JP2022050159A - Air conditioning system - Google Patents

Abstract

To provide an air conditioning system that suppresses variations in air temperature while adjusting the humidity in a cultivation room in a plant factory.SOLUTION: An air conditioning system 1 comprises a first passage 11a that sends the air that has flowed into a suction port 6 to a cooling unit 21, a second passage 11b that sends the air that has passed through the cooling unit 21 to an outlet 7, a first bypass flow path 13 in which an inflow end is connected to the upstream side of the cooling unit 21 in the first passage 11a and an outflow end is connected to the second passage 11b, and a first opening degree-adjusting mechanism 14 for adjusting the opening degree of the first bypass flow path 13.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to an air conditioning system.

Conventionally, a plant factory for cultivating vegetables with artificial light such as fluorescent lamps and LEDs has been known. While the plant factory has the advantage that vegetables can be cultivated regardless of the season and the weather, the cultivation room of the plant factory is a closed space, so temperature control and humidity control in the cultivation room are important. Patent Document 1 discloses an air passage structure that uniformly adjusts the temperature and humidity of air in a cultivation room. In this air passage structure, an air passage that supplies air to the cultivation shelf in the cultivation room and an air passage that discharges air from the cultivation shelf are arranged so as to sandwich the cultivation shelf.

Japanese Unexamined Patent Publication No. 2019-041704

In order to produce vegetables with stable quality in such a plant factory, it is important to keep the cultivation shelves in the cultivation room at a temperature and humidity suitable for the growth of the vegetables.

Here, considering the influence of the wind speed in the cultivation shelf on the growth of vegetables, it is preferable to suppress the wind speed of the blowout to the cultivation shelf to a certain height. However, if the wind speed is relatively low and the distance until the blown air is sucked in is relatively long, the temperature rise of the air becomes large accordingly. Therefore, the temperature of the blowout may be set lower than the temperature of the suction. Furthermore, when the sucked air is dehumidified and supplied to the cultivation shelf again, the sucked air is cooled and dehumidified, so that the air blown out may have a relatively low temperature.

In such a case, the temperature difference between the blown-out air and the sucked-in air becomes large, resulting in temperature variation in the cultivation shelf, and there is a possibility that vegetables with stable quality cannot be produced.

In the air passage system of Patent Document 1, the cold air blown from one end of the plant shelf is sucked in at the other end of the plant shelf, and the variation in temperature in the plant shelf is not taken into consideration.

An object of the present disclosure is to suppress temperature variation while adjusting the humidity of air in a cultivation room in a plant factory.

The first aspect is an air conditioning system that air-conditions the cultivation room (S).
An air passage (11) that communicates a suction port (6) for sucking air in the cultivation room (S) and an air outlet (7) for blowing air into the cultivation room (S).
It is provided with a cooling unit (21) arranged in the air passage (11) and capable of cooling air below the dew point temperature.
The air passage (11)
The first passage (11a) for sending the air flowing into the suction port (6) to the cooling unit (21),
A second passage (11b) that sends air that has passed through the cooling unit (21) to the outlet (7),
The inflow end includes a first bypass flow path (13) connected to the upstream side of the cooling portion (21) in the first passage (11a) and an outflow end connected to the second passage (11b).
It has a first opening degree adjusting mechanism (14) for adjusting the opening degree of the first bypass flow path (13).

In the first aspect, the air flowing through the first bypass passage (13) joins the air in the second passage (11b). By adjusting the opening degree of the first bypass flow path (13), the temperature and humidity of the air in the second passage (11b) cooled by the cooling unit (21) can be adjusted. As a result, the temperature difference from the air temperature of the air inlet (7) of the suction port (6) can be reduced, and the humidity of the cultivation room (S) can be adjusted and the temperature can be varied. It can be suppressed.

The second aspect is, in the first aspect,
The air flowing through the first passage (11a) and the air flowing through the second passage (11b) are arranged on the downstream side of the inflow end of the first bypass flow path (13) in the first passage (11a). It has a heat exchange unit (16) that exchanges heat.

In the second aspect, the heat exchange unit (16) exchanges heat between the air flowing through the first passage (11a) and the air flowing through the second passage (11b). Since the air in the second passage (11b) is cooled by the cooling unit (21), the air flowing through the first passage (11a) can be cooled by the heat exchange unit (16), and the air in the second passage (11b) can be cooled. Can be heated.

The third aspect is, in the second aspect,
In the air passage (11), the inflow end is connected between the heat exchange portion (16) and the cooling portion (21) in the first passage (11a), and the outflow end is the second passage (the second passage (11a). 11b) includes a second bypass flow path (17) connected to the downstream side of the heat exchange section (16).
It has a second opening degree adjusting mechanism (18) for adjusting the opening degree of the second bypass flow path (17).

In the third aspect, a part of the air in the first passage (11a) that has passed through the heat exchange portion (16) flows through the second bypass flow path (17). The air in the second bypass flow path (17) joins the air in the second passage (11b) that has passed through the cooling unit (21) and the heat exchange unit (16). Therefore, by adjusting the opening degree of the second bypass flow path (17), the temperature and humidity of the air in the second passage (11b) can be adjusted, and the temperature and humidity of the blown air can also be adjusted.

The fourth aspect is in any one of the first to third aspects.
It has an air conditioning unit (20) including a first fan (22) for transporting air to the cooling unit (21) and the cooling unit (21).

In the fourth aspect, the general-purpose air conditioning unit (20) can be used for the present air conditioning system (1).

The fifth aspect is the fourth aspect in the fourth aspect.
It has a second fan (15) arranged downstream of the outflow end of the first bypass flow path (13) in the second passage (11b).

In the fifth aspect, since the second fan (15) is arranged on the downstream side of the outflow end of the first bypass flow path (13), the size of the first fan (22) of the air conditioning unit (20) is increased. The existing air conditioning unit (20) can be used as it is without doing anything. This makes it possible to easily configure this air conditioning system.

The sixth aspect is the fourth aspect.
A temperature / humidity control unit (10) including the first passage (11a), the second passage (11b), the first bypass flow path (13), and the first opening adjustment mechanism (14) is provided.
The temperature / humidity control unit (10)
Includes a second fan (15) located in the first bypass flow path (13) or downstream of the outflow end of the first bypass flow path (13) in the second passage (11b). ,
It is configured as a separate body from the air conditioning unit (20).

In the sixth aspect, the present air conditioning system can be easily configured by combining the air conditioning unit (20) and the temperature / humidity control unit (10).

The seventh aspect is in any one of the first to sixth aspects.
Air is supplied from the outlet (7) to the cultivation room (S) so that air flows in the lateral direction of the cultivation room (S) or in the lateral direction of the cultivation shelf (W) of the cultivation room (S). do.

In the seventh aspect, the distance through which the air passes through the cultivation room (S) is shorter when the air is flowed in the short direction than when the air is flowed in the longitudinal direction of the cultivation room (S) or the cultivation shelf (W). Become. As a result, even if the wind speed is suppressed to a certain height, the temperature change of the air passing through the cultivation room (S) or the cultivation shelf (W) can be suppressed. As a result, the temperature of the blown air can be set so that the temperature difference between the blown air and the sucked air is reduced, and the temperature variation in the cultivation room (S) or the cultivation shelf (W) can be suppressed.

FIG. 1 is a schematic diagram of a cultivation room and a cultivation shelf to which the air conditioning system according to the embodiment is applied. FIG. 2 is a diagram showing a configuration of an air conditioning system. FIG. 3 is a diagram showing the air flow by the air conditioning system. FIG. 4 is a diagram showing a configuration of an air conditioning system according to a modified example. FIG. 5 is a diagram showing the air flow by the air conditioning system. FIG. 6 is a diagram showing a configuration of an air conditioning system according to another embodiment. FIG. 7 is a diagram showing a configuration of an air conditioning system according to another embodiment. FIG. 8 is a diagram showing a configuration of an air conditioning system according to another embodiment.

Hereinafter, this embodiment will be described with reference to the drawings. It should be noted that the following embodiments are essentially preferred examples and are not intended to limit the scope of the present invention, its applications, or its uses.

<< Embodiment >>
-Composition of cultivation room-
As shown in FIG. 1, the air-conditioning system (1) of the first embodiment air-conditions the inside of the cultivation room (S) of the plant factory. The cultivation room (S) is a rectangular parallelepiped. A cultivation shelf (W) is arranged in the cultivation room (S). The cultivation shelf (W) is a rectangular parallelepiped. The cultivation shelf (W) has a plurality of cultivation containers arranged side by side in the vertical direction. The cultivation shelf (W) is arranged along the longitudinal direction of the cultivation room (S).

An air supply port (5) and a return air port (4) are provided on the wall surface of the cultivation room (S). Specifically, the air supply port (5) and the return air port (4) are provided on the wall surfaces of the cultivation room (S) facing each other in the lateral direction. The air supply port (5) and the return air port (4) are formed over the entire wall surface of each. The air in the cultivation room (S) is sucked into the return air port (4) by the air conditioning system (1). The sucked air is air-conditioned by the air-conditioning system (1) and is supplied to the cultivation room (S) again from the air supply port (5).

-Air conditioning system configuration-
As shown in FIG. 2, the air conditioning system (1) has an air passage (11), an air conditioning unit (20), a heat exchanger (16), and a first bypass pipe (13).

<Air passage>
The air passage (11) has a first pipe (11a) and a second pipe (11b). The first pipe (11a) is the first passage (11a) of the present disclosure. A suction port (6) is formed at one end of the first pipe (11a). The suction port (6) communicates with the return air port (4). The air in the cultivation room (S) is sucked into the suction port (6) through the return air port (4). The other end of the first pipe (11a) is connected to the air conditioning unit (20). The first pipe (11a) sends the air flowing into the suction port (6) to the air conditioning unit (20).

The second pipe (11b) is the second passage (11b) of the present disclosure. One end of the second pipe (11b) is connected to the air conditioning unit (20). An outlet (7) is formed at the other end of the second pipe (11b). The second pipe (11b) sends the air that has passed through the air conditioning unit (20) to the outlet (7). The air outlet (7) communicates with the air supply port (5). The air outlet (7) blows air into the cultivation room (S) through the air supply port (5).

An auxiliary fan (15) is arranged in the second pipe (11b). The auxiliary fan (15) is the second fan (15) of the present disclosure. Specifically, the auxiliary fan (15) is arranged on the downstream side of the outflow end of the first bypass pipe (13) described later in the second pipe (11b). The auxiliary fan (15) conveys the air in the air passage (11) to the outlet (7).

<Air conditioning unit>
The air conditioning unit (20) is arranged in the air passage (11). The air conditioning unit (20) cools and dehumidifies the air in the air passage (11). The air conditioning unit (20) has a fan (22) and an evaporator (21). The fan (22) is the first fan (22) of the present disclosure. The fan (22) carries air to the evaporator (21). The evaporator (21) is the cooling unit (21) of the present disclosure. The evaporator (21) can cool the air carried by the fan (22) to below the dew point temperature. The evaporator (21) dehumidifies the air flowing into the air conditioning unit (20).

The evaporator (21) is connected to a refrigerant circuit (not shown). The refrigerant circuit includes a compressor, an evaporator (21), a radiator, an expansion valve, and a refrigerant pipe connecting them. The refrigerant circuit has a refrigerant filled therein. The refrigerant circuit performs a refrigeration cycle in which heat is absorbed from the air by an evaporator and radiated to the air by a radiator.

<Expand heat exchanger>
The sensible heat exchanger (16) exchanges heat between the air flowing through the first pipe (11a) and the air flowing through the second pipe (11b). The sensible heat exchanger (16) is the heat exchanger (16) of the present disclosure. The sensible heat exchanger (16) is arranged on the downstream side of the inflow end of the first bypass pipe (13) described later in the first pipe (11a). The sensible heat exchanger (16) is relatively free to flow to the room temperature air flowing from the suction port (6) to the first pipe (11a) and to the second pipe (11b) cooled by the air conditioning unit (20). It exchanges heat with cold air. The sensible heat exchanger (16) precools the air flowing through the first pipe (11a) before flowing into the air conditioning unit (20). The air in the second pipe (11b) cooled by the air conditioning unit (20) is heated by the sensible heat exchanger (16).

<1st bypass pipe>
The first bypass pipe (13) is the first bypass flow path (13) of the present disclosure. The first bypass pipe (13) bypasses the air conditioning unit (20) and the sensible heat exchanger (16). Specifically, the inflow end of the first bypass pipe (13) is connected to the upstream side of the sensible heat exchanger (16) in the first pipe (11a). The outflow end of the first bypass pipe (13) is connected to the downstream side of the manifest heat exchanger (16) in the second pipe (11b).

A first damper (14) is connected to the first bypass pipe (13). The first damper (14) is the first opening degree adjusting mechanism (14) of the present disclosure. The first damper (14) adjusts the opening degree of the first bypass pipe (13). The first damper (14) regulates the flow rate of air flowing through the first bypass pipe (13).

<Sensor>
The air conditioning system (1) has a temperature sensor (8a-8e) and a humidity sensor (9a-9e). The temperature sensors (8a to 8e) are the temperature of the air at the suction port (6), the temperature of the air flowing into the air conditioning unit (20), the temperature of the air flowing out from the air conditioning unit (20), and the second pipe (11b). The temperature of the air at the outflow end of the sensible heat exchanger (16) and the temperature of the air at the outlet (7) are detected. For example, the temperature sensors (8a-8e) have first to fifth temperature sensors (8a-8e). The sensor unit of the first temperature sensor (8a) is provided at the suction port (6). The sensor unit of the second temperature sensor (8b) is provided at the inlet (not shown) of the air conditioning unit (20). The sensor unit of the third temperature sensor (8c) is provided at the outlet (not shown) of the air conditioning unit (20). The sensor unit of the fourth temperature sensor (8d) is provided at the outflow end of the sensible heat exchanger (16) in the second tube (11b). The sensor unit of the fifth temperature sensor (8e) is provided at the outlet (7).

The humidity sensors (9a-9e) are the humidity of the air at the suction port (6), the humidity of the air flowing into the air conditioning unit (20), the humidity of the air flowing out from the air conditioning unit (20), and the second pipe (11b). The humidity of the air at the outflow end of the sensible heat exchanger (16) and the humidity of the air at the outlet (7) are detected. For example, the humidity sensor (9a-9e) has a first-fifth humidity sensor (9a-9e). The sensor unit of the first humidity sensor (9a) is provided at the suction port (6). The sensor unit of the second humidity sensor (9b) is provided at the inlet (not shown) of the air conditioning unit (20). The sensor unit of the third humidity sensor (9c) is provided at the outlet (not shown) of the air conditioning unit (20). The sensor unit of the fourth humidity sensor (9d) is provided at the outflow end of the sensible heat exchanger (16) in the second pipe (11b). The sensor unit of the fifth humidity sensor (9e) is provided at the outlet (7).

<Control unit>
The air conditioning system (1) has a control unit (30). The control unit (30) includes a microcomputer mounted on a control board and a memory device (specifically, a semiconductor memory) for storing software for operating the microcomputer.

The control unit (30) is based on the temperature and humidity information transmitted from various sensors (8a to 8e, 9a to 9e), and the refrigerant circuit of the air conditioning unit (20), the fan (22), and the first damper (1st damper). 14) and the auxiliary fan (15) are controlled. The control unit (30) controls various devices of the air conditioning system (1) so that the temperature and humidity of the air at the outlet (7) become the preset temperature and humidity.

<Operation of air conditioning system>
Next, the operation of the air conditioning system (1) will be described with reference to FIG. The temperatures and humidity shown below are examples. In the following, the preset temperature and humidity of the air at the outlet (7) will be referred to as the set temperature and the set humidity, respectively.

It is assumed that the temperature and humidity of the air at the suction port (6) are 25 ° C. and 80% RH (RH indicates relative humidity). At this time, it is assumed that the set temperature and the set humidity of the blown air are set to 22 ° C. and 65% RH. The air flowing into the first pipe (11a) from the suction port (6) is heat exchanged by the sensible heat exchanger (16). The temperature and humidity of the air that has been heat exchanged and flows into the air conditioning unit (20) is 15 ° C. and 100% RH.

The control unit (30) controls the refrigerant circuit so as to cool and dehumidify the air in the air conditioning unit (20). Specifically, the control unit (30) adjusts the evaporation temperature of the refrigerant in the evaporator (21) by controlling the compressor and the expansion valve of the refrigerant circuit. The air cooled and dehumidified by the evaporator (21) flows out from the air conditioning unit (20) to the second pipe (11b). The temperature and humidity of the air at this time are 10 ° C. and 100% RH.

The air in the second tube (11b) flows into the sensible heat exchanger (16). In the sensible heat exchanger (16), the air in the second tube (11b) is heated by exchanging heat with the air in the first tube (11a). The temperature and humidity of the air in the second tube flowing out of the heat exchanger (16) is 20 ° C. and 50% RH.

The air in the first bypass pipe (13) is 25 ° C., 80% RH air flowing in from the suction port (6). The control unit (30) adjusts the opening degree of the first damper (14) so that the air of the second pipe (11b) flowing out from the sensible heat exchanger (16) reaches the set temperature and the set humidity. The air in the second pipe (11b) flowing out of the heat exchanger (16) is mixed with the air in the first bypass pipe (13) to be heated and humidified. The air in the second pipe (11b) mixed with the air in the first bypass pipe (13) is adjusted to the set temperature and the set humidity, and is blown out from the air supply port (5) of the cultivation room (S).

<< Effect of the embodiment >>
The air conditioning system (1) has a first bypass pipe (13) whose inflow end is connected to the upstream side of the evaporator (21) in the first pipe (11a) and whose outflow end is connected to the second pipe (11b). include. The air conditioning system (1) further includes a first damper (14) that adjusts the opening degree of the first bypass pipe (13). The air flowing from the suction port (6) and flowing through the first bypass pipe (13) bypasses the air conditioning unit (20) and joins with the air flowing through the second pipe (11b). Therefore, by adjusting the opening degree of the first damper (14), the temperature and humidity of the air in the second pipe (11b) cooled and dehumidified by the evaporator (21) can be adjusted. Thereby, for example, even if the air is excessively cooled and dehumidified by the evaporator (21), the temperature and humidity of the air at the outlet (7) can be adjusted by controlling the opening degree of the first damper (14). Can be adjusted.

In addition, the temperature and humidity of the air in the second pipe (11b) can be adjusted by mixing the air flowing through the first bypass pipe (13), so that the temperature of the air in the suction port (6) and the air outlet (7) can be adjusted. ) Can reduce the temperature difference from the air temperature. As a result, the temperature variation in the cultivation room (S) can be suppressed.

In addition, even if the dew point temperature of the air in the evaporator (21) is lowered in order to increase the amount of dehumidification, the air cooled by the evaporator (21) can be passed through the first bypass flow path (13). Can be heated by mixing with. Therefore, it is possible to prevent the air at the outlet (7) from becoming relatively low in temperature. As a result, the temperature difference between the temperature of the air at the suction port (6) and the temperature of the air at the outlet (7) can be reduced.

The air conditioning system (1) is arranged downstream from the inflow end of the first bypass pipe (13) in the first pipe (11a), and flows through the air flowing through the first pipe (11a) and the second pipe (11b). It has a manifest heat exchanger (16) that exchanges heat with air. The air flowing through the first pipe (11a) is cooled by exchanging heat with the air flowing through the second pipe (11b) cooled by the sensible heat exchanger (16) and the evaporator (21). Therefore, the air flowing through the first passage (11a) is precooled before flowing into the air conditioning unit (20). As a result, the power consumption of the air conditioning unit (20) can be suppressed.

In addition, even if the dew point temperature of the air in the evaporator (21) is lowered in order to increase the amount of dehumidification, the air flowing through the second pipe (11b) is still the air in the first pipe (11a) flowing in at room temperature. It is heated by exchanging heat with the sensible heat exchanger (16). Therefore, it is possible to suppress the temperature of the blown air from becoming low. Further, as the temperature of the air in the second pipe (11b) rises, the relative humidity of the air in the second pipe (11b) decreases. Therefore, the relative humidity of the blown air can be reduced.

The air conditioning system (1) of the present embodiment has an air conditioning unit (20) including an evaporator (21) and a fan (22). Thereby, the general-purpose air-conditioning unit (20) can be used for the air-conditioning system (1) of the present embodiment.

In the air conditioning system (1) of the present embodiment, the auxiliary fan (15) is arranged on the downstream side of the outflow end of the first bypass pipe (13) in the second pipe (11b). Therefore, since the existing air conditioning unit (20) can be used as it is without increasing the size of the fan (22) of the air conditioning unit (20), the present air conditioning system (1) can be easily configured.

The air conditioning system (1) of the present embodiment supplies air from the outlet (7) to the cultivation room (S) so that air flows in the lateral direction of the cultivation shelf (W) of the cultivation room (S).

Here, in order to reduce the temperature difference between the air supply port (5) and the return air port (4) while suppressing the wind speed of the blowout to a certain height, the air supply port (5) to the return air port (5) is used. It is desirable that the distance to (4) is short. This is because the shorter the distance from the air supply port (5) to the return air port (4), the more the temperature change of the air flowing in the cultivation shelf (W) can be suppressed.

According to the air conditioning system (1) of the present embodiment, by providing the air supply port (5) and the return air port (4) on the wall surface facing each other in the lateral direction, the air blown out from the air supply port (5) can be generated. It can be flowed in the direction of the short side of the cultivation room (S). As a result, the distance through which the air flows is shorter than when the air flows in the longitudinal direction, and as a result, even if the wind speed of the blowout is suppressed to a certain height, the temperature change of the air passing through the cultivation room (S) is suppressed. be able to.

Further, since the air conditioning system (1) includes an auxiliary fan (15) in addition to the fan (22), the air flow rate of the blowout can be increased as compared with the case of only one fan (22). As a result, the opening area of the air supply port (5) can be increased by the amount that the wind speed is suppressed to a certain height, so that the air supply port (5) is larger than the wall surface facing the cultivation room (S) in the longitudinal direction. It can be installed on the wall surface facing the short side with a large area. By providing the air supply port (5) and the return air port (4) on almost the entire wall surface facing each other in the lateral direction, the wind speed of the blowout is suppressed to a certain height and is uniform throughout the cultivation shelf (W). Can be blown to. The temperature of the air supply port (5) can be set so that the temperature difference between the air supply port (5) and the return air port (4) becomes small, and by extension, the temperature in the cultivation room (S) and the cultivation shelf (W). Variation can be suppressed. As a result, it is possible to suppress variations in the quality of individual vegetables.

<< Modification example >>
As shown in FIG. 4, in the modified example air-conditioning system (1), a second bypass pipe (17) is provided in the air-conditioning system (1) of the above embodiment. The second bypass pipe (17) is the second bypass flow path (17) of the present disclosure.

The inflow end of the second bypass pipe (17) is connected between the manifest heat exchanger (16) and the air conditioning unit (20) in the first pipe (11a). The outflow end of the second bypass pipe (17) is connected to the downstream side of the manifest heat exchanger (16) in the second pipe (11b). Strictly speaking, the outflow end of the second bypass pipe (17) is on the downstream side of the sensible heat exchanger (16) in the second pipe (11b) and is connected to the upstream side of the auxiliary fan (15). The air in the first pipe (11a) that has passed through the sensible heat exchanger (16) bypasses the air conditioning unit (20) and the sensible heat exchanger (16) by passing through the second bypass pipe (17). Then, it flows into the second pipe (11b).

A second damper (18) is connected to the second bypass pipe (17). The second damper (18) adjusts the opening degree of the second bypass pipe (17). The second damper (18) is the second opening degree adjusting mechanism (18) of the present disclosure. The second damper (18) is controlled by the control unit (30).

The operation of the air conditioning system (1) of this modification will be described with reference to FIG. The temperatures and humidity shown below are examples. It is assumed that the temperature and humidity of the air sucked from the return port (4) of the cultivation room (S) are 25 ° C. and 80% RH. At this time, it is assumed that the set temperature and the set humidity of the blown air are set to 23 ° C. and 65% RH. The air flowing from the cultivation room (S) to the first pipe (11a) through the suction port (6) is heat exchanged by the microheat exchanger (16). After the heat exchange, the temperature and humidity of the air flowing into the air conditioning unit (20) become 20 ° C. and 100% RH.

The control unit (30) adjusts the evaporation temperature of the refrigerant in the evaporator (21) by controlling the compressor and the expansion valve of the refrigerant circuit. The air cooled and dehumidified by the evaporator (21) flows out from the air conditioning unit (20) to the second pipe (11b). The temperature and humidity of the air at this time are 10 ° C. and 100% RH.

The air in the second tube (11b) flows into the sensible heat exchanger (16). In the sensible heat exchanger (16), the air in the second tube (11b) is heated by exchanging heat with the air in the first tube (11a). It is assumed that the temperature and humidity of the air in the second tube flowing out of the sensible heat exchanger (16) are 20 ° C. and 55% RH.

The control unit (30) uses the first damper (14) and the second damper (18) so that the air in the second pipe (11b) flowing out of the heat exchanger (16) reaches the set temperature and the set humidity. Adjust the opening of at least one of the above. The air in the first bypass pipe (13) is air having the same temperature as the air in the suction port (6) and a humidity of 80% RH. The air in the second bypass pipe (17) is air having the same temperature as the air flowing into the air conditioning unit (20) and a humidity of 100% RH.

The air in the second pipe (11b) flowing out of the heat exchanger (16) is mixed with at least one of the air in the first bypass pipe (13) and the second bypass pipe (17), and is heated and humidified. To.

After the air in the second pipe (11b) is mixed with the air in the first bypass pipe (13), the air supply port (5) of the cultivation room (S) is passed through the outlet (7) by the auxiliary fan (15). ) Is blown out.

According to this modification, a part of the air in the first pipe (11a) that has passed through the sensible heat exchanger (16) passes through the second bypass pipe (17) and passes through the air conditioning unit (20) and the sensible heat exchange. It merges with the air in the second pipe (11b) that has passed through the vessel (16). By adjusting the opening degree of the second bypass pipe (17), the temperature and humidity of the air in the second pipe (11b) that has passed through the sensible heat exchanger (16) can be adjusted.

In addition, by adjusting the opening degree of at least one of the first damper (14) and the second damper (18), the temperature and humidity of the air in the second pipe (11b) that has passed through the sensible heat exchanger (16). Can be adjusted. The temperature and humidity of the air in the first bypass pipe (13) and the air in the second bypass pipe (17) are different from each other. Therefore, by adjusting the air flow rates of the first bypass pipe (13) and the second bypass pipe (17), the control range of the air temperature and humidity of the outlet (7) is expanded, and the outlet (7) is expanded. ) Air temperature and humidity can be adjusted with high accuracy.

<< Other Embodiments >>
In the above-described embodiment and modification, the configuration may be as follows.

The air conditioning system (1) does not have to have a heat exchanger (16).

The heat exchange unit (16) may be any as long as it can exchange heat between the air in the first pipe (11a) and the air in the second pipe (11b).

The air conditioning system (1) does not have to have a refrigerant circuit. In this case, the cooling unit (21) may be composed of a Pelche element.

The auxiliary fan (15) may be arranged in the first bypass tube (13). Specifically, the auxiliary fan (15) may be arranged on the downstream side of the first damper (14) in the first bypass pipe (13).

In the air conditioning system (1), the evaporator (21) and the fan (22) do not have to be unitized. In other words, the air conditioning system (1) does not have an air conditioning unit (20), and the evaporator (21) and the fan (22) may be separately provided in the air conditioning system (1).

The air conditioning system (1) does not have to have an auxiliary fan (15). For example, as shown in FIG. 6, in the air conditioning system (1) of the above embodiment, the fan (22) is arranged on the downstream side of the outflow end of the first bypass pipe (13) in the second pipe (11b). .. In this case, since the air in the air passage (11) is conveyed by one fan (22), it is preferable to set the air volume of the fan (22) to be relatively high.

The air conditioning system (1) may have a plurality of outlets (7). For example, as shown in FIG. 7, in the air conditioning system (1) of the above embodiment, the second pipe (11b) has a branch flow path (11c) that branches into a plurality of branches on the downstream side of the first bypass pipe (13). .. An outlet (7) is provided at the outflow end of each branch flow path (11c). An auxiliary fan (15) is connected to each branch flow path (11c).

The air conditioning system (1) may have a temperature / humidity control unit (10) configured as a separate body from the air conditioning unit (20). For example, as shown in FIG. 8, in the air conditioning system (1) of the above embodiment, the temperature / humidity control unit (10) is the first pipe (11a), the second pipe (11b), the auxiliary fan (15), and the first. It has a bypass tube (13), a first damper (14), and a sensible heat exchanger (16). In the temperature / humidity control unit (10) of the above modification, a second bypass pipe (17) and a second damper (18) are further provided. As a result, the main air conditioning system (1) can be easily configured by combining the air conditioning unit (20) and the temperature / humidity control unit (10).

The auxiliary fan (15) of the temperature / humidity control unit (10) is arranged on the downstream side of the outflow end of the first bypass pipe (13) in the second pipe (11b). When the temperature / humidity control unit (10) has the second bypass pipe (17), the auxiliary fan (15) is located downstream of the outflow end of the first bypass pipe (13) in the second pipe (11b). , Is arranged on the downstream side of the outflow end of the second bypass pipe (17). As a result, the main air conditioning system (1) can be easily configured by incorporating the temperature / humidity control unit (10) into the existing air conditioning unit (20) without increasing the size of the fan (22) of the air conditioning unit (20). can. As a result, it is possible to reduce the labor and cost of constructing the air conditioning system (1).

The auxiliary fan (15) of the temperature / humidity control unit (10) may be arranged in the first bypass pipe (13). Specifically, the auxiliary fan (15) may be arranged on the downstream side of the first damper (14) in the first bypass pipe (13).

The return air port (4) does not have to be formed on the wall surface facing the air supply port (5).

The return port (4) does not have to be formed over the entire wall surface. The return port (4) does not have to be formed on the wall surface.

The air supply port (5) and the return air port (4) may not be provided. In that case, the air in the cultivation room (S) flows into the first pipe (11a) from the suction port (6). In addition, air is supplied to the cultivation room (S) from the outlet (7).

The air supply port (5) and the return air port (4) may be provided on the cultivation shelf (W). In this case, the air supply port (5) and the return air port (4) are arranged on the side surfaces of the cultivation shelf (W) facing the lateral side, respectively.

The air supply port (5) and the return air port (4) may be arranged on the side surface so as to face each other in the longitudinal direction of the cultivation room (S) or the cultivation shelf (W).

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the spirit and scope of the claims. Further, the above embodiments and modifications may be appropriately combined or replaced as long as the functions of the subject of the present disclosure are not impaired. The above-mentioned descriptions of "first" and "second" are used to distinguish the words and phrases to which these descriptions are given, and do not limit the number and order of the words and phrases.

As described above, the present disclosure is useful for air conditioning systems.

S cultivation room W cultivation shelf 6 suction port 7 outlet 10 temperature / humidity control unit 11 air passage 11a first passage
11b 2nd passage
13 First bypass flow path
14 First opening adjustment mechanism
15 Second fan
16 Heat exchange unit
17 Second bypass flow path
18 Second opening adjustment mechanism
20 Air conditioning unit
21 Cooling unit
22 1st fan

Claims (7)

It is an air conditioning system that air-conditions the cultivation room (S).
An air passage (11) that communicates a suction port (6) for sucking air in the cultivation room (S) and an air outlet (7) for blowing air into the cultivation room (S).
It is provided with a cooling unit (21) arranged in the air passage (11) and capable of cooling air below the dew point temperature.
The air passage (11)
The first passage (11a) for sending the air flowing into the suction port (6) to the cooling unit (21),
A second passage (11b) that sends air that has passed through the cooling unit (21) to the outlet (7),
The inflow end includes a first bypass flow path (13) connected to the upstream side of the cooling portion (21) in the first passage (11a) and an outflow end connected to the second passage (11b).
An air conditioning system comprising a first opening degree adjusting mechanism (14) for adjusting the opening degree of the first bypass flow path (13). In the air conditioning system of claim 1, the air flowing through the first passage (11a) and the second passage, which are arranged on the downstream side of the inflow end of the first bypass flow path (13) in the first passage (11a). An air conditioning system characterized by having a heat exchange unit (16) that exchanges heat with the air flowing through (11b). In the air conditioning system of claim 2,
In the air passage (11), the inflow end is connected between the heat exchange portion (16) and the cooling portion (21) in the first passage (11a), and the outflow end is the second passage (the second passage (11a). 11b) includes a second bypass flow path (17) connected to the downstream side of the heat exchange section (16).
An air conditioning system comprising a second opening degree adjusting mechanism (18) for adjusting the opening degree of the second bypass flow path (17). In any one of the air conditioning systems of claims 1 to 3,
An air conditioning system comprising an air conditioning unit (20) including a cooling unit (21) and a first fan (22) for transporting air to the cooling unit (21). In the air conditioning system of claim 4,
An air conditioning system characterized by having a second fan (15) arranged on the downstream side of the outflow end of the first bypass flow path (13) in the second passage (11b). In the air conditioning system of claim 4,
A temperature / humidity control unit (10) including the first passage (11a), the second passage (11b), the first bypass flow path (13), and the first opening adjustment mechanism (14) is provided.
The temperature / humidity control unit (10) is
Includes a second fan (15) located in the first bypass flow path (13) or downstream of the outflow end of the first bypass flow path (13) in the second passage (11b). ,
An air conditioning system characterized by being configured as a separate body from the air conditioning unit (20). In any one of the air conditioning systems of claims 1 to 6,
Air is supplied from the outlet (7) to the cultivation room (S) so that air flows in the lateral direction of the cultivation room (S) or in the lateral direction of the cultivation shelf (W) of the cultivation room (S). An air conditioning system characterized by

Images