JP2018087668A - Air conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system for controlling an indoor air temperature in a thermostatic chamber, while being able to control the indoor air temperature to be a desired temperature even during a defrosting operation.SOLUTION: In the case of switching an operation mode for each of cooling units (20, 40), the cooling units (20, 40) in the process of cooling switching are brought into a cooling switching operation to increase step by step the number of heat exchangers (21-26, 41-46) which function as evaporators and gradually increase the capacity of cooled air to be supplied to a thermostatic chamber (1), and the cooling units (20, 40) in the process of standby switching are brought into a standby switching operation to reduce the number of the heat exchangers (21-26, 41-46) which function as the evaporators by the increment for the cooling units (20, 40) in the process of cooling switching and gradually reduce the capacity of the cooled air to be supplied to the thermostatic chamber (1).SELECTED DRAWING: Figure 3

Description

    The present invention relates to an air conditioning system that supplies cooling air to a temperature-controlled room to control the indoor air temperature of the temperature-controlled room to a desired temperature.

    2. Description of the Related Art Conventionally, there is known an air conditioning system that controls the temperature of room air in a temperature-controlled room to a predetermined temperature by supplying cooled air to a temperature-controlled room such as an environmental test room (see, for example, Patent Document 1 below) ).

    The air conditioning system disclosed in Patent Document 1 includes a direct expansion type cooling unit having a refrigerant circuit, and supplies the air cooled by the evaporator to the test chamber, thereby adjusting the temperature of the test chamber to a desired temperature. Configured to control.

JP 2001-235237 A

    By the way, in the said air conditioning system, the water | moisture content in air adheres to an evaporator and it forms frost, and there exists a possibility that cooling capacity may fall remarkably. Therefore, before the cooling capacity is significantly reduced, it is necessary to perform a defrost operation for heating the evaporator and removing frost attached to the evaporator.

    However, in the defrosting operation, the air around the evaporator is also heated. Therefore, it is necessary to perform the defrosting operation with the supply of air to the test chamber stopped. On the other hand, if the cooling air is not supplied to the test chamber, the temperature of the test chamber rises. That is, during the defrost operation, the room air temperature in the test chamber cannot be maintained at a desired temperature (low temperature). Therefore, in the air conditioning system, the test had to be stopped when performing the defrost operation.

    The present invention has been made in view of the above points, and an object thereof is an air conditioning system that controls the indoor air temperature of a temperature-controlled room, and is capable of controlling the indoor air temperature to a desired temperature even during a defrost operation. Is to provide.

    A first invention is an air conditioning system for controlling a room air temperature of a temperature-controlled room (1) to a desired temperature, the casing (30, 50) connected to the temperature-controlled room (1) and the casing (30, 30). 50) and a plurality of heat exchangers (21 to 26, 41 to 46) connected to the refrigerant circuit (91 to 96), respectively, and the plurality of heat exchangers (21 to 26, 41). ~ 46) function as an evaporator, cooling mode to supply air cooled to the temperature-controlled room (1), and defrost to heat and defrost the plurality of heat exchangers (21-26, 41-46) Two cooling units (20, 40) configured to switch between a standby mode that does not supply air to the temperature-controlled room (1), and each cooling unit (20, 40) The mode is alternately switched to the standby mode, and when one of the two cooling units (20, 40) is in the cooling mode, the other is in the standby mode. Control unit (60) for controlling the operation mode of the two cooling units (20, 40) so that the control unit (60) operates in each cooling unit (20, 40). When switching the mode, the number of the heat exchangers (21 to 26, 41 to 46) functioning as an evaporator is set in the cooling unit (20, 40) during the cooling switching to switch from the standby mode to the cooling mode. The cooling unit (20, 20) that is in the standby switching mode is configured to increase in stages and perform a cooling switching operation for gradually increasing the air volume of the cooling air supplied to the temperature-controlled room (1) to switch from the cooling mode to the standby mode. 40), the number of the heat exchangers (21 to 26, 41 to 46) functioning as an evaporator is decreased by the amount increased by the cooling unit (20, 40) during the cooling switching, and the constant temperature is set. The air volume of the cooling air supplied to the chamber (1) is gradually increased It is configured so as to perform the standby switching operation to reduce.

    In 1st invention, it is an air-conditioning system which controls the indoor air temperature of a temperature-controlled room (1) to desired temperature, Comprising: The casing (30,50) connected to the said temperature-controlled room (1), and this casing (30, 50) and a plurality of heat exchangers (21 to 26, 41 to 46) connected to the refrigerant circuit (91 to 96), respectively, and the plurality of heat exchangers (21 to 26, 41). ~ 46) function as an evaporator, cooling mode to supply air cooled to the temperature-controlled room (1), and defrost to heat and defrost the plurality of heat exchangers (21-26, 41-46) Two cooling units (20, 40) configured to switch between a standby mode that does not supply air to the temperature-controlled room (1), and each cooling unit (20, 40) The mode is switched alternately to the standby mode, and when one of the two cooling units (20, 40) is in the cooling mode, the other is A control unit (60) for controlling the operation mode of the two cooling units (20, 40) so as to be in the machine mode, and the control unit (60) is provided in each cooling unit (20, 40). When switching the operation mode, the number of the heat exchangers (21 to 26, 41 to 46) functioning as an evaporator is included in the cooling unit (20, 40) during the cooling switching to switch from the standby mode to the cooling mode. The cooling unit (20) that is in standby switching to switch from the cooling mode to the standby mode is performed by performing a cooling switching operation that gradually increases the amount of cooling air supplied to the temperature-controlled room (1). , 40), the number of the heat exchangers (21-26, 41-46) functioning as an evaporator is decreased by the amount increased by the cooling unit (20, 40) during the cooling switching, and Gradually reduce the volume of cooling air supplied to the temperature-controlled room (1) And it is configured to perform the standby switching operation to reduce the.

    In the first invention, in one of the two cooling units (20, 40), in the temperature-controlled room (1) including a defrost operation for heating and defrosting the plurality of heat exchangers (21-26, 41-46). When the standby mode in which no air is supplied is entered, the other is in the cooling mode in which the plurality of heat exchangers (21 to 26, 41 to 46) function as evaporators to supply cooled air to the temperature-controlled room (1). It is configured as follows. Further, each cooling unit (20, 40) is configured to switch between the cooling mode and the standby mode alternately. In other words, one of the two cooling units (20, 40) always supplies cooled air to the temperature-controlled room (1) with multiple heat exchangers (21-26, 41-46) functioning as evaporators. It becomes the cooling mode to be

    In the first invention, when the operation mode is switched in each cooling unit (20, 40), in the cooling unit (20, 40) during the cooling switching to switch from the standby mode to the cooling mode, the heat exchange functioning as an evaporator. In the cooling units (20, 40) that are in standby switching to switch from the cooling mode to the standby mode, the heat exchanger (21, 26) that functions as an evaporator .., 26, 41 to 46) are decreased by the amount increased by the cooling units (20, 40) during the cooling switching. Thereby, in the cooling unit (20, 40) during the cooling switching, the cooling capacity for cooling the air increases stepwise, while in the cooling unit (20, 40) during the standby switching, the cooling capacity for cooling the air is Decrease by the amount of increase in the cooling unit (20, 40) during cooling switching.

    In the first aspect of the invention, the cooling unit (20, 40) during the cooling switching gradually increases the air volume of the cooling air supplied to the temperature-controlled room (1), while the cooling unit (20, 40) during the standby switching. ) Is configured to gradually reduce the amount of cooling air supplied to the temperature-controlled room (1). As a result, the cooling air supplied to the temperature-controlled room (1) in the cooling switching unit (20, 40) in which the cooling capacity is gradually increased as the cooling capacity of the two cooling units (20, 40) increases or decreases in stages. In the cooling unit (20,40) during standby switching where the airflow of the air gradually increases (proportional) and the cooling capacity decreases stepwise, the airflow of the cooling air supplied to the temperature-controlled room (1) gradually (proportional) To) decrease.

    As described above, in the first invention, when the operation mode is switched in the two cooling units (20, 40), the cooling capacity and the air supply amount are not switched to one breath but the one cooling unit (20, 40). Is gradually increased, and in the other cooling unit (40, 20), the switching operation is performed slowly by reducing the amount by the amount increased by one cooling unit (20, 40). Therefore, the temperature of the cooling air supplied to the temperature-controlled room (1) and the air supply amount do not fluctuate greatly by the switching operation.

    In a second aspect based on the first aspect, the control unit (60) switches the cooling mode (20, 40) in the cooling switching unit (20, 40) when switching the operation mode in each cooling unit (20, 40). The operation of increasing the number of the heat exchangers (21 to 26, 41 to 46) functioning as an evaporator is performed by the heat exchanger (21 to 26) functioning as an evaporator in the cooling unit (20, 40) during the standby switching. 26, 41 to 46) is configured to be performed prior to the operation of reducing the number.

    In the second invention, at the time of switching the operation mode in each cooling unit (20, 40), the heat exchanger (21-26, 41-46) functioning as an evaporator in the cooling unit (20, 40) during the cooling switching. The operation to increase the number of units is configured to be performed before the operation to decrease the number of heat exchangers (21 to 26, 41 to 46) that function as evaporators in the cooling units (20, 40) that are in standby switching. Has been. Thereby, in each refrigerant circuit (91-96) in which the plurality of heat exchangers (21-26, 41-46) of the two cooling units (20, 40) are connected in parallel to each other in pairs. When changing the heat exchanger (21-26, 41-46) functioning as an evaporator, the refrigerant is first circulated through the heat exchanger of one cooling unit (20, 40) where the refrigerant did not flow Then, the circulation of the refrigerant to the heat exchanger of the other cooling unit (40, 20) where the refrigerant has flowed is prevented.

    According to a third invention, in the first or second invention, each of the cooling units (20, 40) is provided with a cooler (27, 47) provided in the casing (30, 50) for cooling air. And the control unit (60), in the standby mode of the cooling units (20, 40), after the defrosting operation, the air in the casing (30, 50) is transferred to the coolers (27, 47) It is configured to perform pre-cooling operation for cooling.

    By the way, each cooling unit (20, 40) has a plurality of heat exchangers (21-26, 41-46), and these heat exchangers (21-26, 41-46) are blower fans (29, 49) together with the casing (30, 50). During the defrost operation, the relatively high-temperature air that has heated the plurality of heat exchangers (21 to 26, 41 to 46) is configured to circulate in the casing (30, 50). For this reason, if the mode is immediately switched to the cooling mode after the defrosting operation is completed, the air in the casing (30, 50) is not immediately cooled. Therefore, the relatively hot air in the casing (30, 50) There is a risk that the temperature of the temperature-controlled room (1) will be increased.

    Therefore, in the third aspect of the invention, in the standby mode of each cooling unit (20, 40), after the defrost operation is completed, a precooling operation is performed in which the air in the casing (30, 50) is cooled by the cooler (27, 47). To do. By this precooling operation, the air in the casing (30, 50) heated and heated during the defrosting operation is cooled by the cooler (27, 47). Since the standby mode is switched to the cooling mode after the pre-cooling operation is finished, the air in the casing (30, 50) is sufficiently cooled, and then the temperature-controlled room (1) of the air in the casing (30, 50) Supply (air supply) to is started.

    In a fourth aspect based on the third aspect, the control unit (60) is configured so that the air in the casing (30, 50) is transferred to the cooler (27, 27) in the cooling unit (20, 40) during the cooling switching. , 47) to perform the auxiliary cooling operation for cooling.

    By the way, in the cooling unit (20, 40) during the cooling switching to switch from the standby mode to the cooling mode, some of the heat exchangers (21-26, 41-41) of the plurality of heat exchangers (21-26, 41-46). 46) functions as an evaporator to cool the air, and the number of heat exchangers (21 to 26, 41 to 46) that cool the air increases with time, so the ability to cool the air also Increasing over time. However, since the cooling capacity of the heat exchangers (21 to 26, 41 to 46) where the refrigerant has just started to flow is low, the cooling capacity of the cooling units (20, 40) during the cooling switching is the same as the cooling mode before the standby switching. It becomes lower than the cooling capacity of the cooling unit (20, 40) that has been executed.

    Therefore, in the fourth invention, in the cooling unit (20, 40) during the cooling switching, some of the heat exchangers (21-26, 41-46) (21-26, 41-46). ), In addition to cooling the air, an auxiliary cooling operation for cooling the air was performed using the coolers (27, 47) used in the precooling operation. Thereby, the cooling capacity of the cooling unit (20, 40) during the cooling switching is not lowered as compared with the cooling capacity of the cooling unit (20, 40) that has been executing the cooling mode before the standby switching.

    According to a fifth invention, in any one of the first to fourth inventions, the refrigerant circuit (91 to 96) includes the heat exchanger (21 to 26, 41) included in each of the cooling units (20, 40). To 46), and the plurality of heat exchangers (21 to 26, 41 to 46) of the two cooling units (20, 40) correspond to the refrigerant circuit (91 ~ 96) are connected in parallel to each other.

    In the fifth invention, the plurality of heat exchangers (21 to 26, 41 to 46) of the two cooling units (20, 40) are respectively connected to the corresponding refrigerant circuits (91 to 96) in pairs. Since it is connected in parallel, it functions as an evaporator in the two corresponding heat exchangers of the two cooling units (20, 40) simply by changing the refrigerant flow path in each refrigerant circuit (91-96). The heat exchanger is changed.

    According to the first invention, the cooling unit capable of executing the cooling mode in which the plurality of heat exchangers (21 to 26, 41 to 46) function as an evaporator and supplies the cooled air to the temperature-controlled room (1). Two are provided, and when one is in a standby mode in which air is not supplied to the temperature-controlled room (1) including the defrost operation, the other is in a cooling mode. According to such a configuration, any one of the two cooling units (20, 40) always uses a plurality of heat exchangers (21-26, 41-46) as evaporators to cool the cooled air. Since the cooling mode is to be supplied to the room (1), even if one cooling unit (20, 40) is in the defrosting operation, the other cooling unit (40, 20) will cause the room air in the temperature-controlled room (1) The temperature can be controlled to a desired temperature.

    According to the first aspect of the invention, when the cooling mode (20, 40) is switched from the standby mode to the cooling mode when the operation mode is switched in each cooling unit (20, 40), the cooling capacity (20, 40) during cooling switching is used to cool the air. The cooling unit (20, 40) during standby switching is configured so that the cooling capacity for cooling the air decreases by the amount increased by the cooling unit (20, 40) during cooling switching. doing. In addition, the cooling air supplied to the temperature-controlled room (1) in the cooling unit (20, 40) in the cooling switching mode in which the cooling capacity increases stepwise as the cooling capacity of the two cooling units (20, 40) increases or decreases. In the cooling unit (20,40) during standby switching where the airflow of the air gradually increases (proportional) and the cooling capacity decreases stepwise, the airflow of the cooling air supplied to the temperature-controlled room (1) gradually (proportional) To be reduced). In this way, when switching between operation modes in the two cooling units (20, 40), instead of switching to one breath, the cooling capacity and the air supply amount are gradually increased in one cooling unit (20, 40), In the other cooling unit (40, 20), the switching operation is gradually performed by reducing the amount of increase by the one cooling unit (20, 40). Thereby, the temperature and the air supply amount of the cooling air supplied to the temperature-controlled room (1) are not greatly changed by the switching operation. Accordingly, even when the operation mode is switched, the indoor air temperature of the temperature-controlled room (1) can be stabilized at a desired temperature.

    Further, according to the second invention, at the time of switching the operation mode in each cooling unit (20, 40), the heat exchangers (21 to 26, 26) functioning as an evaporator in the cooling unit (20, 40) during the cooling switching. The operation to increase the number of units 41 to 46) is performed before the operation to decrease the number of heat exchangers (21 to 26, 41 to 46) that function as evaporators in the cooling units (20, 40) that are in standby switching. It was decided that it would be configured. That is, in each refrigerant circuit (91-96) in which a plurality of heat exchangers (21-26, 41-46) of two cooling units (20, 40) are connected in parallel to each other in pairs, When changing the heat exchanger (21-26, 41-46) functioning as an evaporator, the refrigerant was first circulated through the heat exchanger of one cooling unit (20, 40) where the refrigerant did not flow Therefore, the circulation of the refrigerant to the heat exchanger of the other cooling unit (40, 20) in which the refrigerant was flowing was prevented. Thereby, the heat exchanger (21-26, 41-46) which functions smoothly as an evaporator can be changed, without stopping the circulation of the refrigerant in each refrigerant circuit (91-96).

    Further, according to the third invention, in the standby mode of each cooling unit (20, 40), after the defrost operation is completed, the precooling is performed to cool the air in the casing (30, 50) with the cooler (27, 47). We are going to do the operation. By this precooling operation, the air in the casing (30, 50) heated and heated during the defrosting operation is cooled by the cooler (27, 47). Since the standby mode is switched to the cooling mode after the pre-cooling operation is finished, the air in the casing (30, 50) is sufficiently cooled, and then the temperature-controlled room (1) of the air in the casing (30, 50) Supply (air supply) to is started. Accordingly, during the cooling switching operation or during the execution of the cooling mode, relatively high temperature air remains in the casing (30, 50), and this high temperature air is supplied to the temperature-controlled room (1). The room temperature of the temperature-controlled room (1) can be stably controlled to a desired temperature without increasing the air temperature.

    Moreover, according to 4th invention, in the cooling unit (20,40) in cooling switching, some heat exchangers (21-26,41) of several heat exchangers (21-26,41-46). ~ 46) In addition to cooling the air, an auxiliary cooling operation for cooling the air was performed using the coolers (27, 47) used in the precooling operation. As a result, in the cooling unit (20, 40) during the cooling switching in which the cooling capacity tends to be lower than that of the cooling unit (20, 40) executing the cooling mode before the standby switching, the cooler (27, By cooling the air supplementarily in 47), it is possible to avoid a decrease in the cooling capacity due to the switching operation.

    According to the fifth invention, the plurality of heat exchangers (21 to 26, 41 to 46) of the two cooling units (20, 40) correspond to the refrigerant circuits (91 to 96) are connected in parallel to each other, so that the evaporation is performed in the two corresponding heat exchangers of the two cooling units (20, 40) simply by changing the refrigerant flow path in each refrigerant circuit (91 to 96). The heat exchanger that functions as a heat exchanger can be changed. Therefore, the operation mode of the two cooling units (20, 40) can be easily changed. In addition, since the number of devices in the air conditioning system (10) can be reduced by sharing the refrigerant circuit (91 to 96) in the two cooling units (20, 40), the manufacturing cost can be reduced and the system size can be reduced. Can be achieved.

FIG. 1 is a schematic configuration diagram of an air conditioning system according to an embodiment of the present invention, and shows the air flow when the first cooling unit is in the cooling mode and the second cooling unit is in the standby mode. FIG. 2 is a piping diagram showing the configuration of the refrigerant circuit to which the corresponding heat exchangers of the two cooling units of the air conditioning system according to the embodiment of the present invention are connected. FIG. 3A is a time chart for explaining the transition of the operation mode in the first cooling unit, and FIG. 3B is a time chart for explaining the transition of the operation mode in the second cooling unit. is there. FIG. 4 is a schematic configuration diagram of the air conditioning system according to the embodiment of the present invention, and shows the air flow when the first cooling unit is in the standby mode and the second cooling unit is in the cooling mode. FIG. 5 is a schematic configuration diagram of the air conditioning system according to the embodiment of the present invention, and shows an air flow when the operation mode of the first and second cooling units is switched.

    Hereinafter, an air conditioning system according to an embodiment of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1 of the Invention
As shown in FIG. 1, the air conditioning system (10) is provided in a temperature-controlled room (1) composed of an environmental test room for testing the durability and performance of the product (100) under predetermined environmental conditions. By supplying cooled cooling air to the indoor space (S1) of the chamber (1), the air temperature of the indoor space (S1) of the temperature-controlled room (1) is controlled to a predetermined temperature. In the first embodiment, an outdoor unit of an air conditioner is installed as a product (100) in the indoor space (S1) of the temperature-controlled room (1). Further, in the first embodiment, in order to test the durability and performance of the air conditioner with the indoor space (S1) of the temperature-controlled room (1) in an environment of low outside air and high humidity, a humidifier ( 6) is provided.

    First and second air supply ports (4a, 4b) and first and second return air ports (5a, 5b) are formed on the side wall of the temperature-controlled room (1). The first and second air supply ports (4a, 4b) are formed in the middle in the vertical direction of the side wall, and the first and second return air ports (5a, 5b) are formed in the upper part of the side wall. In FIG. 1, the first air inlet (4a) and the second air inlet (4b) are shown to have different heights, but are actually formed at the same height position. . Further, the first return air port (5a) and the second return air port (5b) are also shown in FIG. 1 so as to have different heights, but are actually formed at the same height position.

    In addition, a part of the indoor space (S1) of the temperature-controlled room (1) including the first and second air supply ports (4a, 4b) is covered with the partition wall (2), and the air inflow space (S10) It is configured. The upper end of the inflow space (S10) is closed by a ceiling plate provided below the first and second return air ports (5a, 5b). The partition wall (2) is formed with an air outlet (2a) at the lower portion for guiding the air in the inflow space (S10) to the indoor space (S1). The inflow space (S10) is provided with a partition wall (3), and the inflow space (S10) is introduced into the first and second air supply ports (4a, 4b) by the partition wall (3). It is partitioned into a space (S11) and a mixing space (S12) on the outlet (2a) side. The partition wall (3) is formed with a communication port (3a) for communicating the introduction space (S11) and the mixing space (S12).

    With such a configuration, the cooling air supplied to the introduction space (S11) of the inflow space (S10) via the first and second air supply ports (4a, 4b) is separated from the introduction space (S11). By passing through one communication port (3a) formed in (3) and flowing into the mixing space (S12), they are mixed in the mixing space (S12). And it blows out toward the vicinity in which the apparatus (100) for a test of indoor space (S1) was installed through the blower outlet (2a). The humidifier (6) is installed in the mixing space (S12).

-Overall configuration of air conditioning system-
The air conditioning system (10) includes first and second cooling units (20, 40), first to seventh heat source units (81 to 87), and a controller (60). Although details will be described later, each of the first and second cooling units (20, 40) has seven heat exchangers (21 to 27, 41 to 47), and each of the cooling units (20, 40) has 7 Two heat exchangers (21 to 27, 41 to 47) are connected to the heat source circuits of the corresponding heat source units (81 to 87) in pairs, respectively, and perform first to first refrigeration cycles that perform a vapor compression refrigeration cycle. 7 refrigerant circuit (91-97) is comprised. That is, in the air conditioning system (10), the seven heat exchangers (21-27, 41-47) of the first and second cooling units (20, 40) and the heat source units (81-87) are connected. 1 to 7 refrigerant circuits (91 to 97).

<Cooling unit>
The first and second cooling units (20, 40) are similarly configured. The first and second cooling units (20, 40) include a casing (30, 50), first to seventh heat exchangers (21 to 27, 41 to 47), a heater (28, 48), Blower fan (29,49), air supply duct (31,51), return air duct (32,52), bypass duct (33,53), air supply damper (34,54), and bypass damper (35, 55).

    The casing (30, 50) includes a main body (30a, 50a), an inflow portion (30b, 50b), and an outflow portion (30c, 50c). The main body part (30a, 50a), the inflow part (30b, 50b), and the outflow part (30c, 50c) are all formed in a box shape, and one side in the longitudinal direction of the main body part (30a, 50a) (FIG. 1). In FIG. 1, an inflow portion (30b, 50b) is formed on the left side, and an outflow portion (30c, 50c) is formed on the other side in the longitudinal direction of the main body portion (30a, 50a) (right side in FIG. 1).

    The main body (30a, 50a) is formed in a horizontally long shape. The main body (30a, 50a) is connected to the inflow part (30b, 50b) at one end in the longitudinal direction so that air flows from the inflow part (30b, 50b). The main body (30a, 50a) is connected to the outflow portion (30c, 50c) at the other end in the longitudinal direction so that air flows out to the outflow portion (30c, 50c). Inside the main body (30a, 50a), the first to seventh heat exchangers (21-27, 41-47), the heater (28, 48) and the blower fan (29, 49) are accommodated, They are provided in the above order from one side in the longitudinal direction to the other side.

    The inflow part (30b, 50b) is formed vertically long, the return air port (32, 52) is connected to the upper surface, and the bypass duct (33, 53) is connected to the upper side A port is formed. The inflow portion (30b, 50b) communicates with one end portion (left end portion in FIG. 1) in the longitudinal direction of the main body portion (30a, 50a) at the lower portion.

    The outflow portion (30c, 50c) is provided such that one end portion (left end portion in FIG. 1) communicates with the other end portion (right end portion in FIG. 1) in the longitudinal direction of the main body portion (30a, 50a). The outflow part (30c, 50c) is formed with an air supply port connected to the air supply duct (31, 51) on the side surface and a bypass port connected to the bypass duct (33, 53) on the upper surface. ing.

    With such a configuration, in the casing (30, 50), the air introduced into the upper part of the inflow part (30b, 50b) flows downward, and at the lower part of the inflow part (30b, 50b), the main body part (30a, 50b) 50a), flows from one side in the longitudinal direction of the main body portion (30a, 50a) to the other side, and flows out through the outflow portion (30c, 50c).

    The first to seventh heat exchangers (21 to 27, 41 to 47) are arranged in a line in the width direction (vertical direction in FIG. 1) of the main body portion (30a, 50a), and from the inflow portion (30b, 50b). The air that has flowed into the main body (30a, 50a) is provided so as to flow into each heat exchanger (21-27, 41-47). The first to seventh heat exchangers (21 to 27, 41 to 47) are connected to the corresponding first to seventh refrigerant circuits (91 to 97), respectively. Details of the first to seventh refrigerant circuits (91 to 97) will be described later. Each heat exchanger (21-27, 41-47) is comprised by the fin and tube type heat exchanger, and heat-exchanges the refrigerant | coolant which flows through the inside of the tube, and the air which passes the exterior. In the first embodiment, in each cooling unit (20, 40), the first to sixth heat exchangers (21 to 26, 41 to 46) are for a cooling mode for cooling air in a cooling mode to be described later. The heat exchanger is configured, and the seventh heat exchanger (27, 47) is a cooler for precooling operation that cools the air in each casing (30, 50) in a standby mode to be described later.

    In the first embodiment, the heater (28, 48) is configured by an electric heater, and heats the passing air when energized.

    The blower fan (29, 49) sucks air from the inflow part (30b, 50b) and blows out air to the outflow part (30c, 50c) in the main body part (30a, 50a), and the inside of the casing (30, 50) , An air flow that flows from the inflow portion (30b, 50b) to the outflow portion (30c, 50c) via the main body portion (30a, 50a) is formed.

    One end of the air supply duct (31, 51) is connected to the air supply port formed in the outflow part (30c, 50c) of the casing (30, 50), and the other end is connected to the side wall of the temperature-controlled room (1). It is connected to the formed first and second air supply ports (4a, 4b). Specifically, the air supply duct (31) of the first cooling unit (20) includes the air supply port of the outflow part (30c) of the casing (30) and the first air supply port (4a) of the temperature-controlled room (1). The air supply duct (51) of the second cooling unit (40) is connected to the air supply port of the outflow part (50c) of the casing (50) and the second air supply port (4b) of the temperature-controlled room (1). And connected.

    One end of the return air duct (32, 52) is connected to the first and second return air ports (5a, 5b) formed on the side wall of the temperature-controlled room (1), and the other end is connected to the casing (30, 50). ) Is connected to a return air port formed in the inflow portion (30b, 50b). Specifically, the return air duct (32) of the first cooling unit (20) is connected to the first return air port (5a) of the temperature-controlled room (1) and the return air port of the inlet (30b) of the casing (30). The return air duct (52) of the second cooling unit (40) is connected to the second return air port (5b) of the temperature-controlled room (1) and the return air port of the inlet (50b) of the casing (50). And connected.

    One end of the bypass duct (33, 53) is connected to a bypass port formed in the outflow part (30c, 50c) of the casing (30, 50), and the other end is an inflow part of the casing (30, 50) ( 30b, 50b) is connected to the bypass port formed. That is, the bypass duct (33, 53) connects the outflow part (30c, 50c) and the inflow part (30b, 50b) of the casing (30, 50).

    The air supply damper (34, 54) is a damper whose opening degree can be adjusted. The air supply damper (34, 54) is provided in the air supply duct (31, 51) and adjusts the opening degree of the air supply duct (31, 51), thereby allowing the air supply duct (31, 51) to pass through the air supply duct (31, 51). Adjust the amount of cooling air supplied to the temperature-controlled room (1).

    The bypass damper (35, 55) is a damper whose opening degree can be adjusted. The bypass damper (35, 55) is provided in the bypass duct (33, 53) and adjusts the opening degree of the bypass duct (33, 53), thereby allowing the casing (30, 30) to pass through the bypass duct (33, 53). , 50) is adjusted to return the amount of air returned from the outflow part (30c, 50c) to the inflow part (30b, 50b). When the bypass damper (35,55) is opened, at least part of the air flowing through the casing (30,50) is returned from the outflow part (30c, 50c) to the inflow part (30b, 50b), and the casing (30,50) The air circulates between the inflow part (30b, 50b) and the outflow part (30c, 50c).

    Heating capacity of heaters (28, 48) of first and second cooling units (20, 40), operation of blower fans (29, 49), supply damper (34, 54) and bypass damper (35, 55) ) Is controlled by the controller (60).

<Heat source unit>
The first to seventh heat source units (81 to 87) are similarly configured. The first to seventh heat source units (81 to 87) each have a heat source circuit to which the compressor (71) and the heat source side heat exchanger (72) are connected (see FIG. 2). As described above, since the first to seventh heat source units (81 to 87) are similarly configured, only the first heat source unit (81) is illustrated in FIG. The heat source circuits of the first to seventh heat source units (81 to 87) are connected to the corresponding first to seventh refrigerant circuits (91 to 97), respectively. The first heat source unit (81) is connected to the first refrigerant circuit (91), the second heat source unit (82) is connected to the second refrigerant circuit (92), and the third heat source unit (83) is the third refrigerant circuit. (93), the fourth heat source unit (84) is connected to the fourth refrigerant circuit (94), the fifth heat source unit (85) is connected to the fifth refrigerant circuit (95), and the sixth heat source unit ( 86) is connected to the sixth refrigerant circuit (96), and the seventh heat source unit (87) is connected to the seventh refrigerant circuit (97).

<Refrigerant circuit>
Heat source circuits of the first to seventh heat source units (81 to 87), and first to seventh heat exchangers (21 to 27, 41 to 47) of the corresponding first and second cooling units (20, 40); Are connected by a liquid pipe (76) and a gas pipe (77), respectively, to form seven refrigerant circuits and first to seventh refrigerant circuits (91 to 97). In addition, since the 1st-7th refrigerant circuit (91-97) is comprised similarly, only the 1st refrigerant circuit (91) is illustrated in FIG.

    The heat source circuits of the first to seventh heat source units (81 to 87) are connected to the first to seventh refrigerant circuits (91 to 97) one by one, and the first and second cooling units (20, 40). ) First to seventh heat exchangers (21 to 27, 41 to 47) are connected in parallel, one by one.

    Specifically, the first refrigerant circuit (91) is connected in parallel with the first heat exchanger (21, 41) of the first and second cooling units (20, 40), and the second refrigerant circuit (92). ) Are connected in parallel with the second heat exchangers (22, 42) of the first and second cooling units (20, 40), and the third refrigerant circuit (93) has the first and second cooling units. The third heat exchanger (23, 43) of (20, 40) is connected in parallel, and the fourth refrigerant circuit (94) has a fourth heat exchanger of the first and second cooling units (20, 40). (24,44) are connected in parallel, and the fifth refrigerant circuit (95) is connected in parallel with the fifth heat exchanger (25,45) of the first and second cooling units (20,40), The sixth refrigerant circuit (96) is connected in parallel with the sixth heat exchangers (26, 46) of the first and second cooling units (20, 40), and the seventh refrigerant circuit (97) The seventh heat exchanger (27, 47) of the first and second cooling units (20, 40) is connected in parallel. To have.

    Each liquid pipe (76) and each gas pipe (77) branch into two on the first and second cooling units (20, 40) side, and one branch pipe (76a, 77a) is connected to the first cooling unit (76, 77a). 20) is connected to the corresponding heat exchanger (21 to 27), and the other branch pipe (76b, 77b) is connected to the corresponding heat exchanger (41 to 47) of the second cooling unit (40). Yes. Each liquid pipe (76) is provided with an expansion valve (73) on the heat source circuit side of the branch portion. The branch pipe (76a) on the first cooling unit (20) side of each liquid pipe (76) is connected to a first on-off valve (74) made of an electromagnetic valve, and the second pipe of each liquid pipe (76). A second open / close valve (75) made of an electromagnetic valve is connected to the branch pipe (76b) on the cooling unit (40) side.

    As described above, the heat source circuits of the first to seventh heat source units (81 to 87) are connected to the first to seventh refrigerant circuits (91 to 97) one by one, and the first and second cooling circuits are connected. The first to seventh heat exchangers (21 to 27, 41 to 47) of the units (20, 40) are connected in parallel, one by one. That is, the first to seventh refrigerant circuits corresponding to the first to seventh heat exchangers (21 to 27, 41 to 47) of the first and second cooling units (20, 40) in pairs, respectively. (91-97).

    The operation of the compressor (71) of the first to seventh refrigerant circuits (91 to 97), the opening adjustment of the expansion valve (73), and the opening adjustment of the first and second on-off valves (74, 75) are: It is controlled by the control unit (60).

<Control part>
The control unit (60) alternately switches between the cooling mode and the standby mode in the first and second cooling units (20, 40), and one of the first and second cooling units (20, 40) is in the cooling mode. In this case, the operation mode of the first and second cooling units (20, 40) is controlled so that the other is in the standby mode. Specifically, the control unit (60) includes various control devices of the air conditioning system (10), that is, the heaters (28, 48) and the blower fans (29, 48) of the first and second cooling units (20, 40). 49), the air supply damper (34, 54), the bypass damper (35, 55), the compressor (71), the expansion valve (73), the first and second of the first to seventh refrigerant circuits (91 to 97). The operation mode of the first and second cooling units (20, 40) is controlled by controlling each operation of the on-off valve (74, 75). Specific control operations will be described later.

    In the present embodiment, the control unit (60) includes a microcomputer that controls various control devices of the air conditioning system (10) as disclosed in the present application, and a memory, a hard disk, and the like in which an executable control program is stored. It is out. The control unit (60) is an example of the control unit of the air conditioning system (10), and the detailed structure and algorithm of the control unit (60) are not limited to any hardware that executes the function according to the present invention. It may be a combination with software.

-Driving action-
The control unit (60) controls the operation mode of each cooling unit (20, 40) by controlling the operation of various control devices of the air conditioning system (10). Specifically, the control unit (60) causes each of the cooling units (20, 40) to cool the air cooled by causing the first to sixth heat exchangers (21 to 26, 41 to 46) to function as an evaporator. It includes a cooling mode to supply to the temperature-controlled room (1) and a defrosting operation to defrost by heating the first to sixth heat exchangers (21 to 26, 41 to 46), and supply air to the temperature-controlled room (1) Alternately switch to standby mode. In addition, the control unit (60) includes the first and second cooling units (20, 40) so that when one of the first and second cooling units (20, 40) is in the cooling mode, the other is in the standby mode. 40) Control the operation mode.

    The control unit (60) generates cooling air having a set temperature X (for example, −15 ° C.) of the indoor air of the temperature-controlled room (1) in the cooling mode in each cooling unit (20, 40). The operation of various control devices is controlled so that air is alternately supplied to the temperature-controlled room (1).

    In this way, the control unit (60) alternately executes the cooling mode in the first and second cooling units (20, 40), so that the temperature of the room air in the temperature-controlled room (1) becomes the set temperature X ( For example, it is maintained at −15 ° C.).

    Further, the control unit (60) switches the cooling unit (20, 40) that performs the cooling mode when the operation mode is switched in the first and second cooling units (20, 40), so that the constant temperature chamber (1 ), A predetermined switching operation is performed in the first and second cooling units (20, 40) so that the indoor air temperature does not fluctuate.

    Hereinafter, the switching operation when switching between the cooling mode, the standby mode, and the operation mode will be described in detail with reference to FIGS. 1, 4 and 5 are all schematic configuration diagrams of the air conditioning system (10). In FIG. 1, the first cooling unit (20) is in the cooling mode and the second cooling unit (40) is in the standby mode. In FIG. 4, the air flow in the first cooling unit (20) is in the standby mode, and the second cooling unit (40) is in the cooling mode in FIG. The flow of air when both the first and second cooling units (20, 40) are performing the switching operation is indicated by arrows.

<Cooling mode>
When the controller (60) executes the cooling mode in the first cooling unit (20), the first to sixth heat exchangers (21 to 26, 41 to 46) to which the first to sixth heat exchangers are connected are connected. While controlling the 1st on-off valve (74) of a refrigerant circuit (91-96) to an open state, the 2nd on-off valve (75) is controlled to a closed state. Thus, in the first to sixth refrigerant circuits (91 to 96), the refrigerant circulates to perform a vapor compression refrigeration cycle, and the first to sixth heat exchangers (21 to 26) function as an evaporator. To do. On the other hand, the controller (60) closes the first on-off valve (74) of the first to sixth refrigerant circuits (91 to 96) when executing the cooling mode in the second cooling unit (40). On the other hand, the second on-off valve (75) is controlled to be opened. Thus, in the first to sixth refrigerant circuits (91 to 96), the refrigerant circulates to perform a vapor compression refrigeration cycle, and the first to sixth heat exchangers (41 to 46) function as an evaporator. To do.

    The control unit (60) controls the supply air damper (34, 54) to the maximum opening when the cooling mode is executed in the first and second cooling units (20, 40), while the bypass damper (35, 55) is controlled to the minimum opening, and the blower fans (29, 49) are operated at a predetermined air volume. Thereby, in the casing (30, 50), an air flow from the inflow portion (30b, 50b) through the main body portion (30a, 50a) to the outflow portion (30c, 50c) is formed, and the return air Air in the indoor space (S1) of the temperature-controlled room (1) is taken into the inflow part (30b, 50b) through the duct (32, 52).

    The air taken into the inflow part (30b, 50b) flows into the main body part (30a, 50a) from the lower part of the inflow part (30b, 50b) and functions as the first to sixth heat exchangers (21 When passing through ˜26, 41 to 46), it is cooled by the refrigerant. The cooling air cooled by the first to sixth heat exchangers (21 to 26, 41 to 46) is temperature-adjusted when passing through a heater (28, 48) made of an electric heater, and then a blower fan ( 29, 49) and blown out to the outflow part (30c, 50c).

    The heater (28, 48) made of an electric heater is set to the same temperature as the set temperature X (for example, −15 ° C.) of the indoor air of the temperature-controlled room (1) by the control unit (60). Then, the heating capacity (supply power) is controlled so that the supply air temperature becomes the set temperature. Specifically, the control unit (60) detects that the detected temperature of the air temperature sensor (61, 62) provided in the outflow unit (30c, 50c) is a set temperature X of the indoor air of the temperature-controlled room (1) (for example, , −15 ° C.), the electric power supplied to the heaters (28, 48) is controlled.

    The cooling air blown out to the outflow part (30c, 50c) by the blower fan (29, 49) passes through the air supply passage (31, 51) to the inflow space (S10) of the indoor space (S1) of the temperature-controlled room (1). ). Specifically, the cooling air flows into the introduction space (S11) to which the supply passage (31, 51) is connected, passes through the communication port (3a) of the partition wall (3), and is mixed into the mixing space (S12). After being humidified by the humidifier (6) as necessary, it is blown out from the outlet (2a) toward the vicinity of the apparatus (100) for testing the indoor space (S1).

<Standby mode>
The control unit (60) controls the supply damper (34, 54) to the minimum opening, while controlling the bypass damper (35, 55) to the maximum opening, thereby controlling the supply passage (31, 51). While the communication between each cooling unit (20, 40) and the temperature-controlled room (1) is blocked, in each cooling unit (20, 40), the outflow part (30c, 50c) and inflow part ( 30a, 50a) are connected, and a standby mode in which air is not supplied to the temperature-controlled room (1) is executed. In the standby mode, the control unit (60) always operates the blower fans (29, 49) with a predetermined air volume except for a draining operation (d) in a defrost operation described later. Thereby, in the standby mode, the air blown out to the outflow part (30c, 50c) by the blower fan (29, 49) returns to the inflow part (30b, 50b) through the bypass duct (33, 53), and the casing ( 30, 50), air circulates between the inflow part (30b, 50b) and the outflow part (30c, 50c).

    When the first cooling unit (20) is in the standby mode, the second cooling unit (40) is in the cooling mode, and the control unit (60) causes the first to sixth refrigerant circuits (91 to 96). The first on-off valve (74) is controlled to the closed state, and the second on-off valve (75) is controlled to the open state. Conversely, when the second cooling unit (40) is in the standby mode, the first cooling unit (20) is in the cooling mode, and the control unit (60) controls the first to sixth refrigerant circuits (91 to 96). The first on-off valve (74) is controlled to be in an open state, and the second on-off valve (75) is controlled to be in a closed state.

    As shown in FIGS. 3A and 3B, the control unit (60) performs the standby operation (a), the defrost operation (b to d), and the precool operation (e) in the standby mode. .

    In the standby operation (a), after the standby switching operation is completed, before the defrosting operation (b to d) is performed, the control unit (60) causes the various control devices to wait for a predetermined time at the end of the standby switching operation. Maintained in operating state. In the cooling unit (20, 40) during the standby operation (a), the air is not heated or cooled in the casing (30, 50), and the inflow part (30b, 50b) and the outflow part (30c, 50c) It will circulate between.

    The defrost operation (b to d) includes a heating operation (b), an air blowing operation (c), and a draining operation (d), and the first to sixth heat exchangers (21 to 26, 41 to 46). This is an operation of removing frost attached to the first to sixth heat exchangers (21 to 26, 41 to 46) during the cooling mode by heating. In the defrost operation (b to d), the control unit (60) performs an operation in the order of the heating operation (b), the air blowing operation (c), and the draining operation (d).

    In the heating operation (b), the controller (60) changes the set temperature of the heater (28, 48) from the set temperature X (for example, −15 ° C.) of the indoor air of the temperature-controlled room (1) to the high temperature Y ( For example, the setting is changed to 15 ° C., and heating is performed so that the temperature of the air passing through the first to sixth heat exchangers (21 to 26, 41 to 46) in the casing (30) becomes the set temperature Y. The heating capacity (supply power) of the vessel (28, 48) is controlled. Specifically, the control unit (60) is configured so that the detected temperature of the air temperature sensor (61, 62) provided in the outflow portion (30c, 50c) becomes a set temperature Y (for example, 15 ° C.). The electric power supplied to the heater (28, 48) is controlled. In this way, in the heating operation (b), the air of high temperature Y (for example, 15 ° C.) circulates in the casing (30) and passes through the first to sixth heat exchangers (21 to 26, 41 to 46). By passing, the first to sixth heat exchangers (21 to 26, 41 to 46) are heated by the passing air, and the frost attached to the first to sixth heat exchangers (21 to 26, 41 to 46) Melts.

    In the air blowing operation (c), the operation of the heaters (28, 48) is stopped by the control unit (60). Thereby, the air circulated between the inflow part (30b, 50b) and the outflow part (30c, 50c) of the casing (30, 50) is not heated by the heater (28, 48). However, for a while after the end of the heating operation (b), the temperature of the air circulating between the inflow part (30b, 50b) and the outflow part (30c, 50c) of the casing (30, 50) is relatively high. Therefore, the 1st-6th heat exchanger (21-26,41-46) is heated with passing air, and the frost which adhered to the 1st-6th heat exchanger (21-26,41-46) Will melt.

    In the draining operation (d), the operation of the blower fan (29, 49) is also stopped by the controller (60) while the operation of the heater (28, 48) is stopped. During this draining operation (d), by preventing air from flowing in the casing (30, 50), the first to sixth heat exchangers (21 to 20) are heated by the heating operation (b) and the blowing operation (c). 26, 41 to 46) water formed by melting frost is dropped by its own weight to a drain pan (not shown) provided below the first to sixth heat exchangers (21 to 26, 41 to 46), and the casing. Do not be scattered in (30,50).

    In the precooling operation (e), the air in the casing (30, 50) heated to a high temperature by the defrosting operation (b to d) is converted into the seventh heat exchanger (27,47) constituting the cooler for the precooling operation. ).

    Specifically, when the precooling operation (e) is performed in the first cooling unit (20), the seventh refrigerant circuit (27, 47) to which the seventh heat exchanger (27, 47) is connected by the control unit (60). 97) with the first on-off valve (74) in the open state and the second on-off valve (75) in the closed state, the compressor (71) is started, and refrigerant is supplied to the seventh refrigerant circuit (97). The seventh heat exchanger (27) is circulated to function as an evaporator. Thereby, the air circulating between the inflow part (30b) and the outflow part (30c) of the casing (30) is cooled when passing through the seventh heat exchanger (27).

    On the other hand, when the precooling operation (e) is performed in the second cooling unit (40), the controller (60) causes the seventh refrigerant circuit (97) connected to the seventh heat exchanger (27, 47). With the first on-off valve (74) closed and the second on-off valve (75) controlled to open, the compressor (71) is started to circulate the refrigerant in the seventh refrigerant circuit (97). Then, the seventh heat exchanger (47) functions as an evaporator. Thereby, the air circulating between the inflow part (50b) and the outflow part (50c) of the casing (50) is cooled when passing through the seventh heat exchanger (47).

    By such a precooling operation (e), the air in the casing (30, 50) is cooled after the defrosting operation (b to d) is finished and before switching to the cooling mode.

<Switching action>
As shown in FIGS. 3 and 5, the control unit (60) performs a switching operation when switching the operation mode in each cooling unit (20, 40). Specifically, in the cooling unit (20, 40) during the cooling switching to switch from the standby mode to the cooling mode, evaporation of the first to sixth heat exchangers (21 to 26, 41 to 46) for the cooling mode is performed. Gradually increase the number of heat exchangers functioning as heat exchangers and gradually increase the opening of the supply damper (34,54), while gradually decreasing the opening of the bypass damper (35,55) ( Cooling switching operation in FIG. 3). On the other hand, in the cooling unit (20, 40) during the standby switching to switch from the standby mode to the cooling mode, the heat exchange functioning as an evaporator among the six heat exchangers (21-26, 41-46) for the cooling mode. Decrease the number of units by the amount increased by the cooling unit (20, 40) during cooling switching, gradually reduce the opening of the air supply damper (54, 34) and adjust the bypass damper (55, 35) The opening is gradually increased (standby switching operation in FIG. 3).

    For example, when the operation mode of the first cooling unit (20) is switched from the cooling mode to the standby mode and the operation mode of the second cooling unit (40) is switched from the standby mode to the cooling mode, the control unit (60) The second on-off valve (75) controlled to be closed in all of the first to sixth refrigerant circuits (91 to 96) to which the first to sixth heat exchangers (21 to 26, 41 to 46) are connected. Are opened one by one every T minutes (for example, every minute), and the first on-off valve (74 that has been controlled to be open in all of the first to sixth refrigerant circuits (91 to 96)). ) Are closed one by one every T minutes (for example, every minute) (see the standby switching operation in FIG. 3A and the cooling switching operation in FIG. 3B). The control unit (60) controls the opening of the second on-off valve (75) in each refrigerant circuit (91 to 96) for t seconds (for example, 5 seconds) rather than the control of closing the first on-off valve (74). ) Only first.

    Specifically, in the switching operation, the control unit (60) first opens the second on-off valve (75) of the first refrigerant circuit (91) to which the first heat exchanger (21, 41) is connected, After t seconds, the first on-off valve (74) of the first refrigerant circuit (91) is closed. Then, the second on-off valve (75) of the second refrigerant circuit (92) connected to the second heat exchanger (22, 42) is opened, and the second on-off valve (75) of the first refrigerant circuit (91) is opened. After a lapse of T minutes, the first on-off valve (74) of the second refrigerant circuit (92) is closed after t seconds. Thereafter, similarly, the third refrigerant circuit (93), the fourth refrigerant circuit (94), the fifth refrigerant circuit (95), and the sixth refrigerant circuit (96) are opened and closed every T minutes in this order. The operation of closing the first on-off valve (74) is performed t seconds after the valve (75) is opened.

    Thus, before the switching operation, all of the first to sixth heat exchangers (21 to 26) of the first cooling unit (20) function as evaporators in the first to sixth refrigerant circuits (91 to 96). However, when the refrigerant did not flow through all of the first to sixth heat exchangers (41 to 46) of the second cooling unit (40), the number of heat exchangers functioning as evaporators was changed by this switching operation. In the second cooling unit (40), one unit is increased, and accordingly, in the first cooling unit (20), one unit is decreased. As a result, before the switching operation, the air was cooled only by the first cooling unit (20) (see FIG. 1). By this switching operation, the first cooling unit (20) and the second cooling unit (40), the air is cooled, and the cooling capacity of the first cooling unit (20) decreases stepwise and the second cooling unit (40) increases stepwise (FIG. 5). See). At the end of the switching operation, the air is cooled only by the second cooling unit (40) (see FIG. 4).

    In the switching operation, the controller (60) gradually increases the opening degree of the air supply damper (54) in the second cooling unit (40) that increases the number of heat exchangers functioning as evaporators stepwise. While increasing (proportionally), the opening degree of the bypass damper (55) is gradually (proportionally) decreased (see the cooling switching operation in FIG. 3B). Conversely, in the first cooling unit (20) that reduces the number of heat exchangers functioning as evaporators in stages, the opening of the air supply damper (34) is gradually (proportionalally) reduced while the bypass damper The opening degree of (35) is gradually increased (proportionally) (see the standby switching operation in FIG. 3A).

    Thereby, the cooling air supplied to the temperature-controlled room (1) from each cooling unit (20, 40) with the change of the cooling capacity of the first cooling unit (20) and the second cooling unit (40) by the switching operation. Increases or decreases airflow. Specifically, in the first cooling unit (20) in which the cooling capacity gradually decreases, the air volume of the cooling air supplied to the temperature-controlled room (1) gradually decreases (proportionally) through the bypass passage (33). As a result, the air volume returned from the outflow part (30c) to the inflow part (30b) increases. On the other hand, in the second cooling unit (40) in which the cooling capacity increases stepwise, the air volume of the cooling air supplied to the temperature-controlled room (1) gradually increases (proportionalally) and flows out through the bypass passage (53). The air volume returned from (50c) to the inflow section (50b) decreases. At the end of the switching operation, the air is cooled only by the second cooling unit (40), and only the cooling air cooled by the second cooling unit (40) is supplied to the temperature-controlled room (1).

    When the operation mode of the first cooling unit (20) is switched from the standby mode to the cooling mode and the operation mode of the second cooling unit (40) is switched from the cooling mode to the standby mode, the first cooling unit (20) The cooling switching operation is performed at, and the standby switching operation is performed at the second cooling unit (40).

    Specifically, the first on-off valves (74) of the first to sixth refrigerant circuits (91 to 96) are opened one by one every T minutes (for example, every minute), and the second on-off valves (75 ) Are closed one by one every T minutes (for example, every minute) (see the cooling switching operation in FIG. 3A and the standby switching operation in FIG. 3B). The control unit (60) controls the opening of the first on-off valve (74) in each refrigerant circuit (91 to 96) for t seconds (for example, 5 seconds) than the control of closing the second on-off valve (75). ) Only first. In the first cooling unit (20), the control unit (60) gradually (proportionally) increases the opening degree of the supply damper (34), while gradually increasing the opening degree of the bypass damper (35). (Proportionally) decrease (see cooling switching operation in FIG. 3A). Conversely, in the second cooling unit (40), the opening degree of the supply damper (54) is gradually (proportionalally) decreased, while the opening degree of the bypass damper (55) is gradually (proportionalally) increased. (See the standby switching operation in FIG. 3B).

    As a result, the air volume of the cooling air supplied to the temperature-controlled room (1) gradually increases (proportionalally) in the first cooling unit (20) whose cooling capacity increases stepwise and flows out through the bypass passage (33). The air volume returned from the section (30c) to the inflow section (30b) decreases. On the other hand, in the second cooling unit (40) in which the cooling capacity gradually decreases, the air volume of the cooling air supplied to the temperature-controlled room (1) gradually decreases (proportionally) and flows out through the bypass passage (53). The air volume returned from the (50c) to the inflow section (50b) increases. At the end of the switching operation, the air is cooled only by the first cooling unit (20), and only the cooling air cooled by the first cooling unit (20) is supplied to the temperature-controlled room (1).

    As shown in FIG. 5, during any switching operation, both the first cooling unit (20) and the second cooling unit (40) are controlled by the constant temperature chamber (1) through the supply passage (31, 51). ) Is supplied with cooling air. At this time, the cooling air cooled by the first cooling unit (20) and the second cooling unit (40) passes through the first and second supply ports (4a, 4b) from the supply passages (31, 51). Is supplied to the introduction space (S11) of the inflow space (S10) via the one communication port (3a) formed in the partition wall (3) from the introduction space (S11) to the mixing space (S12). By flowing in, they mix in the mixing space (S12). Then, in the mixing space (S12), after being humidified by the humidifier (6) as necessary, it goes from the outlet (2a) to the vicinity where the apparatus (100) for testing the indoor space (S1) is installed. And blown out.

<Auxiliary cooling operation>
The controller (60) is in the cooling switching operation for switching the seventh heat exchanger (27, 47), which has been functioning as an evaporator in the standby mode before the switching operation and performing the precooling operation, from the standby mode to the cooling mode. In addition, it functions as an evaporator and performs an auxiliary cooling operation for cooling the air as an auxiliary.

    Specifically, when the precooling operation (e) is performed in the first cooling unit (20), after the operation is completed, the control unit (60) controls the first on-off valve (97) of the seventh refrigerant circuit (97). The operation is continued without stopping the compressor (71), with 74) in the open state and the second on-off valve (75) in the closed state. Thus, in the first cooling unit (20) during the cooling switching operation, in addition to the heat exchanger for the cooling mode functioning as an evaporator, the air is supplementarily supplied by the seventh heat exchanger (27) functioning as an evaporator. Is cooled.

    On the other hand, when the precooling operation (e) is performed in the second cooling unit (40), after the operation is completed, the control unit (60) opens the first on-off valve (74) of the seventh refrigerant circuit (97). The operation is continued without stopping the compressor (71) with the second open / close valve (75) kept open in the closed state. Thus, in the second cooling unit (40) during the cooling switching operation, in addition to the heat exchanger for the cooling mode functioning as an evaporator, the air is supplementarily supplied by the seventh heat exchanger (47) functioning as an evaporator. Is cooled.

-Effect of Embodiment 1-
As described above, according to the air conditioning system (10), the cooling mode in which the plurality of heat exchangers (21 to 26, 41 to 46) function as evaporators to supply cooled air to the temperature-controlled room (1). Two cooling units capable of performing the above are provided, and when one enters a standby mode in which air is not supplied to the temperature-controlled room (1) including the defrost operation, the other is in the cooling mode. According to such a configuration, any one of the two cooling units (20, 40) always uses a plurality of heat exchangers (21-26, 41-46) as evaporators to cool the cooled air. Since the cooling mode is to be supplied to the room (1), even if one cooling unit (20, 40) is in the defrosting operation, the other cooling unit (40, 20) will cause the room air in the temperature-controlled room (1) The temperature can be controlled to a desired temperature.

    Further, according to the present air conditioning system (10), when the operation mode is switched in each cooling unit (20, 40), the cooling unit (20, 40) in the cooling switching to switch from the standby mode to the cooling mode cools the air. While the cooling capacity increases step by step, the cooling capacity (20, 40) during standby switching decreases the cooling capacity for cooling air by the amount increased by the cooling unit (20, 40) during cooling switching. It is configured. In addition, the cooling air supplied to the temperature-controlled room (1) in the cooling unit (20, 40) in the cooling switching mode in which the cooling capacity increases stepwise as the cooling capacity of the two cooling units (20, 40) increases or decreases. In the cooling unit (20,40) during standby switching where the airflow of the air gradually increases (proportional) and the cooling capacity decreases stepwise, the airflow of the cooling air supplied to the temperature-controlled room (1) gradually (proportional) To be reduced). In this way, when switching between operation modes in the two cooling units (20, 40), instead of switching to one breath, the cooling capacity and the air supply amount are gradually increased in one cooling unit (20, 40), In the other cooling unit (40, 20), the switching operation is gradually performed by reducing the amount of increase by the one cooling unit (20, 40). Thereby, the temperature and the air supply amount of the cooling air supplied to the temperature-controlled room (1) are not greatly changed by the switching operation. Accordingly, even when the operation mode is switched, the indoor air temperature of the temperature-controlled room (1) can be stabilized at a desired temperature.

    Further, according to the air conditioning system (10), when the operation mode is switched in each cooling unit (20, 40), the heat exchanger (21 to 40) that functions as an evaporator in the cooling unit (20, 40) in the cooling switching mode. The operation to increase the number of units 26, 41 to 46) precedes the operation to decrease the number of heat exchangers (21 to 26, 41 to 46) that function as evaporators in the cooling units (20, 40) that are in standby switching. It was decided to make it perform. That is, in each refrigerant circuit (91-96) in which a plurality of heat exchangers (21-26, 41-46) of two cooling units (20, 40) are connected in parallel to each other in pairs, When changing the heat exchanger (21-26, 41-46) functioning as an evaporator, the refrigerant was first circulated through the heat exchanger of one cooling unit (20, 40) where the refrigerant did not flow Therefore, the circulation of the refrigerant to the heat exchanger of the other cooling unit (40, 20) in which the refrigerant was flowing was prevented. Thereby, the heat exchanger (21-26, 41-46) which functions smoothly as an evaporator can be changed, without stopping the circulation of the refrigerant in each refrigerant circuit (91-96).

    Further, according to the air conditioning system (10), in the standby mode of each cooling unit (20, 40), the air in the casing (30, 50) is cooled by the cooler (27, 47) after the defrost operation is completed. You are going to do a precool action. By this precooling operation, the air in the casing (30, 50) heated and heated during the defrosting operation is cooled by the cooler (27, 47). Since the standby mode is switched to the cooling mode after the pre-cooling operation is finished, the air in the casing (30, 50) is sufficiently cooled, and then the temperature-controlled room (1) of the air in the casing (30, 50) Supply (air supply) to is started. Accordingly, during the cooling switching operation or during the execution of the cooling mode, relatively high temperature air remains in the casing (30, 50), and this high temperature air is supplied to the temperature-controlled room (1). The room temperature of the temperature-controlled room (1) can be stably controlled to a desired temperature without increasing the air temperature.

    Moreover, according to this air-conditioning system (10), in the cooling unit (20, 40) during cooling switching, some heat exchangers (21-26) of the plurality of heat exchangers (21-26, 41-46) 41 to 46), the auxiliary cooling operation for cooling the air is performed using the cooler (27, 47) used in the precooling operation. As a result, in the cooling unit (20, 40) during the cooling switching in which the cooling capacity tends to be lower than that of the cooling unit (20, 40) executing the cooling mode before the standby switching, the cooler (27, By cooling the air supplementarily in 47), it is possible to avoid a decrease in the cooling capacity due to the switching operation.

    Further, according to the air conditioning system (10), the plurality of heat exchangers (21 to 26, 41 to 46) of the two cooling units (20, 40) are respectively paired with the corresponding refrigerant circuits ( 91 to 96) are connected in parallel to each other, so that the corresponding two heat exchangers of the two cooling units (20, 40) can be simply changed in the refrigerant circuit (91 to 96). The heat exchanger functioning as an evaporator can be changed. Therefore, the operation mode of the two cooling units (20, 40) can be easily changed. In addition, since the number of devices in the air conditioning system (10) can be reduced by sharing the refrigerant circuit (91 to 96) in the two cooling units (20, 40), the manufacturing cost can be reduced and the system size can be reduced. Can be achieved.

<< Other Embodiments >>
In the above embodiment, the first and second cooling units (20, 40) each have seven heat exchangers (21-27, 41-47), of which the first to sixth heat exchangers (21- 26, 41 to 46) are configured as heat exchangers for the cooling mode, and the seventh heat exchanger (27, 47) is configured as a cooler for precooling operation. The heat provided by each cooling unit (20, 40) The number of exchangers and the composition ratio of the heat exchanger for the cooling mode and the cooler for the precool operation are not limited to those in the above embodiment.

    In the above embodiment, the auxiliary cooling operation is performed using the cooler for the precool operation, but the auxiliary cooling operation may not be performed.

    Moreover, in the said embodiment, the 1st-7th heat exchangers (21-27, 41-47) of a 1st and 2nd cooling unit (20,40) correspond to 1st each corresponding to one pair. -It connected to the 7th refrigerant circuit (91-97), and the refrigerant circuit (91-96) was shared in two cooling units (20, 40), but in two cooling units (20, 40), It is good also as providing a refrigerant circuit separately.

    As described above, the present invention is useful for an air conditioning system that supplies cooling air to a temperature-controlled room and controls the room air temperature of the temperature-controlled room to a desired temperature.

1 constant temperature room
20 First cooling unit
21-26 1st-6th heat exchanger (heat exchanger)
27 7th heat exchanger (cooler)
28 Heater
29 Blower fan
30 casing
31 Air supply duct
33 Bypass duct
34 Air supply damper
35 Bypass damper
40 First cooling unit
41-46 1st-6th heat exchanger (heat exchanger)
47 7th heat exchanger (cooler)
48 Heater
49 Blower fan
50 casing
51 Air supply duct
53 Bypass duct
54 Air supply damper
55 Bypass damper
60 Control unit

Claims (5)

An air conditioning system for controlling the indoor air temperature of the temperature-controlled room (1) to a desired temperature,
The casing (30, 50) connected to the temperature-controlled room (1) and a plurality of heat exchangers (21-26, provided in the casing (30, 50) and connected to the refrigerant circuit (91 to 96) 41 to 46), and a cooling mode in which the plurality of heat exchangers (21 to 26, 41 to 46) function as evaporators to supply cooled air to the temperature-controlled room (1), and Two cooling systems including a defrosting operation to defrost by heating a plurality of heat exchangers (21 to 26, 41 to 46), and switchable between a standby mode in which air is not supplied to the temperature-controlled room (1) Unit (20,40),
Each of the cooling units (20, 40) is alternately switched between the cooling mode and the standby mode, and when one of the two cooling units (20, 40) is in the cooling mode, the other is in the standby mode. A controller (60) for controlling the operation mode of the two cooling units (20, 40),
When the control unit (60) switches the operation mode in each of the cooling units (20, 40),
In the cooling unit (20, 40) during the cooling switching to switch from the standby mode to the cooling mode, the number of the heat exchangers (21 to 26, 41 to 46) functioning as an evaporator is increased stepwise. The cooling switching operation is performed to gradually increase the air volume of the cooling air supplied to the temperature-controlled room (1),
The number of the heat exchangers (21 to 26, 41 to 46) functioning as an evaporator is set to the cooling unit during the cooling switching in the cooling unit (20, 40) during the standby switching to switch from the cooling mode to the standby mode. The unit (20, 40) is configured to perform a standby switching operation in which the air volume of the cooling air supplied to the temperature-controlled room (1) is gradually decreased while being decreased by the amount increased. Air conditioning system. In claim 1,
When the operation mode is switched in each cooling unit (20, 40), the control unit (60) is configured to operate the heat exchanger (21 to 40) functioning as an evaporator in the cooling unit (20, 40) during the cooling switching. 26, 41 to 46) The operation to increase the number of units is more than the operation to decrease the number of the heat exchangers (21 to 26, 41 to 46) that function as an evaporator in the cooling unit (20, 40) during the standby switching. An air conditioning system characterized by being configured to be performed first. In claim 1 or 2,
Each of the cooling units (20, 40) has a cooler (27, 47) provided in the casing (30, 50) for cooling air,
In the standby mode of each of the cooling units (20, 40), the control unit (60) causes the air in the casing (30, 50) to be discharged by the cooler (27, 47) after the defrost operation is completed. An air conditioning system configured to perform a precooling operation for cooling. In claim 3,
The controller (60) performs an auxiliary cooling operation for cooling the air in the casing (30, 50) by the cooler (27, 47) in the cooling unit (20, 40) during the cooling switching. An air conditioning system characterized by being configured as described above. In any one of Claims 1 thru | or 4,
The refrigerant circuits (91 to 96) are provided in the same number as the heat exchangers (21 to 26, 41 to 46) included in the cooling units (20, 40).
The plurality of heat exchangers (21-26, 41-46) of the two cooling units (20, 40) are connected in parallel to the corresponding refrigerant circuits (91-96) in pairs. Air conditioning system characterized by being.

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