NL1028951C2 - Device for recording and storing solar energy. - Google Patents

Abstract

The device (7) for the absorbing and storing of solar energy, with a construction with PCM material for fastening to a roof (2) or to a facade, has the PCM material in the form of a low melting point PCM, and a heat pump (17) is connected to a pipe (12) located on one side of a panel-form element of PCM material to form a heating/cooling system. Independent claims are included for the following: (1) a building construction (1), a facade, and/or a roof upon which is installed the device for the absorbing and storing of solar energy; and (2) a method for the heating of building construction which is equipped with a device for the absorbing and storing of solar energy.

Description

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Device for recording and storing solar energy.

The present invention relates to a device for recording and storing (solar) energy, comprising a construction to be mounted on a roof or on a facade with a PCM material.

Such a device is generally known in the prior art. US 3,996,919 is mentioned as an example. This describes a system that can be installed on a sloping roof. The PCM material is present as a large number of cylinders that extend perpendicular to the roof structure. Separate lines are present to transfer the heat from the outer surface of the device to the cylinders filled with PCM material.

Such a construction is complex and not very attractive. On the other hand, PCM material appears to be particularly suitable for temporarily storing heat (during the day) and subsequently (at night) delivering it to the interior of an architectural construction.

Moreover, solar collectors are known in the prior art which are used, for example, for heating water. The fluid flowing through such solar collectors is then heated to 40 ° or higher. As a result, the applicability of such solar collectors is limited because, certainly in northern regions, the desired solar radiation is not always sufficiently present.

WO 85/00212 discloses a heating system operating with solar energy which is designed for operating at a higher temperature. The air coming from the heated PCM material with a high melting temperature, which functions as a heat buffer, has a temperature suitable for heating rooms directly.

DE 2914996 describes a solar collector without the use of a heat buffer, wherein the heated material is upgraded via a heat pump.

DE 3910356 describes a heat accumulator in combination with a PCM material, with a high melting temperature for direct use.

The object of the present invention is to make more efficient use of solar energy.

This object is achieved in a device described above in that said construction comprises a plate-shaped part to be arranged on said facade with a first side facing the roof or facade and a second side facing away from it, wherein a plate PCM plate is arranged in said plate-shaped part. material is provided, wherein the outer boundary of that PCM material comprises a radiation-absorbing material on the second side, a layer of insulating material is present on the first side and a conduit is present on the first side or on the second side PCM material extends along said plate in heat-exchanging contact with said PCM material.

According to the present invention there is provided a combination of PCM material and a conduit for dissipating the heat that is either stored in the PCM material or that can be recovered directly from the environment. The PCM material is arranged as a plate, disk or strip and can therefore easily follow the shape of the architectural construction such as the exterior of a roof or facade. That is, a relatively flat construction can be applied to the roof or to the facade in which sufficient PCM material is present to provide the desired storage. The device simultaneously serves as a solar collector, that is to say, depending on the circumstances, it can directly absorb heat and transfer it to the structural structure.

Although the radiation-absorbing layer can be the outside of the construction, according to an advantageous embodiment, a light-transmitting plate is arranged at a distance therefrom on the second side. This can be a glass plate or a plastic plate. An insulating layer (gas / air) is bounded between this plate and the radiation-absorbing material. In this way, in particular at night, it is possible to prevent the unacceptable emission of heat from the PCM material to the environment. According to a special variant of the invention, this space is also used as a gas conduction and more particularly as an air conduction.

However, it should be understood that it is also possible to provide a line for fluid such as a liquid or evaporating liquid in / behind the PCM material, i.e. on the first side.

According to a further advantageous embodiment of the present invention, measures are taken to prevent the device from overheating. To this end, a movable valve is provided which can cover the heat-absorbing material as required. It will be understood that the device described above can be further perfected with another construction known in the state of the art.

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One possibility is to use photovoltaic cells to generate energy simultaneously.

It is clear from the above that the device described above can be realized in a particularly simple manner. After all, PCM materials become increasingly cheaper due to the ever-increasing application. In addition, the construction used here is subject to particularly low requirements.

The device described above is suitable, for example, for a heating / cooling system in which a heat pump is included. This makes it possible to extract low-value heat from the device described above and to transform it into more high-quality heat that can be used for heating purposes, for example. As a result, the device described above becomes effective even with low solar radiation. A temperature of the fluid in the conduit of 0-10 ° is mentioned as an example. A fluid that is at this temperature can be transformed with a particularly high efficiency by a heat pump to a value of 30 ° or slightly higher, which is particularly suitable for use in underfloor heating and radiators with a relatively large heating surface in well-insulated homes.

This heating / cooling system can be further improved by combining floor heating with a PCM material. As a result, for example, heat can be stored during the day in a floor which can be released at night. This includes delivery via radiators that are located, for example, in bedrooms.

According to a further variant of the invention, it is possible to increase the heat accumulated on the roof during the day with a level of 0-10 ° C at night with the aid of a heat pump (at a low energy rate) to a higher temperature level of, for example, 30- 40 ° C and to transport this more high-quality heat to the floor 19, in which PCM material with a phase transition temperature between 30 and 40 ° C is present.

After completely bringing the PCM material present in the floor into the molten state, the remaining heat can be transferred to the radiators on the first floor. A heat pump is also used for this.

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Due to the separation of the heat supply to the floor and to the first floor, a heat pump that has a much smaller capacity will suffice.

The present invention also relates to an architectural construction in which the above described is realized, i.e. consisting of the combination of the above-described device and the heating / cooling system.

With the present invention, it is possible to considerably reduce the energy consumption in a home, office or other architectural construction. Heat stored during the day in the above-described device can be supplied to the structural structure at night with a heat pump. Running the heat pump at night can make use of the often applicable lower electricity rates. The medium that is moved from the device to the heat pump can comprise a gas such as air as described above. It is also possible to use water or a fluid for this purpose which, with a slight increase in temperature, changes to a different phase, such as freon and fluids similar thereto. By combining the device according to the present invention with photovoltaic cells, in addition to the energy recovery advantage, overheating of such photovoltaic cells can also be prevented and the efficiency thereof will thus be optimum.

The PCM material used in both the device and possibly under floor heating can be any PCM material known in the prior art. This is preferably such that optimum heat storage always takes place at the desired temperature and maximum efficiency is achieved for the entire installation, i.e. the combination with heat pump.

According to a particularly simple embodiment, the PCM material is a water-based liquid with a melting point between 0-10 ° C. Such a liquid is preferably impregnated in a foam material such as a melamine foam and subsequently packed in a foil material such as an aluminum foil material. The top side of such a foil material is black to function as an absorbent layer.

It has been found that a particularly small surface on the roof or on the facade can suffice. In a well-insulated house, a surface area of, for example, a few square meters is sufficient, the PCM plate having a thickness of between 5 and 35 mm. Due to the relatively low similar weight of PCM material, this can easily be used in or on structural constructions.

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the drawing. It shows: j

FIG. 1 a heating / cooling system according to the present invention with a first embodiment of the device according to the present invention; and

FIG. 2 a second embodiment of the device according to the present invention.

In Fig. 1, 1 denotes a structural construction. This consists of a sloping roof 2 that delimits a storey space 3 with a storey floor 5.

Below that is the ground floor space 4 with a ground floor floor 6.

The device according to the present invention is indicated in its entirety by 7 and can easily be mounted on the roof boarding 14 of roof 2. The side facing the roof is the first side and the side facing away from the roof is the second side. Optionally, a special roof covering can be applied or this roof covering can be omitted.

The device according to the present invention consists in this exemplary embodiment of a shielding plate 8. This consists of a light-transmitting material such as glass or plastic material. An insulating space 9 is provided below. This is filled with a gas such as air. Below that is a layer of insulating; applied material placed on the top of a PCM layer 11. This one !

PCM layer 11 is designed as a plate and can exist in the manner described above I

from a sheet of foam material in which PCM material is absorbed.

In the embodiment described here, a pipe 12 is arranged under the layer of PCM material. This can also be present in the PCM material. Conduit 12 is connected via a valve 15 to a conduit 16. A layer of insulating material 13 is arranged under the device according to the present invention. This can optionally form part of device 7 so that all this can be placed as a part on a roof construction.

| Conduit 16 is connected to heat pump 17.

| Via heat pump 17, heat can be transformed to a higher one temperature level. This is done via a line 25 which is connected via valves 21 and 22

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6 is with respectively floor heating 19 in the ground floor floor 6 and conventional radiators 18 on the floor space 3. A controller 23 is present for controlling the valves 21 and 22. Floor heating 19 is included in a granulate of PCM material 20.

A movable cover 24 is present which can limit the influence of solar radiation on the heat-absorbing layer 10.

The device described above works as follows. During the day, when the sun is shining, heat will be absorbed by the heat-absorbing layer 10 and stored in the PCM layer 11. As required, the heat can be transferred directly via line 12 to heat pump 17. During the day there will in particular be a need for heat on the ground floor 4 so that valve 21 is regularly controlled by controller 23 and therefore heat will be delivered to the underfloor heating 19 In part, this heat will be stored in the PCM material 20.

At the end of the day, the material in PCM layer 11 will have completely passed into the liquid phase and will contain a lot of energy. If overheating threatens, cover 24 can be operated so that radiation no longer falls on the heat-absorbing layer.

Subsequently, by operating heat pump 17 at a cheap energy rate, heat will be extracted from the PCM material via operation of the heat pump 17 and appropriate control of the valve 15. In that case, there is no heat requirement in the ground floor space 4 and the heat will be sent to floor 3. This effect can be further enhanced by extracting heat via floor heating 19 from the ground floor floor 19.

After all, there is a lot of heat in the PCM material 20, and by pumping back this energy, for example, the floor space 3 is transferred so that the bedrooms have a comfortable temperature at night.

After the above, it will be understood by those skilled in the art that many variants of the controls are possible. It is thus possible for the heat accumulated in the device 7 with the aid of the above described | 30 heat pump to be used for heating the ground floor at night 6. i

The full capacity of the PCM material 20 contained therein is used. Any remaining heat can then be used to provide heat energy to the floor pump with> 7 radiators installed on the floor. This can happen at the end of the night and at the beginning of the morning or during the day. This means that a relatively small heat pump will suffice.

For example, it is possible to charge the ground floor 6 at night with sufficient heat and to provide the radiators 18 with energy during the day.

With the present invention it is possible to suffice with very much less or no energy at all in a home or office building. If energy is required, less peak energy is required, so that smaller installations and low connection values will suffice.

With the present invention, it is possible to operate with particularly small temperature differences between the fluid in line 16 and the fluid in line 25. As a result, the heat pump only needs to upgrade the heat to a small extent. By working at relatively low temperature in line 16, maximum effect can be obtained even with low solar radiation.

15 Boilers are sufficient for the hot water requirement in homes.

Fig. 2 shows a variant of the device according to Figs. 1 and this is indicated in its entirety by 27. This consists of a shielding plate 28 which is also translucent. The space 29 corresponds to space 9, but the special feature is that it simultaneously functions as a conduit for a gas such as air. Flow of that gas is controlled by means of a valve 35. The PCM material is indicated by 31 and there is a heat-absorbing layer 30. An insulating layer 33 is provided under the PCM material.

It will be understood that also in this construction in the PCM material or behind it, i.e. on the first side directed towards the roof boarding, a pipe 25 can be present corresponding to pipe 16.

After the above, those skilled in the art will immediately come up with variants that are obvious after the above and are within | the scope of the appended claims.

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Claims (15)

Device (7, 17) for receiving and storing (solar) energy, comprising a construction to be attached to a roof (2) or to a facade with a PCM-5 material (11,31), characterized in that that construction comprises a plate-shaped part to be arranged on said facade with a first side facing the roof or a facade and a second side directed away therefrom, wherein a plate of PCM material is arranged in said plate-shaped part, the outer boundary of said PCM material comprises a radiation-absorbing material (10) on the second side, a layer of insulating material (13, 33) is present on the first side and a line (12, 29) is present on the first side or on the second side, which extends along that plate of PCM material in heat-exchanging contact with that PCM material. Device according to claim 1, wherein a light-transmitting plate (8, 28) is arranged on the second side at a distance from said radiation-absorbing material (10, 13). Device as claimed in claims 1 and 2, wherein said conduit (29) is an air conduit and extends between said radiation-absorbing layer and said light-transmitting plate (28). Device as claimed in any of the foregoing claims, wherein a valve (15, 35) is arranged in said conduit. 25 Device according to any of the preceding claims, comprising a movable, radiation / heat blocking cover (24, 44), which can cover said radiation-absorbing material. Device according to any of the preceding claims, wherein said PCM material has a melting point of 0-10 ° C. 1028951. Λ 7. Heating / cooling system comprising a device according to one of the preceding claims and a heat pump (17) connected to said pipe (12, 32). The heating / cooling system according to claim 7, wherein the other side of the heat pump (17) is connected to a floor heating system (19). The device according to claim 8, wherein said floor heating (19) comprises a PCM material (20) with a melting temperature of 25 to 40 ° C. 10 10. Structural construction (1) comprising a facade and / or roof (2) as well as a ground floor (6) and a storey space (3), wherein the device according to one of claims 1-5 is arranged on that case or on that roof. and in that construction the heating / cooling system according to claim 6 is arranged. 15 An architectural construction according to claim 10, wherein said heat pump is connected to a floor heating (19) arranged on the ground floor floor (6), which floor heating comprises PCM material. 12. Structural construction according to claim 10 or 11, comprising radiators arranged in the storey space (3) and connected to said cooling / heating system. 13. Structural construction as claimed in any of the claims 7-12, wherein said roof comprises a sloping roof and said device is arranged in / on said roof. 14. Method for heating a structural structure (1), which structure comprises a solar energy-absorbing and storing device arranged on the roof (2) / on the facade, which device is provided with a heat pump ( 17) connected fluid line (12, 32), which heat pump, on the other hand, is connected to heat emission means (18, 19) in that structural construction, which storage for solar energy comprises a PCM material, characterized in that, with solar radiation present and heat requirement of said structural construction fluid with that heat pump is recirculated by the solar energy storage and storage device and is transferred via said heat pump to the heat emission means, in the presence of solar radiation that PCM material is heated, in the absence of solar radiation and heat requirement in that structural engineer construction heat from that PCM material is transferred to those heat emission means. The method of claim 14, wherein the phase transformation temperature of 10 that PCM material is 0-10 ° C. 102895