatic monitoring of the temperature in the return line 6 is ensured, since after each cooling of the temperature sensor 21 at least for a short time again heat transfer fluid 13 is brought from the heat consumer via the return line 6.
The distance 23 causes the temperature sensor 21 is thermally separated from the recooling circuit 16. It is also possible that the temperature sensor 21 is arranged for example in the boiler room, whereby, however, the installation cost is higher again.
The energy for the operation of the pump 14 may be supplied via an electrical supply line, for example from a boiler room, but may also, as exemplified in Fig. 1, be provided by a photovoltaic module 24 which is arranged on the solar collector 1. This can be integrated in the solar collector housing 2 or covered with the cover 5 or arranged outside of this or it is also an arrangement outside the collector housing 2 conceivable. However, the integrated arrangement makes it possible to mount a solar collector 1 according to the invention immediately adjacent to adjacent collector units and thus make the best possible use of existing installation areas.
The photovoltaic module 24 may also be referred to as a solar module and converts the energy of the solar radiation directly into electrical energy using the photoelectric effect, which can serve to supply the pump 14. In addition, it can also be used to supply the valve 20 with an optional valve drive, to supply the regulator 22, a control device or the temperature sensor 21. All common types of solar modules -12-
possible, wherein these are constructed, for example, using mono- or polycrystalline solar cells or other types of solar cells, and reference is made at this point to the known state of the art of photovoltaic modules 24.
The optically active surface of the photovoltaic module 24 is chosen so that a sufficient supply voltage is provided in the case of solar radiation which is suitable for sensible, thermal utilization. Since with an integrated arrangement of the photovoltaic module 24, the optically active surface reduces the usable absorber surface of the absorber 3, it is advantageous if the optically active surface is kept as small as possible and are therefore preferred designs with a high efficiency. In Fig. 1, for simplicity, only a power supply line 25 between the photovoltaic module 24 and pump 14 is shown, but it is possible that lead to other power consumers, such as valve 20, temperature sensor 21 and controller 22 additional power supply lines 25, either directly from Go away photovoltaic module 24 or disconnect from the one power supply line 25. In a further embodiment of the solar collector 1, a control device 26 may be provided in the course of the power supply line 25, with which the operation of the pump 14 can be influenced, for example by the control device 26 is formed as an impulse control and the pump 14 is only activated in pulses.
The control device 26 may further include a transmitting unit 27, with which a transmission of state data of the solar collector 1 to a user interface or a data memory can be performed. For example, the pump running time, the flow temperature, the return temperature, the harvested thermal energy, etc. can be transmitted to the user for information or recorded in a data memory for later evaluations. The transmission to the user can take place in particular via a wireless network or a mobile radio network, whereby a user without having to be in the vicinity of the boiler room or the solar collector 1, can be informed about the operating state of the solar collector 1.
Since the temperature of the heat transfer fluid 13 can be kept at a relatively low level, for example below 95 ° C, in particular below 85 ° C in the stagnation case by the removal of excess heat through the recooling circuit 16, it is possible for the solar collector 1 parts thereof, such as For example, the collector housing 2, the absorber 3, the recooling heat exchanger 15, as well as heat transfer lines predominate.
form of polymer material. As a result, in the case of a solar collector 1 equipped with a recooling heat exchanger 15, additionally lower production costs and / or weight savings can be achieved without its service life being shortened as a result.
Fig. 2 shows a section through a solar collector 1 with an integrated pump 14 along line II - II in Fig. 1 as it has already been described with reference to FIG. 1 and are the same reference numerals for the same or equivalent components.
FIG. 2 shows an embodiment in which the solar radiation 30 incident on the front side 4 of the solar collector 1 is emitted in the state of stagnation by a recooling heat exchanger 15 on the rear side 19 of the solar collector 1 as waste heat 31 to the outside environment 32. The solar collector 1 is shown in a conventional oblique mounting position in middle latitudes and this corresponds to the usual roof mounting or elevated assembly.
The absorber 3 is provided to reduce waste heat losses on the front side 4 of the solar collector 1 with a cover 5 and is further arranged between the absorber 3 and back 19 of the solar collector 1, a thermal insulation 33. In conventional solar co -ectors, this good thermal insulation of the absorber 3 is responsible for the fact that very high temperatures occur in the case of stagnation, which can adversely affect the components of the solar collector 1 and the heat transfer fluid 13 and can significantly shorten their service life.
In Fig. 2, the return cooling circuit 16 and the flow direction of the heat transfer fluid 13 is further characterized by arrowheads.
3 shows a solar collector arrangement 32, which comprises at least two solar co-ordinators 33 connected in series or in parallel, wherein at least one solar collector 33 is designed as a solar collector 1 according to the invention. To avoid repetition with respect to the execution and operation of the solar collector 1 to the description of the preceding Figs. 1 and 2 referenced.
In Fig. 3, the left solar collector 33 is designed as an inventive solar collector 1, which in addition to the absorber 3 and the pump 14 includes an optional recooling heat exchanger 15. The circulation of the heat transfer fluid 13 through the entire solar collector arrangement 32 can be accomplished by the pump 14 of the solar collector 1 according to the invention, whereby additional pumps or a solar station in the boiler room can be omitted. The pump 14 is preferably powered by a photovoltaic module 24 again. The switchover between normal operation and recooling operation takes place by means of a valve 20, which is adjusted based on the temperature measured in the return line 6 with the temperature sensor 21 by means of a regulator 22 as a function of the measured temperature.
Connected to the solar collector 1 according to the invention is another solar collector 33, which in the illustrated embodiment is designed as a conventional solar collector without a pump 14, a recooling heat exchanger 15 and a photovoltaic module 24. The further solar collector 33 can be connected as shown in solid lines, parallel to the first solar collector 1 or alternatively, as shown in dashed lines, connected to the first solar collector 1 in series. In both connection variants, in the event of stagnation, the optional recooling circuit 16 also extends to the one or more solar collectors 33, whereby these lower temperature loads are also exposed. The heat exchanger surface of the return heat exchanger 15 can also be made larger in the solar collector 1 according to the invention, which also in a solar collector assembly 32 which includes a larger number of solar panels 33, only an inventive solar collector 1 is required. The advantageous effects of the solar collector 1 according to the invention, such as the ease of assembly and the automatic self-contained temperature limitation in the stagnation case and the monitoring of the heat demand by temperature measurement in the return line 6, also act on the entire solar collector arrangement 32.
The embodiments show possible embodiments of the solar collector 1, wherein it should be noted at this point that the invention is not limited to the specifically illustrated embodiments of the same, but rather also various combinations of the individual embodiments are mutually possible and this possibility of variation due to the teaching of technical action representational invention in the skill of those skilled in this technical field.
So there are all conceivable variants, which are possible by combinations of individual details of the illustrated and described embodiments, a separate protection accessible, possibly by making divisional applications. - 15-
For the sake of order, it should finally be pointed out that, for a better understanding of the construction of the solar collector, this or its constituent parts have been shown partly out of scale and / or enlarged and / or reduced in size.
The task underlying the independent inventive solutions can be taken from the description.
Above all, the individual in Figs. 1; 2; 3 embodiments form the subject of independent solutions according to the invention. The relevant objects and solutions according to the invention can be found in the detailed descriptions of these figures.
References 1 Solar collector 2 Collector housing 3 Absorber 4 Front 5 Cover disc 6 Return line 7 Supply line 8 Absorber surface 9 Absorber line 10 Expansion vessel 11 Filler neck 12 Safety valve 13 Heat transfer fluid 14 Pump 15 Re-cooling heat exchanger 16 Return circuit 17 Line connection 18 Line connection 19 Rear 20 Valve 21 Temperature sensor 22 Controller 23 Distance 24 Photovoltaic module 25 Power supply line 26 Control device 27 Transmitting unit 28 Solar radiation 29 Waste heat 30 Outside environment 31 Thermal insulation 32 Solar collector arrangement 33 Solar collector N2010 / 24500

权利要求:
Claims (20)
[1]
1. Solar collector (1) comprising a collector housing (2), a angeord Neten and by a heat transfer fluid (13) through-flow absorber (3) for receiving solar radiation (28), to the absorber (3) leading return line (6 ) and one of the absorber (3) outgoing flow line (7), characterized in that a pump (14) for circulating a heat transfer fluid (13) through the absorber (3) on or at least partially within the collector housing (2) is arranged.
[2]
2. Solar collector (1) according to claim 1, characterized in that by means of at least one valve (20) with the return line (6) and the flow line (7) connectable heat exchanger (15) in a recooling position of the valve (20) with the absorber (3) forms a recooling circuit (16) and communicates with the external environment (30) of the solar collector (1), and the heat transfer fluid (13) by means of the pump (14) by the recirculating circuit (16) is recirculated.
[3]
3. Solar collector (1) according to claim 2, characterized in that on or in the solar collector (1) a temperature-dependent controller (22) for adjusting the valve (20) is arranged.
[4]
4. Solar collector (1) according to one of claims 1 to 3, characterized in that the pump (14) with a solar collector (1) arranged Photovoltaikmo-module (24) is connected to the power supply.
[5]
5. Solar collector (1) according to one of claims 2 to 4, characterized in that the recooling heat exchanger (15) on the back (19) of the solar collector (1) is arranged. N2010 / 24500 -2-

[6]
6. SolarkoHektar (1) according to one of claims 2 to 5, characterized in that the recooling heat exchanger (15) by means of a thermal insulation (31) is thermally separated from the absorber (3).
[7]
7. Solar collector (1) according to one of claims 2 to 6, characterized in that the recooling heat exchanger (15) has a heat exchanger surface which is between 20% and 95% of the absorber surface.
[8]
8. Solar collector (1) according to one of claims 2 to 6, characterized in that the recooling heat exchanger (15) has a heat exchanger surface which is at least 100% of the absorber surface or substantially through the entire back (19) of the solar collector (1) is.
[9]
9. Solar collector (1) according to one of claims 4 to 8, characterized in that the photovoltaic module (24) has an optically active surface which is between 2% and 30% of the absorber surface.
[10]
10. Solar collector (1) according to one of claims 4 to 8, characterized in that on the power connection line (25) between the photovoltaic module (24) and pump (14) comprises a control device (26), in particular a pulse control.
[11]
11. Solar collector (1) according to claim 10, characterized in that the control device (26) with a transmitting unit (27) for, in particular wireless transmission of state data of the solar collector (1), in particular the pump running time, the flow temperature and the return temperature to a User interface or a data store.
[12]
12. Solar collector (1) according to one of claims 1 to 11, characterized in that at least one of the components flow line (7), return line (6), absorber (3), heat exchanger (15), collector housing (2), thermal insulation (31 ) is formed predominantly of polymer material. N2010 / 24500 -3-

[13]
13. Solar collector (1) according to one of claims 3 to 12, characterized in that the controller (22) is controlled by a on the return line (6) and the return cooling circuit (16) distant temperature sensor (21).
[14]
14, the solar collector (1) according to one of claims 2 to 13, characterized in that the pump (14) in the return cooling circuit (16) in the branch of the return line (6) is arranged.
[15]
15. Solar collector (1) according to one of claims 1 to 14, characterized in that the absorber (3) arranged in a mounting position of the solar collector (1) above the absorber (3) and preferably within the collector housing (2) arranged compensating vessel ( 10) is connected.
[16]
16. Solar collector (1) according to one of claims 1 to 15, characterized in that the absorber (3) at its installation position in the solar collector (1) highest point, a closable filler neck (11).
[17]
17. Solar collector (1) according to claim 16, characterized in that the filler neck (11) is provided with a safety valve (12).
[18]
18. Solar collector arrangement (32) comprising two or more solar collectors (33) connected in series or in parallel, characterized in that at least one solar collector (33) as a solar collector (1) according to one or more of claims 1 to 17 is formed.
[19]
19. A method for operating a solar collector (1) in which a heat transfer fluid (13) from a return line (6) arranged in a collector housing (2) and the solar radiation (28) facing the absorber (3) to a flow line (7) is guided, characterized in that the circulation of the heat transfer fluid (13) by at or at least partially within the collector housing (2) arranged pump (14). N2010 / 24500
[20]
20. The method according to claim 19, characterized in that the Wärmeträ gerfluid (13) when a limit temperature in the return line (6) is valve-controlled after the absorber (3) by a recooling heat exchanger (15) in a recirculating circuit (16) is guided and the Pump (14) from a solar collector (1) arranged photovoltaic module (24) is supplied with power. Xolar Renewable Energy Group GmbH

Lawyer Partner Right JH N2010 / 24500

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同族专利:

公开号 | 公开日

EP2638333B1|2014-10-22|

WO2012061865A3|2012-09-07|

AT510629B1|2013-12-15|

EP2638333A2|2013-09-18|

WO2012061865A2|2012-05-18|

ZA201303545B|2014-07-30|

US20130276868A1|2013-10-24|

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DE202006008162U1|2006-05-19|2006-08-24|Stefanakis, Jannis, Dipl.-Ing.|Flat shaped solar heat collector has welded construction with inner guide walls and with integral circulation pump and heat exchanger tank|

PT103618B|2006-12-18|2008-11-28|Univ Do Porto|INTELLIGENT DEVICE FOR SOLAR ENERGY ADEQUACY AND LIGHT INPUT ADJUSTMENT|

KR100807846B1|2006-12-20|2008-02-27|성인식|Semi-cylindrical type of solar collection boiler|CN102840700A|2012-08-23|2012-12-26|江苏启能新能源材料有限公司|Idle sunning overheat protection device of solar heat collector|

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GB2514098A|2013-05-04|2014-11-19|Samuel Gerard Bailey|Overheat protection system for solar thermal collectors|

DE102013112607A1|2013-07-10|2015-01-15|Innovative Motion Gmbh|Solar collector assembly|

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GR1009038B|2014-12-01|2017-05-19|Μιχαηλ Αθανασιου Φιλιππιδης|Photovoltaic heat sink-equipped thermal energy-managing system|

IT201700119024A1|2017-10-20|2019-04-20|Mas Roof S R L|MODULAR MULTIFUNCTION PANEL|

WO2021175424A1|2020-03-05|2021-09-10|Logic Ip Ag|A system for extracting thermal energy|

法律状态:
2016-07-15| MM01| Lapse because of not paying annual fees|Effective date: 20151111 |

优先权:

申请号 | 申请日 | 专利标题

ATA1855/2010A|AT510629B1|2010-11-11|2010-11-11|SOLAR COLLECTOR|ATA1855/2010A| AT510629B1|2010-11-11|2010-11-11|SOLAR COLLECTOR|

US13/513,847| US20130276868A1|2010-11-11|2011-11-11|Solar Collector|

PCT/AT2011/050029| WO2012061865A2|2010-11-11|2011-11-11|Solar collector|

EP20110810542| EP2638333B1|2010-11-11|2011-11-11|Solar collector|

ZA2013/03545A| ZA201303545B|2010-11-11|2013-05-16|Solar collector|

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