JP2020143889A - Installation structure of solar heat utilization system - Google Patents

Abstract

To provide an installation structure of a solar heat utilization system capable of being easily installed even after construction of a house.SOLUTION: A solar heat utilization system 10 has a heat exchange unit 28 disposed outdoors. The heat exchange unit 28 stores a heat transfer medium inside, and is disposed in a flow channel of a water supply passage 46 and an underfloor circulation passage 54. Heat is exchanged between: the heat transfer medium stored in the heat exchange unit 28; and cold water and the heat transfer medium flowing in the water supply passage 46 and the underfloor circulation passage 54. Both end portions of a heat collection pipe 26 are connected to the heat exchange unit 28. The heat transfer medium stored in the heat exchange unit 28 can be circulated in the heat collection pipe 26. The heat collection pipe 26 has a heat collection portion 36 mounted on a rafter 24 of an attic space 20. Thus, heat can be collected from the air in the attic space by the heat transfer medium circulated in the heat collection portion 36.SELECTED DRAWING: Figure 1

Description

The present invention relates to an installation structure of a solar heat utilization system.

Patent Document 1 discloses a solar heat-utilizing house in which a solar water heater is installed in the attic space of the house. This solar-powered house heats the stored water by collecting heat from sunlight through the roof and exchanging heat with the stored water inside the solar water heater arranged in the attic. Then, the warmed stored water is supplied to the house through a water pipe and used for a water heater and a floor heating system.

Japanese Unexamined Patent Publication No. 2014-047529

However, in the above prior art, a solar water heater, which is a large-scale facility including a heat exchange unit, is arranged in the attic space. For this reason, when installing a solar heat utilization system after building a house, it is necessary to provide a large opening that communicates with the attic space, which requires a large amount of construction work and is not easy to install. Therefore, there is room for improvement in this respect.

In consideration of the above facts, an object of the present invention is to obtain an installation structure of a solar heat utilization system that can be easily installed even after the construction of a house.

The installation structure of the solar heat utilization system according to the first aspect is provided in the flow path of the fluid supplied indoors of the house, and is installed outdoors and heat exchanges between the heat medium stored inside and the fluid. It has a heat exchange unit in the shape of a tube or a pipe, and has a heat collecting part. It is attached to a roof structure material to collect heat from the air in the roof space, and both ends are connected to the heat exchange unit. A heat collecting pipe through which the heat medium circulates is provided.

In the installation structure of the solar heat utilization system according to the first aspect, the heat collecting portion is attached to the attic structural material of the attic space, while the heat exchange unit is installed outdoors. In this solar heat utilization system, the air in the attic space heated by the solar heat is transferred to the heat medium flowing inside through the heat collecting part. The heated heat medium circulates inside the heat collecting pipe and returns to the inside of the heat exchange unit installed outside the house. As a result, solar heat is collected in the heat exchange unit through the heat medium. Further, in the heat exchange unit, heat exchange is performed between the heated heat medium and the fluid supplied to the interior of the house to warm the fluid. As described above, a part of the heat collecting pipe (heat collecting portion) is arranged in the attic space, and the heat exchange unit is installed outdoors, so that the work of installing a large-scale facility in the attic space becomes unnecessary. As a result, when a solar heat utilization system is installed after construction due to home remodeling or the like, the construction work does not become large.

In the installation structure of the solar heat utilization system according to the second aspect, in the configuration described in the first aspect, the heat collecting portion is attached to two or more rafters supporting the roofing material, respectively.

In the installation structure of the solar heat utilization system according to the second aspect, the heat collecting portion of the heat collecting pipe is attached to two or more rafters arranged in the attic space, respectively. Therefore, a sufficient length of the heat collecting portion can be secured, and the amount of heat supplied from the attic space increases.

The installation structure of the solar heat utilization system according to the third aspect is the configuration described in the first aspect or the second aspect, in which the heat collecting portion is formed by winding an intermediate portion of the heat collecting pipe in a loop shape. It is configured to have a plurality of annular portions.

In the installation structure of the solar heat utilization system according to the third aspect, the surface area of the heat collecting portion is increased by forming a plurality of annular portions in the heat collecting portion. As a result, the heat absorption efficiency by the heat collecting unit is improved, and by extension, the utilization efficiency of solar heat energy is improved.

As described above, the installation structure of the solar heat utilization system according to the first aspect has an excellent effect that the solar heat utilization system can be easily installed even after the construction of a house.

The installation structure of the solar heat utilization system according to the second aspect has an excellent effect that the amount of heat collected from the attic space can be increased.

The installation structure of the solar heat utilization system according to the third aspect has an excellent effect that the heat absorption efficiency by the heat collecting portion can be improved and the utilization efficiency of solar heat energy can be improved.

It is an overall view which shows roughly the installation structure of the solar heat utilization system which concerns on this embodiment. It is an enlarged perspective view which shows the heat collecting part of the heat collecting pipe shown in FIG. 1 in an enlarged manner. It is a block diagram of the solar heat utilization system which concerns on this embodiment.

Hereinafter, the installation structure of the solar heat utilization system 10 according to the present embodiment will be described with reference to FIGS. 1 to 3. First, FIG. 1 shows a schematic cross-sectional view of a house 12 to which the solar heat utilization system 10 is applied. Further, FIG. 3 shows a block diagram of the solar heat utilization system 10.

First, the outline of the house 12 to which the solar heat utilization system 10 is applied will be described with reference to FIGS. 1 and 2.

(Housing)
As shown in FIG. 1, the house 12 has a roof portion 14 having a gable roof and a ceiling portion 18 arranged on the lower side of the roof portion 14 and forming a ceiling surface of the living room space 16. .. Further, an attic space 20 is formed in the space between the roof portion 14 and the ceiling portion 18.

Inside the attic space 20, a ridge 22 as an attic structural material and a plurality of rafters 24 are arranged. The purlins 22 and rafters 24 form part of the roof portion 14.

As shown in FIG. 2, the purlin 22 is a horizontal member arranged at the top of the roof portion 14 and arranged with the girder direction of the house 12 as the longitudinal direction. One end of the plurality of rafters 24 in the longitudinal direction is fixed to the purlin 22. The plurality of rafters 24 are beam members arranged in a direction substantially orthogonal to the longitudinal direction of the ridge 22 in a plan view, and are diagonally laid from the ridge 22 toward the eaves girder (not shown) of the house 12. At the same time, they are arranged substantially in parallel along the longitudinal direction of the purlin 22.

Next, the outline of the solar heat utilization system 10 will be described with reference to FIGS. 1 and 3.

(Solar heat utilization system)
The solar heat utilization system 10 includes a heat collecting pipe 26 for collecting hot air in the attic space 20 heated by solar heat, and a heat exchange unit 28 for storing the heat collected by the heat collecting pipe 26.

As shown in FIG. 1, the heat collecting pipe 26 is formed in a tubular shape or a pipe shape, and both ends in the arrangement direction are connected to a heat exchange unit 28 arranged outside the house. Most of the heat collecting pipe 26 is housed inside the wall portion 30 through the opening 34 formed in the outer wall panel 32 forming the wall portion 30 of the house 12. Further, the heat collecting pipe 26 extends to the upper side of the building through the opening 34, and the intermediate portion in the longitudinal direction is arranged in the attic space 20. The intermediate portion is a heat collecting portion 36, which will be described later. Although not shown, the heat collecting pipe 26 has a heat insulating material wrapped around a portion housed inside the wall portion 30 and a portion exposed to the outside and connected to the heat exchange unit 28.

The heat collecting pipe 26 is used as a circulation path for circulating the antifreeze liquid stored inside the heat exchange unit 28. Specifically, the antifreeze liquid stored in the heat exchange unit 28 is sent to one end of the heat collection pipe 26 by the pump 40, supplied to the inside of the heat collection pipe 26, and then returned to the inside of the heat exchange unit 28. It has become. The antifreeze solution corresponds to the "heat medium" in the present invention.

The heat collecting portion 36 has a plurality of annular portions 36A in which the heat collecting pipe 26 is wound in a loop to form an annular shape in order to increase the surface area thereof. The plurality of annular portions 36A are suspended from two or more rafters 24 via mounting members (hook 42 as an example). As a result, the heat collecting portion 36 is attached to the rafter 24 as an attic structural material. In addition, in FIG. 1 and FIG. 2, for convenience of explanation, the configuration in which the heat collecting portion 36 is attached to one rafter 24 arranged in the attic space 20 is illustrated.

In the house 12, heat is transferred from the ridges 22 and rafters 24 heated by the sun, and hot air is trapped inside the attic space 20. The heat collecting unit 36 having the above configuration is attached in the vicinity of the rafters 24 that have absorbed the sun, and collects heat from the air in the attic space 20 using the antifreeze liquid flowing inside the heat collecting pipe 26 as a heat medium. Then, the antifreeze liquid returns to the heat exchange unit 28 again to exchange heat with other antifreeze liquid stored inside the heat exchange unit 28. By circulating the antifreeze liquid through the heat collecting pipe 26 in this way, the heat of the attic space 20 is stored in the heat exchange unit 28.

As described above, the heat exchange unit 28 is arranged outdoors as a heat storage tank that stores hot air in the attic space 20 using the antifreeze liquid stored inside as a heat medium. The heat exchange unit 28 is a water supply channel 46 for supplying hot water to the hot water supply system 44 in the house 12, and an underfloor circulation path 54 for supplying warmed antifreeze to the floor heating system 52 in the house 12. It is provided in the flow path.

The water supply channel 46 includes a heat exchange path 48 that exchanges heat with the heat exchange unit 28 described above, and a water supply channel 50 that sends hot water from the hot water storage tank 49 that stores hot water to the hot water supply system 44 in the house 12. One end of the heat exchange path 48 is connected to a water supply port (not shown), and cold water is supplied to the inside by opening and closing the solenoid valve 51. The other end of the heat exchange path 48 is connected to a hot water storage tank 49 arranged outdoors in the house 12. The heat exchange unit 28 is provided in the middle of the heat exchange path 48, and the cold water flowing in the heat exchange path 48 is warmed by heat exchange with the antifreeze liquid warmed inside the heat exchange unit 28. As a result, hot water is supplied to and stored in the hot water storage tank 49. Further, hot water is taken out from the hot water storage tank 49 to the water supply channel 50, and hot water is supplied to the hot water supply system 44 in the house 12.

The hot water supply system 44 is provided with an auxiliary heat source such as a boiler (not shown), re-cooks hot water as needed, and supplies it to the bathroom, kitchen, or the like of the house 12.

On the other hand, the underfloor circulation passage 54 forms a part of the floor heating system 52, and is formed in a tube shape or a pipe shape so that the antifreeze liquid can flow. As an example, the underfloor circulation passage 54 is arranged inside a floor heating panel (not shown) arranged on the floor portion 56 of the living room space 16, and is arranged from one end side to the other end side of the floor portion 56 of the living room space 16. It is arranged so as to have a zigzag shape. Then, one end and the other end of the underfloor circulation path 54 in the arrangement direction are connected to the heat exchange unit 28, and the antifreeze liquid supplied into the underfloor circulation path 54 by opening and closing the solenoid valve 58 exchanges heat using the pump 60. It is configured to return to the unit 28. That is, the antifreeze liquid flowing in the floor portion 56 circulates. Further, although not shown, the floor heating system 52 is provided with an auxiliary heat source such as a boiler (not shown), similarly to the hot water supply system 44 described above. As a result, the temperature of the floor portion 56 can be adjusted by heating the antifreeze liquid as needed.

(Action / effect)
Next, the action and effect of this embodiment will be described.

In the installation structure of the solar heat utilization system 10 of the present embodiment, the heat collecting unit 36 is attached to the rafters 24 of the attic space 20, while the heat exchange unit 28 is installed outdoors. In the solar heat utilization system 10, heat is transferred from the air in the attic space 20 heated by the solar heat, and the antifreeze liquid passing through the heat collecting portion 36 of the heat collecting pipe 26 is heated. Further, the warmed antifreeze circulates inside the heat collecting pipe 26 and returns to the inside of the heat exchange unit 28 installed outside the house 12. As a result, solar heat is collected in the heat exchange unit 28 using the antifreeze liquid as a heat medium.

Further, in the heat exchange unit 28, heat exchange is performed between the cold water and the antifreeze liquid supplied indoors. Specifically, the antifreeze liquid returning from the heat collecting pipe 26 to the heat exchange unit 28 exchanges heat with the antifreeze liquid stored in the heat exchange unit 28, and the antifreeze liquid in the heat exchange unit 28 is warmed. Then, heat exchange is performed between the warmed antifreeze liquid and the cold water supplied to the indoor hot water supply system 44, and hot water is obtained. On the other hand, the warmed antifreeze in the heat exchange unit 28 is supplied to the indoor floor heating system 52.

According to the above-described configuration, by arranging only the heat collecting unit 36 in the attic space 20, it is not necessary to install a large facility such as the heat exchange unit 28 in the attic space 20. As a result, when the solar heat utilization system 10 is installed after construction by remodeling a house or the like, the construction work does not become large and can be easily performed.

Further, in the present embodiment, the heat collecting portion 36 of the heat collecting pipe 26 is attached to two or more rafters 24 arranged in the attic space 20. Therefore, the length of the heat collecting portion 36 can be sufficiently secured, and the amount of heat supplied from the attic space 20 can be increased.

Further, in the present embodiment, the surface area of the heat collecting portion 36 is increased by forming a plurality of annular portions 36A in the heat collecting portion 36. As a result, the absorption efficiency of solar heat by the heat collecting unit 36 is improved, and by extension, the utilization efficiency of solar heat energy is improved.

Further, in the present embodiment, the hot water storage tank 49 in which the hot water supplied to the hot water supply system 44 is stored is installed outdoors as in the heat exchange unit 28. Therefore, the living room space 16 can be secured wider than the structure in which the large hot water storage tank 49 is installed in the house. Further, by installing the hot water storage tank 49 outdoors, it is possible to install large-scale equipment without entering the dwelling unit, which facilitates the installation work.

Further, in the present embodiment, since most of the heat collecting pipe 26 is arranged inside the wall portion 30 of the house 12, the heat collecting pipe 26 is not easily affected by the temperature difference of the outside air, and the heat shielding effect is enhanced. Has been done. This makes it possible to improve the efficiency of solar heat transfer by the antifreeze liquid.

[Supplemental Information]
In the above embodiment, the heat collecting portion 36 is attached to the rafters 24, but the present invention is not limited to this, and the heat collecting portion 36 may be attached to the rafters 22. Further, although the heat collecting portion is attached to each of two or more rafters 24, it may be attached to one rafter 24.

Further, in the above embodiment, the solar heat utilization system 10 includes a hot water supply system 44 and a floor heating system 52. However, the present invention is not limited to this, and the configuration may include either the hot water supply system 44 or the floor heating system 52. That is, the heat exchange unit 28 may be provided only in the flow path of the water supply channel 46, or the heat exchange unit 28 may be provided only in the flow path of the underfloor circulation passage 54.

Further, in the floor heating system 52 of the above embodiment, the antifreeze liquid circulates in the underfloor circulation passage 54, but the present invention is not limited to this, and the underfloor heating system 52 can also be a hot water type underfloor heating system in which hot water circulates in the underfloor circulation passage. Good. In this case, one end and the other end of the underfloor circulation path in the arrangement direction may be connected to the hot water storage tank 49 of the above embodiment, and hot water may be supplied from the hot water storage tank 49 into the underfloor circulation path.

10 Solar heat utilization system 12 Residential 20 Attic space 22 Attic structural material (purlin)
24 Attic structural material (rafters)
26 Heat collecting pipe 28 Heat exchange unit 36 Heat collecting part 36A Ring part 46 Water supply channel (flow path)
54 Underfloor circulation path (flow path)

Claims (3)

A heat exchange unit that is provided in the flow path of the fluid supplied indoors in a house, is installed outdoors, and exchanges heat between the heat medium stored inside and the fluid.
It has a tube-like or pipe-like shape, has a heat collecting part, is attached to the roof structure material to collect heat from the air in the roof space, and both ends are connected to the heat exchange unit so that the heat medium can move inside. A circulating heat collecting pipe and
Installation structure of the solar heat utilization system equipped with. The heat collectors are attached to two or more rafters that support the roofing material, respectively.
The installation structure of the solar heat utilization system according to claim 1. The heat collecting portion has a plurality of annular portions formed by winding an intermediate portion of the heat collecting pipe in a loop shape.
The installation structure of the solar heat utilization system according to claim 1 or 2.