JP2012149867A - Cooling system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling system with a comparatively simple structure, which can improve the power generation efficiency of a solar panel.SOLUTION: The air blow out port (23c) of an outdoor unit (21) is provided with a switching damper (25) for switching the direction of air blow out so as to blow out the warm wind discharged during cooling operation to the outside in the lower area (30) of the solar panel (3) while the cool wind discharged during warming operation toward the lower surface of the solar panel (3).

Description

  The present invention relates to a cooling system.

  Conventionally, in outdoor spaces such as rooftops of buildings, solar panels that convert sunlight light energy into electric power and air-cooled heat exchange devices such as air conditioner heat source units and cooling towers are often provided side by side. (For example, refer to Patent Document 1).

  A solar panel provided in an outdoor space converts light energy of sunlight into electric power, and supplies this electric power to an air conditioner or other equipment installed in a building or the like. On the other hand, an air-cooled heat exchange device provided in an outdoor space is configured such that a heat medium such as a refrigerant or water circulates, and sucks outdoor air to exchange heat with the heat medium. For example, in an outdoor unit of an air conditioner, a refrigerant circulates as a heat medium, heat is exchanged between the refrigerant and the sucked outdoor air, and the refrigerant is cooled during a cooling operation, while the refrigerant is cooled during a heating operation. Heating.

JP 2007-255813 A

  By the way, the solar panel has a feature that power generation efficiency (efficiency for converting light energy into electric power) decreases when the temperature rises too much. In order to improve the power generation efficiency of the solar panel, it may be possible to separately provide a cooling device for cooling the solar panel, but this is not preferable because the cost increases.

  This invention is made | formed in view of this point, The objective is to propose the cooling system which can aim at the improvement of the power generation efficiency of a solar panel with a comparatively simple structure.

The first invention is a solar panel (3) that is installed in an outdoor space and converts light energy of sunlight into electric power;
A planting layer (4) provided in a lower region (30) of the solar panel (3) in the outdoor space, and holding a plant for cooling the air in the lower region (30) by transpiration;
An air cooling system in which the heat medium passes through the inside and sucks outside air to exchange heat between the air and the heat medium, thereby cooling the heat medium during the cooling operation and heating the heat medium during the heating operation. Heat exchange device (21),
The heat exchanger (21) is provided at the air outlet (23c) and blows out hot air exhausted during the cooling operation to the outside of the lower region (30), while the cool air exhausted during the heating operation is sent to the solar panel ( 3) A cooling system comprising switching means (25) for switching the blowing direction so as to blow toward the lower surface.

  In 1st invention, the switching means (25) which switches the blowing direction of air is provided in the blower outlet (23c) of a heat exchange apparatus (21). The switching means (25) blows out warm air exhausted during the cooling operation to the outside of the lower region (30), while blowing cool air exhausted during the heating operation toward the lower surface of the solar panel (3).

  With such a configuration, the hot air exhausted during the cooling operation is blown out of the lower region (30) so that the hot air circulates in the lower region (30) and the temperature in the lower region (30). Can be prevented from rising. Moreover, by blowing out the cool air exhausted during the heating operation toward the lower surface of the solar panel (3), the solar panel (3) can be cooled and the temperature rise of the solar panel (3) can be suppressed. Thereby, the power generation efficiency of the solar panel (3) can be improved with a relatively simple configuration without separately providing a cooling device for cooling the solar panel (3). Then, the air heated by the solar panel (3) can be circulated in the lower area (30) and sucked from the suction port (23b) of the heat exchange device (21). The heat exchange efficiency of (21) can be improved.

  In addition, a solar panel (3) and an air-cooled heat exchanger (21) are installed in the same outdoor space, and a planting layer (4 ) Is provided. This prevents the solar panel (3) from being heated by reflection or radiant heat by reflecting the sunlight reflected on the ground in the outdoor space and the radiant heat from the ground being absorbed by the planting layer (4). The Moreover, when the plant of the planting layer (4) performs transpiration, water vapor is released into the air in the lower region (30) of the solar panel (3), and the water vapor absorbs heat from the air and vaporizes to lower region ( 30) Air is cooled. Further, the temperature rise of the solar panel (3) is also suppressed when the cooling air touches the solar panel (3).

  Moreover, an air flow is formed in the lower area | region (30) of a solar panel (3), when the air-cooled heat exchange apparatus (21) sucks the air of the lower area | region (30) of a solar panel (3). Thereby, in the lower area | region (30), since the air containing the water vapor | steam by the transpiration of the plant of a planting layer (4) flows without staying, the transpiration of the plant of a planting layer (4) is accelerated | stimulated.

According to a second invention, in the first invention,
The switching means (25) is configured to adjust the blowing angle so that cold air exhausted during heating operation flows along the lower surface of the solar panel (3). is there.

  In the second invention, the blowing angle of the switching means (25) is adjusted, and the cool air exhausted during the heating operation flows along the lower surface of the solar panel (3). With such a configuration, it is possible to blow cold air over a wide range of the lower surface of the solar panel (3), and the cooling efficiency of the solar panel (3) is improved.

According to a third invention, in the first or second invention,
A guide member (35) for guiding the cool air is provided so that the cool air exhausted during the heating operation flows along the lower surface of the solar panel (3).

  In the third invention, the guide member (35) guides the cool air exhausted during the heating operation so as to flow along the lower surface of the solar panel (3). With such a configuration, it is possible to distribute cold air over a wide range of the lower surface of the solar panel (3), and the cooling efficiency of the solar panel (3) is improved.

According to a fourth invention, in any one of the first to third inventions,
The switching means (25) is configured to switch the blowing direction so that air exhausted during the defrost operation of the heat exchange device (21) is blown out of the lower region (30). It is a feature.

  In the fourth invention, the air blowing direction is switched by the switching means (25), and the air exhausted during the defrost operation of the heat exchange device (21) is blown out of the lower region (30).

  With such a configuration, the hot air exhausted during the defrost operation is blown out of the lower region (30) so that the hot air circulates in the lower region (30) and the temperature in the lower region (30). Can be prevented from rising. As a result, the temperature increase of the solar panel (3) can be suppressed, and the power generation efficiency of the solar panel (3) can be improved.

  Specifically, control is performed so that the warm air exhausted during the cooling operation is blown out of the lower region (30) while the cool air exhausted during the heating operation is blown out toward the lower surface of the solar panel (3). However, even during heating operation, when performing defrost operation to remove frost adhering to the outdoor heat exchanger of the heat exchange device (21), hot air is blown from the outlet (23c). Become. Therefore, in the present invention, when the defrost operation is performed during the heating operation, the blowing direction is switched by the switching means (25) so that the exhausted air is blown out to the outside of the lower region (30).

According to a fifth invention, in any one of the first to fourth inventions,
An outside air temperature detecting means (47) for detecting outside air temperature outside the lower region (30);
A suction temperature detection means (48) for detecting the temperature of the air sucked into the suction port (23b) of the heat exchange device (21),
The switching means (25) is a cool air exhausted during heating operation when the outside air temperature detected by the outside air temperature detecting means (47) is higher than the suction temperature detected by the suction temperature detecting means (48). Is blown out of the lower region (30) so that the blowing direction is switched.

  In the fifth invention, the outside air temperature detecting means (47) detects the outside air temperature outside the lower region (30). The suction temperature detection means (48) detects the temperature of the air sucked into the suction port (23b) of the heat exchange device (21). When the outside air temperature is higher than the suction temperature, the air blowing direction is switched by the switching means (25), and the cool air exhausted during the heating operation is blown out of the lower region (30).

  With such a configuration, high-temperature air is sucked into the suction port (23b) of the heat exchange device (21), which improves the heat exchange efficiency of the heat exchange device (21) during heating operation. it can.

  Specifically, cool air exhausted during heating operation is blown out toward the lower surface of the solar panel (3), so that the solar panel (3) can be cooled to suppress the temperature rise of the solar panel (3). . Then, the air whose temperature has been increased through heat exchange with the solar panel (3) circulates in the lower region (30) and is sucked into the inlet (23b) of the heat exchanger (21).

  However, when the temperature of the solar panel (3) is not so high, such as during periods of low solar radiation, heat exchange between the cold wind exhausted during heating operation and the solar panel (3) is hardly performed, and the temperature is low. The remaining air circulates in the lower region (30) and is sucked into the suction port (23b) of the heat exchange device (21). As a result, the heat exchange efficiency of the heat exchange device (21) decreases.

  On the other hand, in the present invention, when the outside air temperature is higher than the suction temperature, the cool air exhausted during the heating operation is blown out to the outside of the lower region (30). Thus, the air can be sucked into the suction port (23b) of the heat exchange device (21), and the heat exchange efficiency of the heat exchange device (21) during the heating operation can be improved.

A sixth invention is any one of the first to fifth inventions,
After the air is blown toward the lower surface of the solar panel (3) during the heating operation, the flow direction of the air flowing along the lower surface is changed so as to go to the suction port (23b) of the heat exchange device (21). An airflow guide member (38) for guiding the airflow is provided.

  In 6th invention, air blows off toward the lower surface of a solar panel (3) at the time of heating operation. The flow direction of the air flowing along the lower surface of the solar panel (3) is changed by the airflow guide member (38), and is guided toward the suction port (23b) of the heat exchange device (21).

  With such a configuration, the air flow direction member (38) changes the air flow direction, and heat is exchanged with the solar panel (3) to circulate the heated air in the lower region (30). The heat exchange device (21) can be sucked from the suction port (23b), and the heat exchange efficiency of the heat exchange device (21) can be improved.

  According to the present invention, the air blowing direction is changed between the cooling operation and the heating operation by the switching means (25) provided at the air outlet (23c) of the heat exchange device (21). Thereby, the warm air exhausted during the cooling operation is blown out of the lower region (30), so that the warm air circulates in the lower region (30) and the temperature in the lower region (30) rises. Can be suppressed. Moreover, by blowing out the cool air exhausted during the heating operation toward the lower surface of the solar panel (3), the solar panel (3) can be cooled and the temperature rise of the solar panel (3) can be suppressed. As a result, the power generation efficiency of the solar panel (3) can be improved with a relatively simple configuration without separately providing a cooling device for cooling the solar panel (3). Then, the air heated by the solar panel (3) can be circulated in the lower area (30) and sucked from the suction port (23b) of the heat exchange device (21). The heat exchange efficiency of (21) can be improved.

  Also, a guide member that adjusts the blowing angle of the switching means (25) to blow cold air over a wide area of the lower surface of the solar panel (3) or guide the cold air to flow along the lower surface of the solar panel (3). By providing (35), the cooling efficiency of the solar panel (3) can be improved.

  In addition, when performing defrost operation even during heating operation, the hot air circulated in the lower region (30) by blowing out the warm air exhausted during the defrost operation to the outside of the lower region (30). And it can suppress that the temperature in a lower area | region (30) rises. As a result, the temperature increase of the solar panel (3) can be suppressed, and the power generation efficiency of the solar panel (3) can be improved.

  In addition, when the outside air temperature is higher than the suction temperature, the cool air exhausted during heating operation is blown out to the outside of the lower region (30), so that hot air is taken in from the outside and the heat exchange device (21) is inhaled. The air can be sucked into the mouth (23b), and the heat exchange efficiency of the heat exchange device (21) during the heating operation can be improved.

  In addition, by changing the air flow direction using the airflow guide member (38), heat exchanged with the solar panel (3) is performed in the lower region (30) to circulate the air whose temperature has been increased. 21) can be sucked in from the suction port (23b), and the heat exchange efficiency of the heat exchange device (21) can be improved.

FIG. 1 is a schematic configuration diagram of a cooling system according to Embodiment 1 of the present invention. FIG. 2 is a schematic configuration diagram of a cooling system according to the second embodiment. FIG. 3 is a plan view of the cooling system according to the second embodiment. FIG. 4 is a flowchart showing the operation of the cooling system according to the second embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1 of the Invention
-Cooling system configuration-
As shown in FIG. 1, the cooling system (1) includes an outdoor unit (21) as a heat exchange device for an air conditioner (2), a solar panel ( 3) and a planting layer (4).

  The air conditioner (2) has a refrigerant circuit (not shown) in which a refrigerant as a heat medium circulates and a vapor compression refrigeration cycle is performed, and an outdoor unit (21) installed on the roof (R) of a building ) And an indoor unit (not shown) installed in the building. The outdoor unit (21) accommodates an outdoor circuit, while the indoor unit accommodates an indoor circuit. In the present embodiment, one or more indoor units are installed in each of a plurality of rooms in a building. The refrigerant circuit is configured by connecting the indoor circuits of the plurality of indoor units in parallel to the outdoor circuit of the outdoor unit (21). Each indoor unit has an air-cooled indoor heat exchanger and an expansion mechanism, and supplies air regulated by the indoor heat exchanger to each room.

  The outdoor unit (21) includes an air-cooled outdoor heat exchanger (21a) connected by a refrigerant pipe to form an outdoor circuit, and a compressor (not shown). The outdoor unit (21) has a blower fan (not shown) that takes outside air into the interior and passes the outdoor heat exchanger (21a). The outdoor circuit and the blower fan are accommodated in the outdoor casing (23). With such a configuration, the outdoor unit (21) is configured such that the refrigerant as the heat medium passes through the inside and sucks outside air to exchange heat between the air and the refrigerant.

  The outdoor casing (23) has a main body (23a), a suction duct (23b) as a suction port, and a blow-out duct (23c) as a blow-out port. An outdoor circuit is accommodated in the main body (23a). The suction duct (23b) is provided on the side of the main body and opens obliquely downward. The blowout duct (23c) is provided at the upper part of the main body (23a), and opens in the right direction and in the diagonally upward left direction in FIG.

  The outdoor unit (21) has a switching damper (25) as switching means for switching the air blowing direction. The switching damper (25) is provided in the blowing duct (23c), and adjusts the air blowing angle by rotating around a rotating shaft (26) connected to a motor (not shown). As a result, the external blowing position (shown by a solid line in FIG. 1) for blowing out the air after heat exchange to the outside of the lower region (30) of the solar panel (3) and the air after heat exchange on the lower surface of the solar panel (3) Can be switched to an internal blowing position (shown in phantom lines in FIG. 1).

  The outdoor unit (21) is installed in the lower area (30) of the solar panel (3). Specifically, the outdoor unit (21) sucks air in the lower area (30) of the solar panel (3) through the suction duct (23b), while the solar panel (3) through the blowout duct (23c). It installs so that the air after heat exchange may be blown out to the outside or inside of the lower region (30). Thus, by installing the outdoor unit (21) in the lower region (30) of the solar panel (3), direct sunlight can be suppressed from being applied to the outdoor unit (21). In the present embodiment, the suction duct (23b) is formed so as to open obliquely downward, and is configured to suck air in the lower layer portion of the lower region (30) of the solar panel (3). .

  The solar panel (3) is supported by a support base (not shown) and is inclined with respect to the floor surface of the rooftop (R) so that the amount of solar radiation on the light receiving surface is as large as possible. Moreover, although illustration is abbreviate | omitted, a solar panel (3) is comprised so that the light energy by the sunlight received at the light-receiving surface may be converted into electric energy, and supplied to an air conditioning apparatus (2) as electric power. .

  A plate-shaped guide member (35) is disposed below the solar panel (3). Specifically, the guide member (35) is arranged in parallel or perpendicular to the lower surface of the solar panel (3) with a predetermined gap. Thereby, the air path (36) is formed in the lower surface of the solar panel (3).

  The planting layer (4) is provided in the lower region (30) of the solar panel (3). The planting layer (4) is formed in a panel shape and holds plants. In the present embodiment, the planting layer (4) is constituted by snails and a panel-shaped holding member that holds snags. Moreover, in this embodiment, the planting layer (4) is provided in the lower layer part of the downward area | region (30) of a solar panel (3). Specifically, the planting layer (4) is laid on the roof (R) floor area below the solar panel (3) (30) except for the location of the outdoor unit (21) It has been.

  Moreover, the cooling system (1) includes a watering device (5) for spraying water toward the planting layer (4). The watering device (5) includes a transport pipe (5b) connected to a water source (5a), a water pump (5c), and a spray nozzle (5d). In this embodiment, the water source (5a) is constituted by a well in which groundwater is stored. The transport pipe (5b) extends from one end side to the other end side of the lower region (30) of the solar panel (3). The transport pipe (5b) is provided at a relatively high position in the lower region (30) of the solar panel (3) so that a plurality of spray nozzles (5d) spray water downward at intervals. Is attached. In the present embodiment, the transport pipe (5b) is disposed so as to be inclined with respect to the floor surface of the rooftop (R) in parallel with the solar panel (3). The water pump (5c) is provided upstream of the spray nozzle (5d) of the transport pipe (5b) and sucks water in the well, which is the water source (5a), to the downstream of the transport pipe (5b). Pump toward you.

  With this configuration, when the water pump (5c) of the watering device (5) is operated, the water from the water source (5a) is pumped downstream in the transport pipe (5b), and a plurality of spray nozzles (5d) It sprays toward the planting layer (4) below.

-Operation of the cooling system during cooling operation-
Next, the operation of the cooling system (1) during the cooling operation will be described.

  In the refrigerant circuit of the air conditioner (2), when the compressor is started, the outdoor heat exchanger (21a) functions as a radiator, while the refrigerant circulates so that the indoor heat exchanger functions as an evaporator. Specifically, in the outdoor unit (21), the high-pressure refrigerant compressed by the compressor flows into the outdoor heat exchanger (21a), while the blower fan drives the outdoor heat exchanger via the suction duct (23b). Air sucked into the main body (23a) containing (21a) passes through the outdoor heat exchanger (21a). As a result, in the outdoor heat exchanger (21a), the high-pressure refrigerant in the refrigerant circuit radiates heat to the air, flows out from the outdoor unit (21), and flows into the expansion mechanism of the indoor unit provided in each room. After being depressurized by the mechanism to become a low-pressure refrigerant, it flows into the indoor heat exchanger. In each indoor heat exchanger, the low-pressure refrigerant absorbs heat from the air in each room, thereby cooling the air in each room.

  Further, in the outdoor unit (21), the switching damper (25) in the blowing duct (23c) is rotated to switch to the external blowing position (shown by a solid line in FIG. 1). Then, the warm air radiated and heated from the high-pressure refrigerant in the outdoor unit (21) is exhausted to the outside of the outdoor unit (21) by the switching damper (25) through the blowout duct (23c). At this time, the warm air is blown out of the lower region (30) of the solar panel (3) from the blowing duct (23c). Here, as described above, since the blowing duct (23c) is provided at the upper part of the main body (23a), the blown air from the outdoor unit (21) is blown into the lower region (30) of the solar panel (3). The air is blown out from the relatively high position toward the outside of the lower region (30). Due to the flow of the blown air, the air in the upper layer portion of the lower region (30) is attracted in the flow direction of the blown air and exhausted to the outside of the lower region (30).

  The solar panel (3) receives sunlight from the light receiving surface and converts the light energy of sunlight into electrical energy. And electric energy is supplied to an air conditioning apparatus (2) as electric power.

  Moreover, in the lower area | region (30) of a solar panel (3), water is sprayed regularly toward a planting layer (4) by a watering device (5). Specifically, by the operation of the water pump (5c), water from the water source (5a) is pumped to the spray nozzles (5d) through the transfer pipe (5b), and the lower nozzles are planted from the spray nozzles (5d). Sprayed towards the planting layer (4). Thereby, water is supplied to the planting layer (4).

  In the planting layer (4), the plant retains the water sprayed by the watering device (5), evaporates and releases it into the air. In this way, the water vapor released to the lower region (30) of the solar panel (3) by the transpiration of the plant in the planting layer (4) absorbs heat from the air in the lower region (30), thereby cooling the air.

  As described above, since the air in the lower region (30) of the solar panel (3) is cooled by the transpiration of the plant in the planting layer (4), the outdoor unit (21) is driven by the fan. The cooled air in the lower area (30) of the panel (3) will be sucked in. As a result, the amount of heat radiation in the outdoor heat exchanger (21a) functioning as a radiator of the air conditioner (2) performing the cooling operation increases, and the enthalpy of the refrigerant in the outdoor heat exchanger (21a) decreases. As a result, the amount of heat absorbed by the refrigerant in the indoor heat exchanger functioning as an evaporator increases, and the cooling efficiency of the air conditioner (2) significantly increases.

  Further, when the outdoor unit (21) sucks air in the lower region (30) of the solar panel (3), an air flow is formed in the lower region (30) of the solar panel (3). Thereby, in the lower region (30), air containing water vapor due to the transpiration of the plant in the planting layer (4) flows without stagnation, so that the transpiration of the planting layer (4) is promoted.

  In the present embodiment, the planting layer (4) is provided in the lower layer part of the lower region (30) of the solar panel (3), while the outdoor unit (21) is provided in the lower region (30) of the solar panel (3). It is comprised so that the air of the lower layer part of may be sucked. Therefore, in the lower area (30) of the solar panel (3), an air flow passing through the vicinity of the planting layer (4) provided in the lower layer is formed, and water vapor due to the transpiration of the plant in the planting layer (4) is generated. The contained air will flow more reliably. As a result, transpiration of the planting layer (4) is further promoted.

  In addition, in the summer when the outside air temperature is high and the amount of solar radiation is high, the planting layer (4) reflects the sunlight reflected on the floor of the rooftop (R) and the radiant heat from the floor to the planting layer (4). By being absorbed, the solar panel (3) is suppressed from being heated by reflection or radiant heat. Furthermore, the temperature rise of the solar panel (3) is also suppressed by cooling the air in the lower region (30) of the solar panel (3) by the transpiration of the plant in the planting layer (4).

  In the present embodiment, as described above, the blown air from the outdoor unit (21) is blown out from a relatively high position in the lower region (30) of the solar panel (3). Inspired by the flow of the blown air, an air flow is formed in the flow direction of the blown air in the upper layer portion of the lower region (30), and the air in the upper layer portion is exhausted to the outside of the lower region (30). By the way, in the upper layer part of the lower region (30) of the solar panel (3), the air temperature is higher than the lower layer part because it is close to the solar panel (3). Therefore, as described above, air flow is formed in the upper layer portion of the lower region (30) by the blown-out air from the outdoor unit (21), so that relatively high temperature air flows into the upper layer portion of the lower region (30). It is exhausted outside without staying in This makes it easier for the lower layer air in the lower region (30) cooled by the transpiration of the plant in the planting layer (4) to be supplied to the upper layer, and the solar panel (3) is cooled. As a result, the temperature rise of the solar panel (3) is further suppressed.

  In addition, in this embodiment, the plant of the planting layer (4) is comprised by Snago. Snagoke has the characteristics that it can grow without soil to absorb moisture and nutrients from the atmosphere, and is strong against drying and has a high water holding power. For this reason, the planting layer (4) retains snag moss, so that the transpiration of snag moss is maintained for a relatively long time even if it is dried and lacks moisture in the atmosphere. Snagoke can also grow in the shade, so there is no problem in growing even if it is provided in the lower area (30) of the solar panel (3), and this also ensures stable transpiration. . As mentioned above, the air of the lower area | region (30) of a solar panel (3) will be cooled stably by employ | adopting Snagoke for the plant of a planting layer (4).

-Operation of the cooling system during heating operation-
Next, the operation of the cooling system (1) during the heating operation will be described.

  In the refrigerant circuit of the air conditioner (2), when the compressor is started, the outdoor heat exchanger (21a) functions as an evaporator, and the refrigerant circulates so that the indoor heat exchanger functions as a radiator. Specifically, the high-pressure refrigerant compressed by the compressor flows into the indoor heat exchanger of the indoor unit provided in each room. In each indoor heat exchanger, the air in each room is warmed by the high-pressure refrigerant in the refrigerant circuit radiating heat to the air. The high-pressure refrigerant that has flowed out of the indoor heat exchanger flows into the expansion mechanism of the indoor unit, is decompressed by the expansion mechanism to become low-pressure refrigerant, and then flows into the outdoor heat exchanger (21a). In the outdoor heat exchanger (21a), the low-pressure refrigerant absorbs heat from the air to cool the air.

  Further, in the outdoor unit (21), the switching damper (25) in the blowout duct (23c) is rotated to switch to the internal blowout position (shown in phantom lines in FIG. 1). And the cold wind which was absorbed and cooled by the low-pressure refrigerant in the outdoor unit (21) is blown out toward the lower surface of the solar panel (3) through the blowing duct (23c) by the switching damper (25). Here, the blown-out cool air flows along the lower surface of the solar panel (3) through the guide member (35). Thereby, cold wind can be distributed over the wide range of the lower surface of a solar panel (3), and the cooling efficiency of a solar panel (3) improves.

-Effect of Embodiment 1-
As described above, according to the cooling system (1) according to the first embodiment, the air blowing direction is switched by the switching damper (25), and the cooling air is directed toward the lower surface of the solar panel (3) during the heating operation. By blowing out, the solar panel (3) can be cooled and the temperature rise of the solar panel (3) can be suppressed. Thereby, the power generation efficiency of the solar panel (3) can be improved with a relatively simple configuration without separately providing a cooling device for cooling the solar panel (3).

  In addition, the outdoor unit (21) is configured so that warm air is blown from a relatively high position in the lower region (30) of the solar panel (3) toward the outside of the lower region (30) during cooling operation. Has been. With such a configuration, it is possible to prevent the warm air from circulating in the lower region (30) of the solar panel (3) and causing the temperature in the lower region (30) to rise, and the lower region (30 An air flow that flows in the flow direction of the blown air can be formed in the upper layer portion. As a result, the air in the upper layer of the lower region (30) having a relatively high temperature can be exhausted outside without being retained. Therefore, air in the lower layer of the lower region (30), which is cooled by the transpiration of the planting layer (4), is easily supplied to the upper layer, and the temperature rise of the solar panel (3) is further suppressed. can do.

  In addition, on the roof (R) of the building, a planting layer (4) is provided in the lower region (30) of the solar panel (3), and the solar panel (3) is located below the solar panel (3) by the transpiration of the plant in the planting layer (4). It was decided to cool the air in the region (30). Thereby, the temperature rise of a solar panel (3) is suppressed. In particular, in summer when the outside air temperature is high and the amount of solar radiation is large, the power generation efficiency is significantly reduced due to the temperature rise of the solar panel (3). Since the temperature rise of the solar panel (3) can be suppressed, the power generation efficiency can be improved. Thereby, a large amount of solar radiation in the summer can be used effectively for power generation.

<< Embodiment 2 of the Invention >>
FIG. 2 is a schematic configuration diagram of a cooling system according to the second embodiment. Since the difference from the first embodiment is that the opening / closing operation of the switching damper (25) during heating operation is partially different, hereinafter, the same parts as those of the first embodiment are denoted by the same reference numerals, and different points. Only will be described.

  As shown in FIG. 2, the outdoor unit (21) includes an air-cooled outdoor heat exchanger (21a), a defrost device (28) disposed in the vicinity of the outdoor heat exchanger (21a), and a compressor (illustrated). (Omitted). The outdoor unit (21) has a blower fan (not shown) that takes outside air into the interior and passes the outdoor heat exchanger (21a). The outdoor circuit and the blower fan are accommodated in the outdoor casing (23).

  The outdoor casing (23) has a main body (23a), a suction duct (23b) as a suction port, and a blow-out duct (23c) as a blow-out port. An outdoor circuit is accommodated in the main body (23a). The suction duct (23b) is provided on the side of the main body and opens obliquely downward. The blowout duct (23c) is provided at the upper part of the main body (23a), and opens in the right direction and in the diagonally upward left direction in FIG.

  The outdoor unit (21) has a switching damper (25) as switching means for switching the air blowing direction. Specifically, the switching damper (25) includes an external blowing position for blowing the air after heat exchange to the outside of the lower region (30) of the solar panel (3) in the blow duct (23c), and the air after heat exchange. Is provided at each of the internal blow-out positions for blowing the air toward the lower surface of the solar panel (3).

  The switching damper (25) adjusts the air blowing direction and the blowing angle by rotating about a rotating shaft (26) connected to a motor (not shown). That is, by opening the external blow position switching damper (25) and closing the internal blow position switching damper (25), the air after heat exchange is blown to the outside of the lower area (30) of the solar panel (3). The Further, by closing the external blowing position switching damper (25) and opening the internal blowing position switching damper (25), the air after heat exchange is blown out toward the lower surface of the solar panel (3).

  In addition, in this Embodiment 2, although it has set as the structure which provided the switching damper (25) in the external blowing position and the internal blowing position, respectively, like Embodiment 1, only one switching damper (25) of the blowing direction is used. It is good also as a structure which switches.

  The defrost device (28) is for removing frost adhering to the outdoor heat exchanger (21a), and can be constituted by, for example, a heater for heating the outdoor heat exchanger (21a). In addition, it may be configured to remove frost by circulating a high-temperature refrigerant therein and exchanging heat between the high-temperature refrigerant and the outdoor heat exchanger (21a).

  The outdoor unit (21) is installed in the lower area (30) of the solar panel (3). Specifically, the outdoor unit (21) sucks air in the lower area (30) of the solar panel (3) through the suction duct (23b), while the solar panel (3) through the blowout duct (23c). It installs so that the air after heat exchange may be blown out to the outside or inside of the lower region (30). A suction temperature sensor (48) (suction temperature detecting means) for detecting the temperature of the air sucked into the suction duct (23b) is attached to the suction duct (23b).

  A plate-shaped guide member (45) is disposed below the solar panel (3). The guide member (45) is formed with a plurality of heat radiation holes (45a) penetrating in the thickness direction. Thereby, a guide member (45) functions as a heat sink which radiates the heat of a solar panel (3). Outside the system, an outside temperature sensor (47) (outside temperature detecting means) for detecting outside temperature outside the lower region (30) is provided.

  As shown in FIG. 3, a plurality of guide members (45) are arranged so as to extend perpendicular to the lower surface of the solar panel (3) and along the inclination direction of the solar panel (3) (shown in FIG. 3). An example is the case of 3 sheets × 2 rows, but the number of sheets is not particularly limited). And the row | line | column of the three guide members (45) arrange | positioned along the inclination direction is arrange | positioned at intervals in the width direction (up-down direction in FIG. 3) of the solar panel (3). That is, a total of six guide members (45) are arranged. As a result, the cold air exhausted during the heating operation is guided to flow along the lower surface of the solar panel (3) into the space between the lower surface of the solar panel (3) and the two rows of guide members (45). An air passage (46) is formed. In FIG. 3, the solar panel (3) is not shown.

  An airflow guide member (38) extending vertically downward from the lower surface of the solar panel (3) is provided on the downstream side of the air passage (46). A gap is provided between the lower end of the airflow guiding member (38) and the upper surface of the planting layer (4), and external air flows into the lower region (30) from this gap.

  The airflow guiding member (38) extends in the width direction of the solar panel (3). In other words, the air blown out from the blow duct (23c) and circulated through the air passage (46) collides with the air flow guide member (38), the flow direction is changed, and circulates in the lower region (30) to heat It is led to the suction duct (23b) of the exchange device (21).

  With this configuration, the air heated by the solar panel (3) is circulated in the lower area (30) and sucked from the suction duct (23b) of the heat exchange device (21). The heat exchange efficiency of the heat exchange device (21) can be improved.

  In addition, in this Embodiment 2, although description of the watering apparatus (5) sprinkling toward a planting layer (4) is abbreviate | omitted, it is good also as a structure which provided the watering apparatus (5).

-Operation of cooling system-
Next, operation | movement operation | movement of a cooling system (1) is demonstrated using the flowchart figure of FIG. As shown in FIG. 4, in step S101, it is determined whether or not the heat exchange device (21) is in the heating operation. If “YES” at step S101, the process branches to step S102. When the determination in step S101 is “NO”, it is determined that the cooling operation is being performed, and the process branches to step S105.

  In step S102, it is determined whether or not to perform the defrost operation during the heating operation. If the determination in step S102 is “YES”, it is determined that the air blown from the blowout duct (23c) of the heat exchange device (21) is hot air, and the process branches to step S105. If “NO” at step S102, the process branches to step S103.

  In step S103, it is determined whether or not the outside air temperature detected by the outside air temperature sensor (47) is higher than the suction temperature detected by the suction temperature sensor (48). If “YES” at step S103, the process branches to step S105. If “NO” at step S103, the process branches to step S104.

  In step S104, the external blow position switching damper (25) is closed and the internal blow position switching damper (25) is opened. That is, the air exhausted from the blowing duct (23c) is blown out toward the lower surface of the solar panel (3), and the process is terminated.

  In step S105, the external blow position switching damper (25) is opened and the internal blow position switching damper (25) is closed. That is, the air exhausted from the blowing duct (23c) is blown out to the outside of the lower region (30), so that high temperature air is taken in from the outside and sucked into the suction duct (23b), and the process is terminated.

-Effect of Embodiment 2-
As described above, according to the cooling system (1) according to the second embodiment, when the defrost operation is performed even during the heating operation, the warm air exhausted during the defrost operation is reduced to the lower region (30). It is possible to suppress the warm air from circulating in the lower region (30) and the temperature in the lower region (30) from rising. As a result, the temperature increase of the solar panel (3) can be suppressed, and the power generation efficiency of the solar panel (3) can be improved.

  In addition, when the outside air temperature is higher than the suction temperature, the cool air exhausted during heating operation is blown out to the outside of the lower region (30), so that hot air is taken in from the outside and the heat exchange device (21) is inhaled. The air can be sucked into the mouth (23b), and the heat exchange efficiency of the heat exchange device (21) during the heating operation can be improved.

-Other embodiments-
In the said embodiment, although the cooling system (1) was provided with the water sprinkler (5), it may be provided with the water supply means which supplies water to a planting layer (4) instead of a water sprinkler (5). .

  Moreover, in the said embodiment, Snagoke was employ | adopted as a plant of a planting layer (4), However, The plant of the planting layer (4) which concerns on this invention is not restricted to this, What kind of thing will be used if it transpires It may be a thing.

  Moreover, in the said embodiment, although the water source (5a) of the water sprinkler (5) was comprised by the well, a water source (5a) is not restricted to this, For example, the water guide | induced from the water supply etc. is stored temporarily. It may be a water supply tank or the like. Further, the watering device (5) may be configured not to include the water pump (5c) but to directly connect the transport pipe (5b) to the water supply.

  Moreover, in the said embodiment, although the solar panel (3) and the outdoor unit (21) were installed in the roof (R) of a building, these are not the roof (R) of a building but outdoor space, such as the ground It may be installed in.

  In the embodiment, the power generated by the solar panel (3) is configured to be supplied to the air conditioner (2). However, the generated power is configured to be supplied to another device. It may be.

  Moreover, in the said embodiment, although the planting layer (4) was provided in the lower layer part of the lower area | region (30) of a solar panel (3), the arrangement position of a planting layer (4) is not restricted to this, It can be anywhere below the solar panel (3) (30). For example, you may arrange | position above the lower layer part of a lower area | region (30) with a support stand etc.

  In the above embodiment, the outdoor unit (21) is configured to suck air in the lower layer of the lower region (30) of the solar panel (3). However, the outdoor unit (21) Of course, a suction port may be formed at a position other than the lower layer of the lower region (30).

  In the embodiment, the cooling system (1) includes the outdoor unit (21) of the air conditioner (2) as an air-cooled heat exchange device according to the present invention. However, the cooling system (1) according to the present invention is not limited to this. For example, the cooling system (1) may include a heat source device of a refrigeration apparatus such as a chiller as an air-cooled heat exchange apparatus.

  In the first embodiment, the air blowing direction is switched by only one switching damper (25). However, similarly to the second embodiment, the switching damper (25) is switched between the external blowing position and the internal blowing position, respectively. It is good also as a structure which provided.

  Further, the control in which the switching damper (25) is switched and the air is blown out of the lower region (30) during the defrost operation or when the outside air temperature is higher than the suction temperature will be described only in the second embodiment. However, the same applies to the cooling system (1) of the first embodiment.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention provides a highly practical effect that it is possible to improve the power generation efficiency of the solar panel with a relatively simple configuration. Is expensive.

1 Cooling system
3 Solar panel
4 Planting layer
21 Outdoor unit (heat exchanger)
23c Air outlet duct (air outlet)
23b Suction duct (suction port)
25 Switching damper (switching means)
30 Lower area
35 Guide member
38 Airflow guide member
47 Outside temperature sensor (outside temperature detection means)
48 Suction temperature sensor (suction temperature detection means)

Claims (6)

A solar panel (3) that is installed in an outdoor space and converts the light energy of sunlight into electric power;
A planting layer (4) provided in a lower region (30) of the solar panel (3) in the outdoor space, and holding a plant for cooling the air in the lower region (30) by transpiration;
An air cooling system in which the heat medium passes through the inside and sucks outside air to exchange heat between the air and the heat medium, thereby cooling the heat medium during the cooling operation and heating the heat medium during the heating operation. Heat exchange device (21),
The heat exchanger (21) is provided at the air outlet (23c) and blows out hot air exhausted during the cooling operation to the outside of the lower region (30), while the cool air exhausted during the heating operation is sent to the solar panel ( 3. A cooling system comprising switching means (25) for switching the blowing direction so as to blow toward the lower surface of 3). In claim 1,
The switching means (25) is configured to adjust the blowing angle so that cool air exhausted during heating operation flows along the lower surface of the solar panel (3). . In claim 1 or 2,
A cooling system comprising a guide member (35) for guiding the cold air exhausted during heating operation so as to flow along the lower surface of the solar panel (3). In any one of claims 1 to 3,
The switching means (25) is configured to switch the blowing direction so that air exhausted during the defrost operation of the heat exchange device (21) is blown out of the lower region (30). Features a cooling system. In any one of claims 1 to 4,
An outside air temperature detecting means (47) for detecting the outside air temperature in the lower region (30);
A suction temperature detection means (48) for detecting the temperature of the air sucked into the suction port (23b) of the heat exchange device (21),
The switching means (25) is a cool air exhausted during heating operation when the outside air temperature detected by the outside air temperature detecting means (47) is higher than the suction temperature detected by the suction temperature detecting means (48). The cooling system is configured to switch the blowing direction so as to be blown out of the lower region (30). In any one of claims 1 to 5,
Change the flow direction of the air flowing along the lower surface after being blown out toward the lower surface of the solar panel (3) during the heating operation so as to go to the inlet (23b) of the heat exchange device (21) A cooling system comprising an airflow guiding member (38) for guiding the airflow.

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