JP2010107118A - Solar heat panel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solar heat panel with an installation structure preventing deterioration of design performance, capable of eliminating a tank installation space on the ground and having excellent reliability. <P>SOLUTION: A first transparent body 412a, an inner wall 412b and a projecting member 412c are formed beforehand by integral molding by a transparent resin material. Thus, projecting walls 410e and bottom faces 410d of a base 411 can be formed to have a groove shape with a shallow depth. As a result, coating treatment to uniformly form a light absorption treatment layer with respect to the surfaces of the projecting walls 410e and bottom faces 410d can be easily performed, so as to drastically shorten work time required for the coating treatment. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a solar panel installed on a roof.

  Generally, a solar thermal panel absorbs sunlight as heat by a device called a collector, and uses the heat for hot water supply or heating. It is a device that uses natural energy in the same way as a solar cell, and should be promoted to prevent global warming.

  Many solar panels currently in practical use have separate collectors and tanks. A solar panel called “natural circulation type” has a tank installed above the collector. In a solar panel called “forced circulation type”, the collector and the tank are physically separated, the collector is installed on the roof, and the tank is installed on the ground. In addition, a “pumping type” solar panel that integrates a collector and tank has been proposed for a long time. Patent Document 1 (Japanese Utility Model Publication No. 62-130357) discloses a “pumping type” solar panel.

The “natural circulation type” solar panel has a problem in design (appearance) because the tank projects largely upward from the heat collector. “Forced circulation” solar panels are mounted on the roof only with a collector, so the problem of design has been solved, but the tank installation space has been moved to another location such as the ground. There is a problem that needs to be secured. In addition, the “pumping type” solar panel has a simple box shape, and the construction method on the roof has not been sufficiently studied.
Japanese Utility Model Publication No. 62-130357

  The problem to be solved by the present invention is that, in the conventional solar panel, a problem arises in the design property when the roof is installed, and the installation space for the tank must be secured separately when the tank is separated. There is a problem in the construction method when installing on the roof.

  Accordingly, an object of the present invention is to solve the above-mentioned problems, and it is possible to provide a solar panel having a highly reliable installation structure that can eliminate the need for a ground tank installation space without impairing the design. provide.

  The solar panel according to the present invention is a solar panel installed on a roof, and is provided so as to surround a solar panel body including a hot water storage tank that also serves as a collector, and a side surface of the solar panel body. A frame member and a support member fixed to the roof are provided, and the following configuration is provided.

  The frame member is supported by the support member, and the hot water storage tank is provided over substantially the entire surface of the solar panel body, and is provided so as to substantially fill the space up to the roof inside the solar panel body. .

  The hot water storage tank provided in the solar thermal panel body is composed of a transparent body and a tank body, and the transparent body covers a first transparent body that covers an opening on the upper surface side of the tank body, and a top surface of the first transparent body. A plurality of convex members arranged on the convex member, and a second transparent body placed on the convex member and arranged with a predetermined gap with respect to the first transparent body.

  The tank body has a plurality of inner walls and a base portion to form a conduit portion extending in a predetermined direction therein, and the plurality of inner walls and the first transparent body are integrally formed by resin molding. Has been.

  In the solar thermal panel, the plurality of inner walls, the first transparent body, and the plurality of convex members are integrally formed by resin molding.

  In the solar panel, the base portion includes a plurality of curved bottom surfaces extending along a direction in which the conduit portion extends, and a convex wall portion is provided with both sides of the bottom surface rising upward. The conduit portion is formed by the top portion of the wall portion and the lower end portion of the inner wall being brought together.

  In the solar thermal panel, the base portion has an inner wall on the base portion side that extends until it comes into contact with the first transparent body. Moreover, the said solar thermal panel WHEREIN: The said tank main body has carbon black. In the solar thermal panel, the tank body is subjected to black chrome plating using carbon black as a conductive material.

  According to the solar panel according to the present invention, since the hot water storage tank capable of holding hot water having the same capacity as the conventional one is housed in the space between the solar panel and the roof, the design property is not impaired, and the tank installation space on the ground Can be made unnecessary. In addition, since the support member is used for installation on the roof, it is possible to provide an installation method with excellent long-term reliability. In addition to these, it is possible to provide a low-cost solar panel that is excellent in workability and maintainability.

  Furthermore, since the first transparent body and the inner wall are formed by integral molding in advance with a transparent resin material, the shape on the base portion side can be made a simple shape with little unevenness. As a result, the coating process for forming the light absorption processing layer on the surface of the base part can be easily performed, and the working time required for the coating process can be greatly shortened.

  In particular, when a convex wall portion and a curved bottom surface are provided in the base portion, it can be formed into a groove shape with a shallow depth, and the light absorption processing layer can be uniformly applied to the surface of the convex wall portion and the bottom surface. The working time required for the coating process can be greatly reduced.

  Embodiments of the present invention will be described below. Note that the same or corresponding portions are denoted by the same reference numerals, and the description thereof may not be repeated.

  In the embodiments described below, when referring to the number, amount, and the like, the scope of the present invention is not necessarily limited to the number, amount, and the like unless otherwise specified. Further, in the following embodiments, when there are a plurality of embodiments, it is planned from the beginning to appropriately combine the configurations of the embodiments unless otherwise specified.

(Embodiment 1)
The structure of the solar panel 1 in Embodiment 1 based on this invention is demonstrated with reference to FIGS. FIG. 1 is a perspective view schematically showing the overall structure of the solar panel 1 according to the first embodiment, and FIG. 2 is a partial cross-sectional view showing the internal structure of the solar panel 1 according to the first embodiment. FIG. 3 is a plan view of the solar thermal panel 1, and FIG. 4 is a plan view showing the structure of the hot water storage tank 8.

(Solar thermal panel 1)
Referring to FIG. 1, solar panel 1 according to the present embodiment includes a solar panel body 100 that incorporates a hot water storage tank 108 that also serves as a heat collector, and a frame member 200 that is provided so as to surround a side surface of the solar panel body 100. And. In the present embodiment, the solar panel 1 includes a horizontal beam 25, a vertical beam 26, and an engaging member 210 as support members described later.

(Solar thermal panel body 100)
Referring to FIG. 2, solar panel body 100 includes hot water storage tank 108, and frame member 200 is disposed around hot water storage tank 108 with a heat insulating material 112 made of a cushioning material 105 using an elastomer and styrene foam. Is provided. The frame member 200 is made of an aluminum member whose surface is anodized (consisting of four members corresponding to each side of the panel, the size when assembled: 1165 mm × 990 mm × 46 mm). Yes.

  The hot water storage tank 108 includes a transparent body 109 and a tank body 110 integrated with a heat collector. The transparent body 109 includes a first transparent body 109a that covers the opening 110b on the upper surface side of the tank body 110, a plurality of convex members 109b that are arranged at predetermined positions on the first transparent body 109a, and an upper surface of the convex member 109b. And a second transparent body 109c disposed with a predetermined gap with respect to the first transparent body 109a.

  As an example of a resin material, polycarbonate is used for the first transparent body 109a, and tempered glass is used for the second transparent body 109c. In addition, a film 102 having a property of shielding ultraviolet rays is attached to the back side of the tempered glass. Thereby, suppression of the light deterioration of the structural member which consists of resin materials is enabled, and it can contribute to the improvement of long-term reliability.

  The convex member 109b has a trapezoidal cross-sectional shape and a height of about 5 mm. The first transparent body 109a and the convex member 109b may be formed as an integral molding made of the same member, or after forming each as a separate member, the convex member 109b may be fixed to the first transparent body 109a. Absent. As shown in FIG. 3, the convex members 109b are arranged so as to be parallel to each other at a predetermined interval. By interposing the convex member 109b between the first transparent body 109a and the second transparent body 109c, a heat insulating layer made of an air layer can be formed. The height of the convex member 109b determines the thickness of the air layer. From the viewpoint of heat insulation, about 5 mm is preferable as described above. Thereby, the heat insulation performance of the hot water storage tank 108 can be improved.

  Referring to FIG. 2 again, the tank body 110 is integrally formed of polycarbonate, which is the same resin material as the first transparent body 109a. Note that the strength of the tank main body 110 can be increased by using glass fiber reinforced plastic or carbon fiber reinforced plastic from the viewpoint of contribution to improvement of long-term reliability. In addition, 18 rows of conduit portions 115 that are partitioned by an inner wall 110c and store water serving as a heat medium are formed therein. One row of the conduit portions 115 has a width of about 50 mm and a depth of about 70 mm.

  As shown in FIG. 4, the pattern of the conduit 115 in plan view is a serpentine shape (meandering shape), and all 18 rows of the conduit portions 115 are connected in series. Note that this shape is an example, and an optimal quantity / shape is appropriately selected for the conduit portion 115. Joint outlet pipes 120 having a diameter of about 7 mm were provided on the left and right side surfaces of the tank body 110. A 0-ring 121 is attached to the middle of the joint outlet pipe 120.

  Since the tank body 110 and the first transparent body 109a are molded from the same resin material, the coefficient of thermal expansion is the same. This can contribute to improvement of reliability.

  The surface of the tank body 110 is black chrome plated as a light selective absorption material (see the light absorption treatment layer 115m shown in FIG. 14). More specifically, first, a coating material containing carbon black is coated on the surface of the heat collecting part (inner wall 110c and curved bottom surface 110d) of the tank body 110, and the coating material is dried by heating, and at the same time, the carbon black is fixed to the resin. After that, black chrome plating was performed using carbon black as a conductive material. The tank body 110 in the present embodiment constitutes a heat collector by the entire surface.

  Thus, by containing carbon black in the tank main body 110, it is possible to prevent deterioration of the tank main body 110 due to ultraviolet rays while promoting absorption of sunlight from its light absorption characteristics. In addition, carbon black contained in the heat collecting part of the tank body 110 is subjected to black chrome plating as a conductive material, so that it absorbs visible light from sunlight well due to the light selective absorption characteristics of the material itself. Infrared radiation from can be suppressed, and the efficiency as a heat collecting part can be improved.

  As shown in FIGS. 3 and 4, 16 bolt holes 116 and 117 each having a diameter of about 3 mm through which the bolt screw 113 is passed are provided on the entire outer periphery of the tank body 110 and the first transparent body 109a. .

  Referring to FIG. 2 again, the first transparent body 109a is fixed to the tank main body 110 using a bolt screw 113 and a nut 114. Further, a groove 132 is provided on the surface of the tank body 110 on the inner peripheral side of the bolt holes 116 and 117, and a ring-shaped sealing material 111 is accommodated in the groove 132.

  A frame member 200 is provided around the hot water storage tank 108 with a cushioning material 105 using an elastomer and a heat insulating material 112 made of foamed polystyrene or the like interposed therebetween. The frame member 200 is composed of four members, surrounds the hot water storage tank 108 from four sides, and is fixed with screws (not shown), whereby the solar panel 1 is completed.

  The hot water storage tank 108 is provided over almost the entire surface of the solar panel body 100 and is provided so as to substantially fill the space up to the roof 28 in the solar panel body 100. It is provided so as to be located closer to the roof 28 than the lower end 201 of the frame member 200.

  That is, the lower end surface 110 a of the hot water storage tank 108 protrudes from the lower end portion 201 of the frame member 200 to the roof 28 side. This is because the tank capacity necessary as a water heater is secured in the space between the solar panel 1 and the roof 28 while keeping the thickness of the solar panel 1 thin.

The conventional solar panel generally holds a tank having a capacity of about 200 L, and the area of the heat collector is an average of 4 m ² , which is 50 L / m ² between the solar panel 1 and the roof 28. If this space can be secured, this means that a tank having the required volume can be held inside the solar panel. Therefore, in the solar thermal panel 1 in the present embodiment, as described above, 18 rows of the conduit portions 115 are formed, and the width of the one row of the conduit portions 115 is about 50 mm and the depth is about 70 mm. A space of 50 L / m ² is secured.

(Fixing the solar panel 1 to the roof 28)
Next, fixation of the solar panel 1 having the above configuration to the roof 28 will be described with reference to FIGS. 5 is a diagram showing the arrangement of the support members provided on the roof 28, and FIG. 6 is an exploded perspective view schematically showing a state when the solar panel 1 is placed on the roof 28. FIG. FIG. 8 is a transverse sectional view of the solar thermal panel 1 placed on the roof 28, and FIG. 8 is a longitudinal sectional view of the solar thermal panel 1 placed on the roof 28. FIGS. 9 to 11 are views showing the first to third steps when the solar panel 1 is fixed to the support member, and FIG. 12 is a view showing the structure of the water conduit member 23.

  With reference to FIG. 5 and FIG. 6, as the support member provided on the roof 28, the vertical beam 26 arranged at a predetermined pitch in the vertical direction and the horizontal direction, and the vertical beam 26 fixed on the vertical beam 26, in the horizontal direction It has a horizontal rail 25 that extends. Usually, the solar panel 1 is arranged so that the vertical rail 26 is arranged at the center of the solar panel 1. At both ends of the horizontal rail 25, vertical rails 26 are provided in order to avoid cantilever support of the horizontal rail 25.

  First, the vertical beam 26 is screwed to the roof 28, and then the horizontal beam 25 is fixed on the vertical beam 26 with a fixing bracket or a screw. Further, on the upper surface of the horizontal rail 25, an engaging member 210 having a hook-like engaging claw 211 at the tip for engaging with an engaging region portion 202 provided on the frame member 200 of the solar panel 1 stands. (See FIG. 8).

  As shown in FIG. 7, a support panel 29 is provided between the lower end surface 110 a of the hot water storage tank 108 of the solar panel 1 and the roof 28, and the support panel 29 is placed on the roof 28. A hot water storage tank 108 is placed on the top. The support panel 29 preferably has a heat insulating performance, and for example, a foam heat insulating material or a vacuum heat insulating material is used.

  Examples of the foam insulation material include foamable resins, and more specifically, polystyrene foam and urethane foam are preferable. As the vacuum heat insulating material, a glass fiber vacuum-sealed is generally preferable. Further, by using a deformable material for the support panel 29, it is possible to fill a gap between the unevenness on the surface of the roof 28 and the lower end surface 110 a of the hot water storage tank 108.

  Thus, by providing the support panel 29, it becomes possible to receive the load of the solar panel 1 and the water introduced therein by the roof 28 via the support panel 29. If the support panel 29 is not provided, the load of the solar panel 1 is applied to a part of the roof 28 via the frame member 200, the horizontal beam 25, and the vertical beam 26, but the load is increased by adding the support panel 29. It can be distributed over a wider roof 28.

  At the same time, if the support panel 29 completely closes the space between the hot water storage tank 108 and the roof 28, the air flow can be cut off and the heat radiation from the bottom surface of the hot water storage tank 108 can be reduced. . Further, by using a foamable resin or a vacuum heat insulating material for the support panel 29, it is possible to reduce heat radiation due to heat conduction from the bottom surface of the hot water storage tank 108 through the support panel 29.

  In the region where the horizontal rail 25 and the vertical rail 26 are located on the lower end surface 110a of the hot water storage tank 108, the hot water storage tank 108 is provided so as to substantially fill the space up to the roof 28 inside the solar panel body 100. Since it is necessary, the lower end surface 110a of the hot water storage tank 108 is provided with a recessed region 110e (see FIG. 7) and a recessed region 110f (see FIG. 8).

  The recessed areas 110e and 110f are provided to prevent physical interference between the hot water storage tank 108, the horizontal rail 25, and the vertical rail 26. Therefore, it is preferable that the depth of the hollow regions 110e and 110f viewed from the bottom surface of the hot water storage tank 108 is as shallow as possible as long as the depth does not interfere with the horizontal rail 25 and the vertical rail 26.

  In addition, when the surface of the roof 28 is substantially flat, and the heat insulation of the lower end surface 110a of the hot water storage tank 108 is not a problem, the lower end surface 110a of the hot water storage tank 108 is not attached to the roof 28 without the support panel 29 interposed. It is also possible to adopt a configuration that directly contacts.

  As shown in FIG. 8, the engagement panel 211 provided at the tip of the engagement member 210 engages with the engagement region portion 202 provided in the frame member 200, so that the solar panel 1 is It will be fixed to 210. In FIG. 8, the engagement state at the lower end portion of the solar panel 1 is illustrated, but the engagement claw 211 is similarly provided at the upper end portion of the solar panel 1. Engage with part 202.

(Construction procedure of solar panel 1)
With reference to FIG. 9 to FIG. 11, the solar panel 1 is constructed from the lower side, and the state shown in FIG. 9 indicates a state in which the construction of the lower stage (for example, the third stage) solar panel 1 has already been completed. . 9 to 11, the left side is the lower side and the right side is the upper side.

  Next, as shown in FIG. 10, the engaging claw 211 provided at the tip of the engaging member 210 is attached to the frame member 200 with the lower end of the upper solar panel 1 (for example, the fourth step) inclined. The upper end side of the solar panel 1 is gradually pushed down to the roof 28 side while being engaged with the provided engagement region portion 202. Thereby, the engagement area part 202 provided in the frame member 200 on the upper end side of the solar panel 1 can be engaged with the engagement claw 211 provided at the tip of the engagement member 210. FIG. 11 shows a state in which the construction of the upper solar panel 1 has been completed.

  Note that the hot water storage tanks 108 are connected to each other by using a joint lead-out pipe 120 provided in the hot water storage tank 108 to connect the water conduit pipe member 23 having physical flexibility. As shown in FIG. 12, the water conduit member 23 has a water conduit 22 and attachments 21 fixed to both ends thereof.

  The attachment 21 is made of resin, and the water conduit 22 is made of resin including a metal mesh. The length of the water conduit 22 can be freely set by the distance between the solar thermal panels 1 to be connected. For the connection between the attachment 21 and the joint outlet pipe 120 provided in the hot water storage tank 108, a fitting type attachment mechanism that can be attached and detached without using a tool or the like is employed.

  In this way, the solar heat panels 1 are defined by using the water guide pipe member 23 for connecting the solar heat panels 1 and using the flexible and freely bendable material for the water guide pipe 22. Even in a state that is not in a positional relationship, it is possible to connect without any problem, and it is possible to improve the workability. Moreover, since it becomes possible to connect not only the adjacent solar thermal panel 1 but the solar thermal panels 1 installed in the physically distant place by using the water conduit 22 of various length, it is narrow. The workability to the roof can also be improved.

  Moreover, by using the water guide pipe member 23 that can be attached and detached without using a tool to connect the solar panels 1 to each other, the attachment and detachment becomes very simple, and the workability and maintainability can be simplified. As an additional effect, since the water conduit using the attachment method has already been mass-produced, it can be easily obtained as an inexpensive member, and the total cost of the solar panel can be reduced. Become.

  Here, as an example, a procedure for constructing five solar thermal panels 1 in the lateral direction will be described. First, the first solar panel 1 is stood against the right end of the crosspiece 25, and one attachment 21 of the first water guide pipe member 23 is attached to the joint outlet pipe 120 on the right side of the solar panel 1, and the other attachment 21 is in the upper stage. It was pulled out above the horizontal rail 25.

  One attachment 21 of the second water conduit member 23 was attached to the left joint lead-out tube 120 of the first solar panel 1, and the other attachment 21 was pulled out to the left side of the first solar panel 1. Thereafter, the first solar panel 1 is fixed using the engaging member 210 as described above.

  Next, the second solar panel 1 is stood on the left side of the first solar panel 1, and the attachment 21 of the water conduit member 23 drawn from the left side of the first solar panel 1 is attached to the second solar panel. And attached to the right joint outlet tube 120.

  Further, the third water guide pipe member 23 was attached to the joint outlet pipe 120 on the left side of the second solar panel 1. Similarly, the third, fourth, and fifth solar panels 1 were sequentially fixed, and five solar panels 1 were fixed between the horizontal rails 25 along the horizontal direction. Since the water conduit members 23 are drawn out from the side surfaces of the first solar panel 1 and the fifth solar panel 1, they are connected to the water supply pipe 60 from the water supply and the pipe 61 to the auxiliary heating device, respectively. To do.

  Thus, since the solar panel 1 is directly connected to the water supply pipe 60 from the water supply, water is introduced into the hot water storage tank 108 using only the pressure of the water supply and moved, so that a pump is unnecessary. It is possible to reduce initial costs and running costs. In addition, in this Embodiment, although the solar thermal panel 1 has disclosed the case where it is directly connected with the water supply piping 60 from a water supply, you may install a pressure-reduction valve between a water supply and the solar thermal panel 1. FIG. .

  FIG. 13 shows a construction example for a building where a plurality of roofs 28a and 28b exist. The case where the area of each roof 28a, 28b is small and a sufficient number of solar panels 1 cannot be loaded on one roof is shown. In this case, the solar panel 1 is fixed to the roof 28a and the roof 28b by the above-described construction method, respectively, and the joint part 210 on the right side of the solar panel group A composed of the three solar panels 1 constructed on the roof 28a; The joint portion 210 on the left side of the solar thermal panel group B composed of the two solar thermal panels 1 constructed on the roof 28b is connected by using the water conduit member 23 in which the length of the water conduit 22 is sufficiently long. is doing. A water supply pipe 60 from the water supply is connected to the solar thermal panel group A, and a pipe 61 to the auxiliary heating device is connected to the solar thermal panel group B.

  In addition, since the horizontal rail 25 located in the lowest stage is not covered with the solar panel body 100 and is exposed as it is, the decorative cover 400 is provided on the horizontal rail 25 in order to improve the design. The joint member 210 is used for fixing.

  As mentioned above, according to the solar thermal panel 1 in this Embodiment, since the hot water storage tank 108 which can hold | maintain the hot water of the capacity | capacitance equivalent to the past was stored in the space between the solar thermal panel 1 and the roof 28, designability is not impaired. This eliminates the need for ground tank installation space. Further, since the support panel 29 is used for installation on the roof 28, it is possible to receive the load of the solar thermal panel 1 and water introduced therein by the roof 28 via the support panel 29.

  At the same time, the support panel 29 closes the space between the hot water storage tank 108 and the roof 28, so that the air flow can be blocked and the heat radiation from the bottom surface of the hot water storage tank 108 can be reduced. As a result, it is possible to provide an installation method with excellent long-term reliability. In addition to these, it is possible to provide a low-cost solar panel that is excellent in workability and maintainability.

(Embodiment 2)
Next, the structure of the solar thermal panel in Embodiment 2 based on this invention is demonstrated with reference to FIGS. FIG. 14 is a diagram showing a cross-sectional structure of the solar panel body 100 employed in the solar panel 1 shown in the first embodiment, and FIG. 15 shows the solar panel employed in the solar panel in the present embodiment. FIG. 16 is a partial exploded view showing the cross-sectional structure of the solar panel main body 400 employed in the solar panel according to the present embodiment, and FIG. 17 shows the present embodiment. It is a figure which shows the cross-section of the solar thermal panel main body 400A of the other form employ | adopted as the solar thermal panel.

  In the solar thermal panel main body 100 employed in Embodiment 1 shown in FIG. 14, the tank main body 110 is integrally formed of polycarbonate, which is a resin material, and the cross section of the conduit portion 115 has a U shape. Further, in order to increase the efficiency as a heat collector, a light absorption treatment layer 115m coated with black chrome plating as a light selective absorption material is formed on the surface of the conduit portion 115 of the tank body 110.

  However, since the cross section of the conduit portion 115 is U-shaped, the upper opening is narrow with respect to the depth, so that the light absorption treatment layer 115m is uniformly formed on the surface of the conduit portion 115. Therefore, the coating process is complicated, and there is a concern that a long working time is required.

  Therefore, the solar panel body 400 employed in the solar panel according to the present embodiment has a first transparent body that separates the inner wall used for partitioning the conduit portion inside the tank body from the tank body to form a transparent body. An inner wall is provided on the body. Hereinafter, the structure of solar panel body 400 in the present embodiment will be described with reference to FIG. 15 and FIG. 16. Note that the same reference numerals are used for the same or corresponding parts as in solar panel body 100 in the first embodiment. A duplicate description may not be repeated. Moreover, the external appearance as a solar thermal panel has the same external appearance as Embodiment 1.

(Solar thermal panel body 400)
Referring to FIGS. 15 and 16, solar panel main body 400 in the present embodiment has a solar heat panel main body 400 having hot water storage tank 408, and surroundings of hot water storage tank 408 are cushioning material 105 using an elastomer and polystyrene foam. A frame member 200 is provided with a heat insulating material 112 made of, for example, interposed. The frame member 200 is made of an aluminum member whose surface is anodized (consisting of four members corresponding to each side of the panel, the size when assembled: 1165 mm × 990 mm × 46 mm). Yes.

  The hot water storage tank 408 includes a transparent body 409 and a tank body 410 integrated with a heat collector. The transparent body 409 includes a first transparent body 412a that covers the opening 410b on the upper surface side of the tank body 410, a plurality of convex members 412c that are arranged at predetermined positions on the first transparent body 412a, and an upper surface of the convex member 412c. And a second transparent body 409c disposed with a predetermined gap with respect to the first transparent body 410b.

  For the first transparent body 412a, polycarbonate is used as an example of a resin material, and tempered glass is used for the second transparent body 409c. A film 402 having a property of shielding ultraviolet rays is attached to the back side of the tempered glass. Thereby, suppression of the light deterioration of the structural member which consists of resin materials is enabled, and it can contribute to the improvement of long-term reliability.

  An inner wall 412b for forming a conduit portion 415 is provided on the lower surface of the first transparent body 412a together with a curved bottom surface 410d provided on a base portion 411 constituting the tank body 410. The bottom surface 410d has a curved surface that extends along the direction in which the conduit portion 415 extends, and convex wall portions 410e that rise upward are provided on both sides of the curved surface. The top part of the convex wall part 410e and the lower end part of the inner wall 412b are brought together to form a conduit part 415.

  The base portion 411 of the tank body 410 is integrally formed of polycarbonate, which is the same resin material as the first transparent body 412a. Note that the strength of the base portion 411 can be increased by using glass fiber reinforced plastic or carbon fiber reinforced plastic from the viewpoint of contribution to improvement of long-term reliability. The base portion 411 has a bottom surface 410d for forming 18 rows of conduit portions 415. One row of the conduit portions 415 has a width of about 50 mm and a depth of about 70 mm.

  On the surface of the bottom surface 410d of the base portion 411, a light absorption processing layer 410m coated with black chrome plating as a light selective absorption material is formed in order to increase the efficiency as a heat collector. More specifically, first, a coating material containing carbon black is coated on the surface of the heat collecting portion (the convex wall portion 410e and the curved bottom surface 410d) of the base portion 411. After being fixed to, black chrome plating was performed using carbon black as a conductive material. Base portion 411 in the present embodiment constitutes a heat collector by the entire surface thereof.

  Thus, by including carbon black in the base portion 411, it is possible to prevent deterioration of the base portion 411 due to ultraviolet rays while promoting the absorption of sunlight from its light absorption characteristics. In addition, the carbon black contained in the heat collecting part of the base part 411 is plated with black chrome as a conductive material, so that it absorbs visible light from sunlight from the light selective absorption characteristics of the material, Infrared radiation from can be suppressed, and the efficiency as a heat collecting part can be improved.

  Further, since the convex wall portion 410e and the bottom surface 410d of the base portion 411 have a groove shape with a shallow depth, the light absorption processing layer 410m is uniformly formed on the surfaces of the convex wall portion 410e and the bottom surface 410d. Therefore, the coating process is easy and the working time required for the coating process can be greatly reduced.

  The total surface area of the light absorption treatment layer coated on the inner wall of the tank body is smaller than that in the first embodiment, but the light incident on the tank body is reflected by the convex wall 410e and the curved surface due to reflection or the like. Since it reaches the bottom surface 410d, the heat collecting ability of light does not decrease when viewed as a whole tank.

  In the present embodiment, as shown in FIG. 16, the first transparent body 412a, the inner wall 412b, and the convex wall portion 410e are formed in advance by integral molding with a transparent resin material. An example of the resin material is polycarbonate.

  The convex member 412c has a trapezoidal cross-sectional shape and a height of about 5 mm. Similar to the case shown in FIG. 3, the convex members 412c are arranged so as to be parallel to each other at a predetermined interval. By interposing the convex member 412c between the first transparent body 412a and the second transparent body 409c, a heat insulating layer made of an air layer can be formed. The height of the convex member 412c determines the thickness of the air layer. From the viewpoint of heat insulation, about 5 mm is preferable as described above. Thereby, the heat insulation performance of the hot water storage tank 408 can be improved.

  In addition, when the structure of the 1st transparent body 412a is compared with the structure of the 1st transparent body 109a employ | adopted in Embodiment 1, the structure becomes a complicated shape, but the 1st transparent body 412a is formed by injection molding. Since the first transparent body 412a, the inner wall 412b, and the convex member 412c are integrally molded, the manufacturing cost does not increase. Moreover, it is also possible to adopt a configuration in which the first transparent body 412a and the inner wall 412b are integrally molded and the convex member 412c is molded with another member.

  As in the case shown in FIG. 4, the pattern in the plan view of the conduit portion 415 has a serpentine shape, and all the 18 rows of the conduit portions 415 are connected in series. Note that this shape is an example, and an optimal quantity / shape is appropriately selected for the conduit portion 415. A joint outlet tube 120 having a diameter of about 7 mm was provided on the left and right side surfaces of the base portion 411. A 0-ring 121 is attached to the middle of the joint outlet pipe 120.

  The base part 411, the first transparent body 412a, the inner wall 412b, and the convex wall part 410e are molded with the same resin material, so that the thermal expansion coefficient of the material is the same, so that the long-term temperature Stress between members is less likely to occur with respect to the cycle, and this can contribute to improvement of long-term reliability.

  In addition, the structure as another solar thermal panel is the same as the structure of the solar thermal panel in Embodiment 1 mentioned above.

  As mentioned above, according to the solar thermal panel in this Embodiment, the hot water storage tank 408 which can hold | maintain the hot water of a capacity | capacitance equivalent to the past is provided in the space between a solar thermal panel and a roof similarly to the solar thermal panel in Embodiment 1 mentioned above. It can be accommodated, the design property is not impaired, and the ground tank installation space can be made unnecessary. Further, since the support panel is used for installation on the roof, it is possible to receive the load of the solar thermal panel and the water introduced therein by the roof via the support panel.

  At the same time, the support panel closes the space between the hot water storage tank 408 and the roof, so that the air flow can be blocked, and heat radiation from the bottom surface of the hot water storage tank 408 can be reduced. As a result, it is possible to provide an installation method with excellent long-term reliability. In addition to these, it is possible to provide a low-cost solar panel that is excellent in workability and maintainability.

  Furthermore, the 1st transparent body 412a, the inner wall 412b, and the convex member 412c are previously formed by integral molding with the transparent resin material. Thereby, the convex wall part 410e and the bottom face 410d of the base part 411 can be formed into a groove shape with a shallow depth. As a result, the coating process for uniformly forming the light absorption processing layer 410m on the surfaces of the convex wall 410e and the bottom surface 410d can be easily performed, and the working time required for the coating process is greatly reduced. be able to.

  In order to further improve the strength of the tank body 410, as shown in FIG. 17, the base portion side inner wall 410f formed integrally with the base portion 411 is partially formed in the same manner as in the first embodiment. It is also possible to use the solar thermal panel body 400A used. In this case, by adjusting the position where the base portion side inner wall 410f is provided to the position where the convex member 412c is provided, the external force applied to the convex member 412c can be released to the base portion 411 through the base portion side inner wall 410f. As shown in FIGS. 15 and 16, when the first transparent body 412a and the inner wall 412b are integrally formed, the thickness of the inner wall 412b facing the position where the convex member 412c is provided is set to the other inner wall. It is also possible to employ a configuration in which the thickness is greater than the thickness of 412b.

  Although the embodiments of the present invention have been described above, the embodiments disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

It is a perspective view which shows the outline of the whole structure of the solar thermal panel in Embodiment 1. FIG. FIG. 3 is a partial cross-sectional view showing the internal structure of the solar thermal panel in the first embodiment. 3 is a plan view of the solar thermal panel in the first embodiment. FIG. 3 is a plan view showing a structure of a hot water storage tank in Embodiment 1. FIG. FIG. 3 is a diagram showing an arrangement of support members provided on a roof in the first embodiment. It is the disassembled perspective view which showed typically the state at the time of mounting the solar thermal panel in Embodiment 1 on a roof. It is a cross-sectional view in the state which mounted the solar thermal panel in Embodiment 1 on the roof. It is a longitudinal cross-sectional view in the state which mounted the solar thermal panel in Embodiment 1 on the roof. It is a figure which shows the 1st step which shows the state which fixes the solar thermal panel in Embodiment 1 to a supporting member. It is a figure which shows the 2nd step which shows the state which fixes the solar thermal panel in Embodiment 1 to a supporting member. It is a figure which shows the 3rd step which shows the state which fixes the solar thermal panel in Embodiment 1 to a supporting member. It is a figure which shows the structure of the conduit pipe member in Embodiment 1. FIG. It is a figure which shows the construction example to the building in which the some roof in Embodiment 1 exists. It is a figure which shows the cross-section of the solar thermal panel main body employ | adopted as the solar thermal panel shown in Embodiment 1. FIG. It is a figure which shows the cross-section of the solar thermal panel main body employ | adopted as the solar thermal panel in Embodiment 2. FIG. It is a partial exploded view which shows the cross-sectional structure of the solar thermal panel main body employ | adopted as the solar thermal panel in Embodiment 2. FIG. It is a figure which shows the cross-section of the solar panel body of another form employ | adopted as the solar panel in Embodiment 2. FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Solar thermal panel, 21 Attachment, 22 Water conduit, 23 Water conduit member, 25 Horizontal cross, 26 Vertical cross, 29 Support panel, 60 Water supply piping, 61 Piping, 100, 400, 400A Solar thermal panel main body, 102, 402 Film, 105 , 305 Buffer material, 108, 408 Hot water storage tank, 109, 409 Transparent body, 109a, 412a First transparent body, 109b, 412c Convex member, 109c, 409c Second transparent body, 110, 410 Tank body, 110a Lower end surface, 110b , 410b opening, 110c, 412b inner wall, 110d, 410d bottom surface, 110e, 110f hollow region, 111 sealing material, 112 heat insulating material, 113 bolt screw, 114 nut, 115, 415 conduit portion, 115m, 410m light absorption processing layer, 116 117 bolts , 120 joint outlet tube, 120 ring, 132 groove, 200 frame member, 201 lower end portion, 202 engagement region portion, 210 engagement member, 211 engagement claw, 410e convex wall portion, 410f inner wall, 411 base side inner wall.

Claims (6)

A solar panel installed on the roof,
A solar panel body with a built-in hot water storage tank that also serves as a heat collector;
A frame member provided so as to surround a side surface of the solar panel body;
A support member fixed to the roof,
The frame member is supported by the support member,
The hot water storage tank is provided over substantially the entire surface of the solar panel body, and is provided so as to substantially fill the space up to the roof inside the solar panel body.
The hot water storage tank provided in the solar thermal panel body is composed of a transparent body and a tank body,
The transparent body is placed on the convex member, a first transparent body that covers the opening on the upper surface side of the tank body, a plurality of convex members disposed on the first transparent body, A second transparent body disposed with a predetermined gap with respect to the first transparent body,
The tank body has a plurality of inner walls and a base portion in order to form a conduit portion extending in a predetermined direction therein.
The plurality of inner walls and the first transparent body are solar panels that are integrally formed by resin molding.   The solar panel according to claim 1, wherein the plurality of inner walls, the first transparent body, and the plurality of convex members are integrally formed by resin molding. The base portion has a plurality of curved bottom surfaces extending along the direction in which the conduit portion extends, and a convex wall portion is provided on which both sides of the bottom surface rise upward.
The solar panel according to claim 1 or 2, wherein the conduit portion is formed by joining a top portion of the convex wall portion and a lower end portion of the inner wall.   4. The solar panel according to claim 1, wherein the base portion has a base portion side inner wall that extends until it comes into contact with the first transparent body.   The solar thermal panel according to any one of claims 1 to 4, wherein the tank body has carbon black.   The solar tank according to claim 5, wherein the tank body is black chrome plated using carbon black as a conductive material.

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