JP2011001713A - Photovoltaic power generation heat collection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a photovoltaic power generation heat collection system capable of efficiently using heat stored in a heat storage means.SOLUTION: A roof surface 42 of a building is provided with a solar cell module 8 in a state of interposing an air flow layer S between itself and the roof surface 42, and a heat transfer means 13 is connected to the air flow layer S. The heat transfer means 13 is connected to a ceiling space 21 between an intermediate floor 15 and the ceiling 20 provided directly under the intermediate floor 15, and the ceiling space 21 is provided with the heat storage means 12 for storing heat. Since the ceiling 20 is provided with a heat insulating material 24 higher in heat insulating effect than the ceiling 20, heat stored in the heat storage means 12 can be efficiently used as floor heating.

Description

  The present invention relates to a solar power generation heat collection system capable of performing both power generation and heat collection using solar energy.

The thing of patent document 1 is known as an example of the solar power generation heat collection system which can perform both electric power generation and heat collection using solar energy.
In this solar power generation heat collecting system, a plurality of solar cell modules are disposed on a roof surface, and a translucent member is provided above these solar cell modules so as to cover at least the upper part of the solar cell module. An air circulation layer is formed between the translucent member and the roof surface, and a heat transfer means connected to the heat storage means that is disposed under the floor and stores heat is connected to the air circulation layer. .

In such a solar power generation heat collection system, sunlight can be converted into electricity (electric power) by the solar cell module disposed on the roof surface, and power consumed in the building can be covered. Can be self-sufficient.
Further, a translucent member is provided above the solar cell module so as to cover at least the upper part of the solar cell module, an air circulation layer is formed between the translucent member and the roof surface, and further, an air circulation layer Since the heat transfer means connected to the heat storage means under the floor is connected to the solar heat, the air is heated by being transmitted to the air in the air circulation layer through the translucent member, Further, heat is stored in the heat storage means via the heat transfer means. As a result, the heat stored in the heat storage means can be used for floor heating, and the power used for the heating device or the like can be reduced.
Therefore, since power generation and heat collection can be performed simultaneously in this way, the utilization efficiency of solar energy can be improved.

JP 2005-226978 A

By the way, in the above-mentioned conventional solar power generation heat collecting system, heat storage means was installed under the floor on the first floor to provide floor heating on the first floor, but between the floor on the second floor and above and the ceiling plate directly below it. By installing the heat storage means, floor heating of the second floor or higher can be achieved.
However, the heat from the heat storage means is released not only upward but also downward. Therefore, if the heat storage means is installed between the floors of two or more floors and the ceiling directly below it, a part of the heat released from the heat storage means heats the ceiling, so one part of the heat released from the heat storage means. Therefore, the heat stored in the heat storage means could not be used efficiently.

  This invention is made | formed in view of the said situation, and makes it the subject to provide the solar power generation heat collecting system which can use efficiently the heat stored by the heat storage means.

In order to solve the above-mentioned problem, the invention according to claim 1, for example, as shown in FIGS. 1 to 6, the solar cell module 8 flows between the roof surface 42 and the roof surface 42 of the building. Provided with the layer S interposed,
Heat transfer means 13 is connected to the air circulation layer S,
The heat transfer means 13 is connected to a ceiling space 21 between a floor (for example, the intermediate floor 15) above the first floor 30 of the building and a ceiling 20 provided immediately below the floor 15. ,
The ceiling space 21 is provided with heat storage means 12 for storing heat,
The ceiling 20 is provided with a heat insulating material 24 having a heat insulating effect higher than that of the ceiling 20.

According to the first aspect of the present invention, the solar heat is transmitted through the solar cell module 8 and transmitted to the air in the air circulation layer S, whereby the air is heated and the heated air is transferred to the heat transfer means 13. Through the ceiling 15 provided between the floor 15 above the first floor 30 of the building and the ceiling 20 provided directly below the floor 15, and the heat of the heated air flows into the ceiling space. The heat is stored in the heat storage means 12 provided in 21.
As a result, the heat stored in the heat storage means 12 can be used for floor heating, and since the heat insulating material 24 having a higher heat insulating effect than the ceiling 20 is provided on the ceiling 20, it is released downward from the heat storage means 12. Most of the generated heat is insulated by the heat insulating material 24. Therefore, the heat stored in the heat storage means 12 can be efficiently used as floor heating.

The invention according to claim 2 is the solar power collection system according to claim 1,
The floor above the first floor 30 is an intermediate floor 15 at an intermediate position of a specific floor (for example, the second floor),
A storage space 17 is provided between the intermediate floor 15 and the specific floor (second floor 16).
The heat storage means 12 is provided in a ceiling space 21 between the intermediate floor 15 and a ceiling 20 provided immediately below the intermediate floor 15.

According to the second aspect of the present invention, most of the heat released downward from the heat storage means 12 is thermally insulated by the heat insulating material 24, so that the heat stored in the heat storage means 12 can be used efficiently. At the same time, the ceiling 20 is heated by a part of the heat transmitted through the heat insulating material 24 and can be used for heating the storage space 17 below. That is, since the storage space 17 is lower in height from the floor surface to the ceiling than the living room, the storage space 17 can be warmed to some extent by the heated ceiling 20. The storage space 17 does not need to be heated as much as a living room in winter, but is maintained to a certain temperature by being heated to some extent, which is useful for maintenance of stored items.
Further, by changing the performance of the heat insulating material 24, the ratio of the heat flowing upward and the heat flowing downward can be changed.

The invention according to claim 3 is the solar heat collecting system according to claim 2,
A room 18a on the specific floor (for example, the second floor) floor 16 is adjacent to the storage space 17,
An air outlet 25 is provided between an end of the intermediate floor 15 on the side of the room 18a and an end of the ceiling 20 on the side of the room 18a.

  According to the invention described in claim 3, since the air outlet 25 is provided between the end of the intermediate floor 15 on the room 18 a side and the end of the ceiling 20 on the room 18 a side, Warm air warmed by the released heat is discharged from the air outlet 25 and can be used for heating the room 18a on the specific floor.

Invention of Claim 4 is a solar power generation heat collecting system as described in any one of Claims 1-3,
An air flow passage 23 is provided between the heat storage means 12 and the ceiling 20.

  According to the fourth aspect of the present invention, since the air flow passage 23 is formed between the heat storage means 12 and the ceiling 20, the warm air warmed by the heat released downward from the heat storage means 12 is generated. Since it reaches the ceiling space 21 through the air flow passage 23, it can be effectively used as floor heating.

Invention of Claim 5 is a photovoltaic power generation heat collecting system as described in any one of Claims 1-4,
The heat storage means 12 is a latent heat storage material that stores heat using latent heat.

  According to the invention described in claim 5, since the heat storage means 12 is a latent heat storage material, the heat storage capacity can be made relatively large, and the heat storage temperature is stabilized, so that the heat storage effect can be enhanced.

  According to the present invention, the heat stored in the heat storage means can be used for floor heating, and since the heat insulating material having a higher heat insulation effect than the ceiling is provided on the ceiling, the heat is released downward from the heat storage means. Since most of the heat is insulated by a heat insulating material, the heat stored in the heat storage means can be used efficiently.

It is a disassembled perspective view which shows an example of the building provided with the solar power generation heat collecting system which concerns on this invention. It is a figure which shows schematic structure of the solar power generation heat collecting system which concerns on this invention. It is a longitudinal cross-sectional view of the principal part which shows an example of the building provided with the solar power generation heat collecting system which concerns on this invention. The roof of the building provided with the solar power generation heat collecting system which concerns on this invention is shown, and it is principal part sectional drawing cut | disconnected by the vertical surface parallel to a building. It is principal part sectional drawing cut | disconnected by the vertical plane orthogonal to a ridge in the same. FIG. 6 is an enlarged view of the main part of FIG. 5.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is an exploded perspective view showing an example of a building provided with a solar power collection system according to the present invention, FIG. 2 is a diagram showing a schematic configuration of the solar power collection system, and FIG. It is a longitudinal cross-sectional view of the principal part which shows an example of the building provided with the system.

  The building 1 shown in FIGS. 1 to 3 includes a building body 3 constructed on a foundation 2 and a roof 4 formed on the building body 3. The roof 4 is formed by arranging a plurality of roof panels 41 in a girder direction, and the roof panel 41 assembles the eaves into a rectangular frame shape as shown in FIG. 4, and reinforcing bars inside the rectangular frame. Are assembled vertically and horizontally to constitute a frame body 41a, and a face member 41b such as a field plate is provided on the upper surface of the frame body 41a. A plurality of roof panels 41 are arranged to form roof surfaces 42 having a downward slope from the ridge 5 toward the eaves on both sides of the ridge 5.

The roof surface 42 on one side of the roof surfaces 42 formed on both sides of the ridge 5 has a plurality of see-through solar cell modules 8 with the air circulation layer S interposed between the roof surfaces 42. Is provided.
The see-through solar cell module 8 has a rectangular thin plate shape, in which PV cells of single crystal silicon are enclosed between tempered glass (upper surface) and transparent backsheet (lower surface) using EVA resin. In addition, the sunlight irradiated between the PV cell and the PV cell is transmitted through the transparent back sheet, so that the daylighting property is secured.

As shown in FIGS. 4 to 6, a rectangular frame-shaped frame 9 surrounding the peripheral portion is formed at the peripheral portion of the see-through solar cell module 8 (hereinafter, abbreviated as the solar cell module 8) as described above. Is provided.
The frame 9 connects a pair of vertical frame portions 9 </ b> A arranged on the left and right along the inclination direction of the roof 4 and the upper and lower ends of the vertical frame portions 9 </ b> A and is arranged along the girder direction of the roof 4. The upper frame portion 9B and the lower frame portion 9C are provided. The solar cell module 8 is waterproofed and reinforced by the vertical frame portion 9A, the upper frame portion 9B, and the lower frame portion 9C.

  As shown in FIG. 6, the upper frame portion 9B is a long member integrally formed by extrusion molding of aluminum or the like. The upper frame portion 9B is a frame main body 91B having a rectangular cross section and an upper portion of the frame main body 91B. A contact piece 92B (substantially L-shaped in cross section provided in an obliquely upward direction along the inclined direction) is provided (in FIG. 6, the contact piece 92B extends to the left in terms of the drawing). In addition, a pair of protruding pieces 93B into which the solar cell module 8 is fitted are provided at the lower part of the frame main body 91B.

  As shown in FIG. 6, the lower frame portion 9C is a long member integrally formed by extrusion molding of aluminum or the like, and has a cylindrical frame main body 91C having an L-shaped cross section and a lower portion of the frame main body 91C. A collar portion 92C projecting obliquely downward along the inclination direction of the roof 4 (in FIG. 6, the collar portion 92C projects rightward for reasons of drawing) and hangs downward from the lower surface of the collar portion 92C. A draining portion 93C and an intermediate connecting portion 94C that connects an intermediate portion of the draining portion 93C and a side surface of the frame main body 91C are provided. In addition, a pair of protruding pieces 95C into which the solar cell module 8 is fitted is provided on the upper portion of the frame main body 91C.

  On the other hand, as shown in FIG. 4, the vertical frame portion 9 </ b> A is a long member having a substantially L-shaped cross section, and the pair of vertical frame portions 9 </ b> A arranged on the left and right along the inclination direction of the roof 4 Each is fixed to a support rail 10 mounted on the surface 42. Each vertical frame portion 9A has a pair of projecting pieces 91A into which the solar cell module 8 similar to the above-described upper frame portion 9B and lower frame portion 9C is fitted, and a fixed piece 92A fixed to the support rail 10. I have. The pair of vertical frame portions 9A arranged on the left and right sides has an opening K formed on the upper surface thereof, and a cover member 93A is attached to the opening K with a screw B2.

The solar cell module 8 in which the frame 9 as described above is provided at the periphery is supported by the support rail 10 with the air circulation layer S interposed between the solar cell module 8 and the roof surface 42.
The support rails 10 are long ones that extend from the eaves of the roof 4 toward the ridge on the roof surface 42, and a plurality of the support rails 10 are provided at predetermined intervals in the ridge direction. The solar cell module 8 is supported by 10.
As shown in FIG. 4, the support rail 10 supports the vertical frame receiving portion 101 and the vertical frame receiving portion 101 which is hollow and receives the fixing piece 92A of the vertical frame portion 9A and is fixed by screws B3. A vertical frame support portion 102 fixed on the roof surface 42 with screws B4 is provided. At both ends along the longitudinal direction of the vertical frame receiving portion 101, water stop portions 103 are formed to prevent rainwater or the like that has entered from between the solar cell module 8 and the cover member 93 </ b> A from falling on the roof surface 42. ing.

The solar cell module 8 configured as described above is attached to the roof surface 42 as follows.
That is, the frame 9 is attached to the solar cell module 8 by fitting the peripheral edge portion thereof into the pair of projecting pieces 91A, 93B, and 95C of the vertical frame portion 9A, the upper frame portion 9B, and the lower frame portion 9C. . Further, as shown in FIG. 4, the support rail 10 is attached on the roof surface 42 by fixing the vertical frame support portion 102 with screws B 4, and the vertical frame portion 9 A is attached to the support rail 102. The solar cell module 8 is attached by being supported.
Specifically, the solar cell modules 8 that are adjacent to each other in the vertical direction are, as shown in FIGS. 5 and 6, a solar cell module that is disposed above the upper frame portion 9B of the solar cell module 8 that is disposed below. 8C, the flange 92C of the lower frame portion 9C contacts the upper surface of the frame main body 91B of the upper frame portion 9B, and the contact piece 92B of the upper frame portion 9B is the frame main body of the lower frame portion 9C. By abutting the side surfaces of 91C, they are loosely fitted to each other.
Further, the solar cell modules 8 adjacent to each other in the left-right direction are arranged such that the support rails 10 of the vertical frame portion 9A of the solar cell module 8 arranged on the right side and the vertical frame portion 9A of the solar cell module 8 arranged on the left side are arranged. A fixed piece 92A of each vertical frame portion 9A is fixed to the vertical frame receiving portion 101 with screws B3. Further, a cover member 93A is attached to the opening K formed on the upper surfaces of both the vertical frame portions 9A by screws B2. That is, the cover member 93 </ b> A is disposed between the solar cell modules 8 adjacent to the left and right.
Thus, the solar cell module 8 is provided with the air circulation layer S interposed between the solar cell module 8 and the roof surface 42.
As shown in FIG. 1, a plurality of solar cell modules 8 are installed in the inclination direction of the roof 4, but the solar cell except that there is no PV cell in the vicinity of the building instead of the solar cell module 8. A transparent glass module 8a having the same structure as that of the module 8 is installed. As a result, the temperature of the air circulation layer S can be increased and the amount of sunlight can be improved. The housing of the transparent glass module 8a is the same as that of the solar cell module 8.

In addition, as shown in FIG. 5, the air circulation layer S is formed in the gap 423 of the face door 46 attached to the eaves side of the solar cell module 8 and the opening formed on the ridge 5 side of the roof surface 42 and leading to the attic. 424. The heat transfer means 13 is connected to the opening 424.
Here, the heat transfer means 13 is connected to the opening 424 formed on the ridge 5 side of the roof surface 42 because the air heated in the air circulation layer S is directly transferred from the ridge 5 side of the roof 4 to the heat transfer means. This is because the data can be transmitted to 13. That is, since high temperature air tends to rise to the ridge 5 side of the roof 4, it is preferable to provide the heat transfer means 13 on the ridge 5 side because the heat collection rate is higher than the case where it is provided on the eaves side.

Any heat transfer means 13 may be used as long as it can transfer the heat collected in the air circulation layer S. In addition to a combination of a transport fan and a duct, for example, a pipe made of metal such as aluminum or copper having high thermal conductivity. And ducts. In particular, a known heat pipe in which a volatile liquid is sealed in the pipe is suitable.
In this Embodiment, as shown in FIGS. 1-3, the fan unit 13e provided with the ducts 13a, 13b, 13c, the chamber box 13d, and the fan is used as the heat-transfer means 13. FIG.
The duct 13a has one end connected to an opening 424 formed in the roof surface 42 and the other end connected to the chamber box 13d. A plurality of openings 424 are provided along the roof ridge direction, and the ducts 13a are connected to the openings 424, respectively.

The chamber box 13d has a cylindrical shape that is long in the direction of the roof ridge. One end of the chamber box 13d is connected to a ventilation gallery provided on the end wall of the building body 3, and the other end face is closed. Further, the plurality of ducts 13a are connected to the outer peripheral portion at predetermined intervals in the axial direction.
The duct 13b has one end connected to the chamber box 13d and the other end connected to the fan unit 13e. There are a plurality of fan units 13e, and a duct 13b is connected to each fan unit 13e.
One end of the duct 13c is connected to the fan unit 13e, and is introduced into the building through the floor and wall.
The heated air in the air circulation layer S is sucked from the air circulation layer S by the fan of the fan unit 13e, and circulates through the duct 13a, the chamber box 13d, the duct 13b, and the duct 13c.

Further, in the chamber box 13d, a first electric damper (not shown) that opens and closes a connecting portion between the chamber box 13d and the duct 13b, and a second electric damper (not shown) that opens and closes one end of the chamber box 13d, In the summer day, the first electric damper is closed and the second electric damper is opened so that the heated air in the air circulation layer S can be naturally exhausted from the ventilation gallery of the wife wall. It has become.
The first and second electric dampers are connected to a controller (not shown), and are connected to a temperature sensor (not shown) installed in the air circulation layer S near the transparent glass module 8a.
The first and second electric dampers are automatically opened and closed by the controller as the temperature of the air circulation layer S changes. For example, during the summer day, the first electric damper is closed and the second electric damper is opened, so that the heated air in the air circulation layer S is naturally exhausted from the ventilation gallery of the wife wall. In addition to opening the first electric damper and closing the second electric damper, nighttime cold air is taken into the air circulation layer S, and radiation cooling from the roof surface 42 and the surface of the solar cell module 8 also acts, and the duct 13a, The chamber box 13d, the duct 13b, and the duct 13c can be circulated and can be stored in the heat storage means 12, 35 described later.
Further, during the winter day, the first electric damper is opened and the second electric damper is closed, whereby the air heated in the air circulation layer S is circulated through the duct 13a, the chamber box 13d, the duct 13b, and the duct 13c. Heat storage means 12 and 35, which will be described later, can store heat and close the first electric damper and open the second electric damper at night in winter, thereby cooling the air in the air circulation layer S to the ventilation gallery of the wife wall. Can be exhausted naturally.

The building body 3 is a two-story building, and an intermediate floor 15 is provided at an intermediate position between the second floor (specific floor). The intermediate floor 15 is disposed above a part of the second floor 16, and the height from the second floor 16 is about 0.9 m to 1.4 m.
A storage space 17 is provided between the intermediate floor 15 and the second floor 16. The storage space 17 and the rooms 18a and 18b on the second floor are adjacent to each other, and the storage space 17 can be entered and exited from the rooms 18a and 18b.

A ceiling 20 is provided immediately below the intermediate floor 15, and the duct 13 c is connected to a ceiling space 21 between the ceiling 20 and the intermediate floor 15. That is, the duct 13 c penetrates the ceiling 22 on the second floor and further penetrates the intermediate floor 15 and the ceiling 20. A blow pipe 13f is connected to the duct 13c, and the blow pipe 13f is disposed in the ceiling back space 21 and is open to the ceiling back space.
Although there are a plurality of ducts 13c, only one duct is shown in FIG. As shown in FIG. 3, the duct 13c penetrates the room 27 on the intermediate floor 15, the intermediate floor 15, and the second floor 15 after passing through the ceiling 22 on the second floor. After penetrating the ceiling, the second floor 15 may be penetrated through the inner wall 28 of the second floor. In this case, the blowing pipe 13f may be connected to the ceiling space 21 through the floor material of the floor panel constituting the intermediate floor 15.

Heat storage means 12 is provided in the ceiling space 21. The heat storage means 12 is preferably a latent heat storage material that stores heat using latent heat, for example, in that the heat storage capacity can be made relatively large and the heat storage effect is enhanced. The latent heat storage material is a material that stores and releases heat by melting and solidifying latent heat of a simple substance, a eutectic mixture, or a freezing point depressing substance. Specifically, it is possible to effectively use a material in which a sodium sulfate decahydrate is filled in a polypropylene container or a material in which paraffin is sealed with a special resin-processed aluminum sheet. Such a heat storage means 12 is supported with a gap between it and the ceiling 20 by a support member provided above the ceiling 20. Therefore, an air flow passage 23 is provided between the heat storage means 12 and the ceiling 20.
As the support member, for example, a cross member is assembled vertically and horizontally in a horizontal plane, and this support member is fixed to a floor panel member constituting the intermediate floor 15. As for the floor panel, the frame is assembled into a rectangular frame, and reinforcing bars are assembled vertically and horizontally inside the rectangular frame to form a frame, and a face material made of plywood is attached to the upper surface of the frame It will be.

Further, a heat insulating material having a heat insulating effect higher than that of the ceiling 20 is provided on the back side of the ceiling 20. The heat insulating material 24 is formed in a plate shape with, for example, polystyrene foam, and the air flow passage 23 is provided between the heat insulating material 24 and the heat storage means 12.
Further, as shown in FIG. 3, an air outlet 25 is provided between the end of the intermediate floor 15 on the room 18a side and the end of the ceiling 20 on the room 18a side. As shown in FIG. 2, a blowout hole 26 penetrating vertically is provided.

The duct 13 c passes through the second floor 16, passes through the first floor room (for example, entrance hall) 29, passes through the first floor 30, and is connected to the lower floor 31.
The duct 13c is provided with an air outlet 13g. The air outlet 13g is open to the entrance hall 29, and warm air (heated air) is blown out from the air outlet 13g to the entrance hall 29.
Further, a branch duct 13h is connected to the duct 13c horizontally in the ceiling back space 16b between the second floor 16 and the ceiling 16a immediately below it, and is further bent downward to penetrate the ceiling 16a. The lower surface of the ceiling 16a is opened toward a first floor room (for example, a washroom) 32, and warm air is blown out to the room 32 from the front end opening of the branch duct 13h.
In FIG. 3, the branch duct 13h branched from the duct 13c is opened on the lower surface of the ceiling 16a. However, the present invention is not limited to this. For example, as shown in FIGS. The duct 13c may be opened directly on the lower surface of the ceiling 16a.

Further, a moisture-proof soil concrete 33 is placed on the ground G of the underfloor 31, and a heat insulating material 34 is provided on the side surface of the foundation 2 facing the underfloor 31 side.
On the surface of the moisture-proof soil concrete 33, heat storage means 35 is provided by laying river sand with a predetermined thickness, and a duct 13c is connected to the heat storage means 35. That is, the lower end portion of the duct 13c is branched and arranged substantially horizontally, and is embedded in the heat storage means 35. The outer periphery of the duct 13c embedded in the heat storage means 35 is axially disposed on the outer peripheral portion. Air outlets are formed at predetermined intervals. And warm air is blown out from this blower outlet, and the heat of the warm air is stored in the heat storage means 35. Therefore, the heat stored in the heat storage means 35 can be used for floor heating of the room of the first floor 30.
Moreover, if a blow hole is formed in the floor panel which comprises the 1st floor 30, the warm air can be blown out from this blow hole to the room on the 1st floor.

According to the present embodiment, sunlight can be converted into electricity (electric power) by the plurality of solar cell modules 8 arranged on the roof surface 42, and the electric power consumed in the building 1 can be covered.
Moreover, since the air circulation layer S is formed between the solar cell module 8 and the roof surface 42, and the heat transfer means 13 is connected to the air circulation layer S, solar heat passes through the solar cell module 8. Then, the air is heated by being transmitted to the air in the air circulation layer S, and the heated air is provided via the heat transfer means 13 and the intermediate floor 15 on the second floor of the building and immediately below it. It flows into the ceiling back space 21 between the ceiling 20 and the heat of the heated air is stored in the heat storage means 12 provided in the ceiling back space 21.
As a result, the heat stored in the heat storage means 12 can be used for floor heating of the room 27 on the intermediate floor, and the heat insulating material 24 having a higher heat insulating effect than the ceiling 20 is provided on the ceiling 20. Most of the heat released downward is insulated by the heat insulating material 24. Therefore, the heat stored in the heat storage means 12 can be efficiently used as the floor heating of the room 27 on the intermediate floor. Moreover, since the blowout hole 26 is formed in the intermediate floor 15, and warm air blows off from this blowout hole 26, it can utilize as the heating of the room 27 on an intermediate floor.

In addition, the ceiling 20 is heated by a part of the heat transmitted through the heat insulating material 24 and can be used for heating the storage space 17 below. That is, since the storage space 17 has a lower height from the floor surface (floor surface on the second floor) to the ceiling 20 than the living room, the storage space 17 can be warmed to some extent by the heated ceiling 20. The storage space 17 does not need to be heated as much as a living room in winter, but is maintained to a certain temperature by being heated to some extent, which is useful for maintenance of stored items. Further, by changing the performance of the heat insulating material 24, the ratio of the heat flowing upward and the heat flowing downward can be changed.
Further, the air heated in the air circulation layer S flows into the lower floor 31 of the first floor via the heat transfer means 13, and the heat of the heated air is stored in the heat storage means 35 provided in the lower floor 31. The As a result, the heat stored in the heat storage means 35 can be used for floor heating on the first floor.

Further, the room 18a on the second floor is adjacent to the storage space 17, and the air outlet 25 is provided between the end of the intermediate floor 15 on the room 18a side and the end of the ceiling 20 on the room 18a side. Therefore, the warm air warmed by the heat released from the heat storage means 12 is released from the outlet 25 and can be used for heating the room 18a on the second floor.
In addition, since the air flow passage 23 is formed between the heat storage means 12 and the ceiling 20, the warm air heated by the heat released downward from the heat storage means 12 passes through the air flow passage 23 and the back of the ceiling. Since it reaches the space 21, it can be effectively used as floor heating.
Furthermore, since the heat storage means 12 is a latent heat storage material, the heat storage capacity can be made relatively large, and since the heat storage temperature is stabilized, the heat storage effect can be enhanced.

Further, since the solar cell module 8 is provided on the roof surface 42 of the building 1 with the air circulation layer S interposed between the solar cell module 8 and the roof surface 42, the conventional method for forming the air circulation layer S is provided. A transparent member is not required.
Therefore, the air circulation layer S can be formed together with the installation of the solar cell module 8 only by the installation work of the solar cell module 8. Therefore, the construction is facilitated, and the translucent member is not required, so that the number of parts can be reduced accordingly.
Furthermore, since the heat transfer means 13 is connected to the air circulation layer S on the ridge side of the roof 4, the air heated in the air circulation layer S is directly transferred from the ridge side of the roof 4 to the heat transfer means 12. be able to. That is, since air with high temperature tends to rise to the ridge side of the roof 4, it is preferable to provide the heat transfer means 13 on the ridge side because the heat collection rate is higher than the case where it is provided on the eaves side.

Moreover, since the solar cell module 8 is supported by the support rail 10 provided on the roof surface 42, the solar cell module 8 is in a state where the air circulation layer S is interposed between the roof surface 42 and the roof surface 42. It can be installed easily and reliably.
Further, a plurality of support rails 10 extending from the eaves of the roof 4 toward the ridge are provided at predetermined intervals in the ridge direction, and the heat transfer means 13 is connected to the air circulation layer S on the ridge side of the roof. The air heated in the air circulation layer S flows smoothly along the extending direction of the support rail 10 and reaches the heat transfer means 13.

  In the present embodiment, the duct 13c of the heat transfer means 13 may also be connected to the ceiling space 16b between the second floor 16 and the ceiling 16a directly below it. In this case, a part of the plurality of ducts 13c may be connected to the ceiling back space 16b, and a heat insulating material having a higher heat insulating effect than the ceiling 16a may be provided on the ceiling 16a.

DESCRIPTION OF SYMBOLS 1 Building 4 Roof 8 See-through type photovoltaic power generation module 12 Heat storage means 13 Heat transfer means 15 Intermediate floor 16 Second floor (specific floor)
17 Storage space 18a Room (Room on specific floor)
20 Ceiling 21 Ceiling back space 23 Air flow passage 24 Heat insulating material 25 Air outlet 30 First floor 42 Roof surface S Air circulation layer

Claims (5)

On the roof surface of the building, the battery module is provided with an air circulation layer interposed between the roof surface and the roof surface,
Heat transfer means is connected to the air circulation layer,
The heat transfer means is connected to a ceiling space between a floor above the first floor of the building and a ceiling provided directly below the floor,
A heat storage means for storing heat is provided in the ceiling space,
A solar heat collecting system, wherein a heat insulating material having a higher heat insulating effect than the ceiling is provided on the ceiling. In the solar power generation heat collecting system of Claim 1,
The floor above the first floor is an intermediate floor at an intermediate position of a specific floor,
The space between this intermediate floor and the specific floor is a storage space,
The solar heat collecting system, wherein the heat storage means is provided in a ceiling space between the intermediate floor and a ceiling provided immediately below the intermediate floor. The solar power collection system according to claim 2,
The room on the specific floor is adjacent to the storage space,
A solar heat collecting system, wherein an air outlet is provided between an end of the intermediate floor on the room side and an end of the ceiling on the room side. In the solar power generation heat collecting system as described in any one of Claims 1-3,
An photovoltaic power collection system comprising an air flow path provided between the heat storage means and the ceiling. In the solar power generation heat collecting system as described in any one of Claims 1-4,
The solar heat collecting system, wherein the heat storage means is a latent heat storage material that stores heat using latent heat.

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