JP2009257697A - Air-conditioning system and outdoor unit of air conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent indoor units of air conditioners from being brought into a state where their air-conditioning operations cannot be executed, in an air-conditioning system comprising the air conditioners where the plurality of indoor units are connected to an outdoor unit. <P>SOLUTION: This outdoor unit 23 of each air conditioner 14, constituting the air conditioning system, is provided with a gas-side extending pipe 48 connected to a gas-side joint pipe 16, at one end and constituting an outdoor gas-side connecting section 46 at the other end, and a liquid-side extending pipe 47, connected to a liquid-side joint pipe 36 at one end and constituting an outdoor liquid-side connecting section 45 at the other end. The air-conditioning system is provided with a gas-side connecting circuit 70 that connects the outdoor gas-side connecting sections 46 of the outdoor units 23 to one another, and a liquid-side connecting circuit 60 for connecting the outdoor liquid-side connecting sections 45 of the outdoor units 23 to one another. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air conditioning system including an air conditioner in which a plurality of indoor units are connected to an outdoor unit, and an outdoor unit of the air conditioning system.

  Conventionally, an air conditioner in which a plurality of indoor units are connected to an outdoor unit is known. An example of this type of air conditioner is disclosed in Patent Document 1.

Patent Document 1 discloses an air conditioner including an outdoor unit and two indoor units. In this air conditioner, each indoor unit is connected to an outdoor unit via a gas side communication pipe and a liquid side communication pipe. Each of the gas side communication pipe and the liquid side communication pipe has its indoor side branched into two hands and connected to the indoor unit. The two indoor units are connected in parallel to each other. The outdoor unit is provided with a compressor, an outdoor heat exchanger, an outdoor expansion valve, and the like. Each indoor unit is provided with an indoor expansion valve and an indoor heat exchanger.
JP 2002-147878 A

  By the way, in the air conditioner of patent document 1, although the branch location of piping with respect to a some indoor unit is provided between the outdoor unit and each indoor unit, providing the branch location in an outdoor unit is considered. However, in such an air conditioner, the piping configuration in the outdoor unit becomes more complicated as the number of connected indoor units increases. For this reason, there is a limit to the number of indoor units connected to one outdoor unit, and so many indoor units cannot be provided. In order to provide many indoor units, it is necessary to install a plurality of air conditioners.

  However, even if a plurality of air conditioners are installed, if the air conditioners are independent of each other, in each air conditioner, if there is an abnormality in the compressor, the refrigerant from the outdoor unit compressor to the indoor unit Cannot be supplied to the indoor unit of the air conditioner.

  The present invention has been made in view of such points, and an object of the present invention is to provide an air conditioning system including an air conditioner in which a plurality of indoor units are connected to an outdoor unit. It is to be configured so as to avoid a situation in which it is impossible to execute.

  The first invention includes a plurality of air conditioners (14), and each of the air conditioners (14) includes an outdoor unit (23) provided with a compressor (32) and an outdoor heat exchanger (33). A refrigerant circuit (5) formed by a plurality of indoor units (24) each provided with an indoor heat exchanger (56), and a refrigerant is circulated in the refrigerant circuit (5) to perform a refrigeration cycle The air conditioning system is configured as described above. The air conditioning system includes a plurality of refrigerant circuits (5) of the air conditioners (14) housed in the outdoor unit (23) and connected to the indoor units (24) one by one. Gas side branch pipe (17, 18), gas side junction pipe (16) for connecting all gas side branch pipes (17, 18) to the compressor (32), and each indoor unit (24) A plurality of liquid side branch pipes (37, 38) connected to each other, and a liquid side junction pipe for connecting all the liquid side branch pipes (37, 38) to the outdoor heat exchanger (33) ( 36), and one end of each air conditioner (14) connected to the outdoor side unit (23) is connected to the gas side junction pipe (16) and the other end is connected to the outdoor side gas side connecting part (46). A gas side extension pipe (48) constituting one end and a liquid side extension pipe (47) constituting one end of the liquid side junction pipe (36) and the other end constituting an outdoor liquid side connection section (45) are provided. And above The gas side connection circuit (70) for connecting the outdoor gas side connection portions (46) of the outdoor units (23) to each other and the outdoor liquid side connection portion (45) of the outdoor units (23) are connected to each other. And a liquid side connection circuit (60).

  In the first invention, the outdoor units (23) are connected to each other by the gas side connection circuit (70) and the liquid side connection circuit (60). The gas side connection circuit (70) connects between the outdoor gas side connection part (46) which is an end part of the gas side extension pipe (48) extending from the gas side junction pipe (16). Further, the liquid side connection circuit (60) connects between the outdoor liquid side connection portions (45) which are the end portions of the liquid side extension pipe (47) extending from the liquid side confluence pipe (36). In other words, the outdoor units (23) are connected to each other so that the gas side merging pipes (16) and the liquid side merging pipes (36) communicate with each other. For this reason, in each air conditioner (14), the indoor heat exchanger (56) of the air conditioner (14) is connected to another air conditioner through the gas side connection circuit (70) and the liquid side connection circuit (60). The gas side junction pipe (16) extending from the compressor (32) of the compressor (14) communicates with the liquid side junction pipe (36) extending from the outdoor heat exchanger (33) of the other air conditioner (14). . And for each air conditioner (14), there is other between the indoor heat exchanger (56) of the air conditioner (14) and the outdoor heat exchanger (33) of the other air conditioner (14). The refrigerant discharged from the compressor (32) of the air conditioner (14) can be circulated to perform a refrigeration cycle.

  In a second aspect based on the first aspect, each of the air conditioners (14) is configured such that the refrigerant discharged from the compressor (32) of the refrigerant circuit (5) is the indoor heat of the refrigerant circuit (5). The first air conditioner (14a), which is one of the plurality of air conditioners (14), performs the normal heating operation while being configured so as to be able to perform a normal heating operation that dissipates heat in the exchanger (56). When the first heating operation and the first air conditioner (14a) cannot perform the normal heating operation, the refrigerant circuit of the second air conditioner (14b) different from the first air conditioner (14a) ( The refrigerant discharged from the compressor (32b) of 5b) is supplied to the refrigerant circuit (5a) of the first air conditioner (14a) using the gas side connection circuit (70) and the liquid side connection circuit (60). ) To the indoor heat exchanger (56a), and the second heating operation to dissipate heat is executable.

  In the second invention, the first heating operation in which the first air conditioner (14a) performs the normal heating operation can be executed. In the normal heating operation of the first air conditioner (14a), the refrigerant discharged from the compressor (32) of the first air conditioner (14a) is converted into the indoor heat exchanger (56 of the first air conditioner (14a). ) To dissipate heat. Moreover, in 2nd invention, when the 1st air conditioner (14a) cannot perform normal heating operation | movement, it discharged from the compressor (32b) of the refrigerant circuit (5b) of a 2nd air conditioner (14b). 2nd heating which supplies a refrigerant | coolant to the indoor heat exchanger (56a) of the refrigerant circuit (5a) of a 1st air conditioner (14a) using a gas side connection circuit (70) and a liquid side connection circuit (60) Operation is performed.

  Specifically, in the second heating operation, the refrigerant discharged from the compressor (32b) of the second air conditioner (14b) joins the gas side of the first air conditioner (14a) through the gas side connection circuit (70). The refrigerant introduced into the pipe (16a) and introduced into the gas side merge pipe (16) is supplied to the indoor unit (24) of the first air conditioner (14a). In the first air conditioner (14a), the refrigerant supplied from the second air conditioner (14b) dissipates heat in the indoor heat exchanger (56a), so that the heating operation is performed. Then, the refrigerant radiated by the indoor heat exchanger (56a) returns to the outdoor unit (23a) and passes through the liquid side junction pipe (36a) through the liquid side connection circuit (60) to the second air conditioner (14b). Return to the liquid side junction (36b). The refrigerant that has returned to the liquid side merge pipe (36b) of the second air conditioner (14b) evaporates in the outdoor heat exchanger (33b) of the second air conditioner (14b), and the second air conditioner (14b ) Is sucked into the compressor (32b). Thus, according to this 2nd invention, between the 1st outdoor unit (23a) and the 2nd outdoor unit (23b), gas side merging pipes (16) and liquid side merging pipes (36) communicate with each other. Therefore, even if the first air conditioner (14a) cannot perform the normal heating operation, the compressor (32b) and the outdoor heat exchanger (32b) of the second air conditioner (14b) The heating operation is performed in the indoor unit (24) of the first air conditioner (14a) using 33b).

  According to a third aspect of the present invention, in the second aspect of the invention, the indoor heat exchanger (56) radiates heat to the liquid side junction pipe (36) of each air conditioner (14) during the normal heating operation. A heating pressure reducing valve (41) for reducing the pressure of the refrigerant is provided, and the liquid side extension pipe (47) is connected to a position closer to the indoor heat exchanger (56) than the heating pressure reducing valve (41).

  In 3rd invention, the pressure reducing valve for heating (41) which decompresses the refrigerant | coolant thermally radiated with the indoor heat exchanger (56) at the time of normal heating operation | movement to the liquid side merge pipe (36) of each air conditioner (14) Is provided. For this reason, in the second heating operation for the first air conditioner (14a), the refrigerant radiated by the indoor heat exchanger (56a) of the first air conditioner (14a) is heated by the first air conditioner (14a). The pressure is reduced by the heating pressure reducing valve (41) of the second air conditioner (14b) without passing through the pressure reducing valve (41).

  According to a fourth invention, in the second or third invention, the first air conditioner (14a) removes frost attached to the outdoor heat exchanger (33) during the normal heating operation. The first air conditioner (14a) is configured to be capable of performing a defrosting operation that is melted by the refrigerant discharged from the compressor (32) of the air conditioner (14a) or the second air conditioner (14b). When performing a frost operation | movement, it is comprised so that the said 2nd heating operation | movement may be performed.

  In the 4th invention, the 1st air harmony machine (14a) is constituted so that execution of a defrosting operation is possible. In the first air conditioner (14a) during the defrosting operation, the outdoor heat exchanger (33a) serves as a radiator, so that the normal heating operation cannot be performed. In the fourth aspect of the invention, the second heating operation is performed when the first air conditioner (14a) cannot perform the normal heating operation by the defrosting operation.

  According to a fifth invention, in the fourth invention, the connection of the gas side extension pipe (48a) in the gas side junction pipe (16a) to the refrigerant circuit (5a) of the first air conditioner (14a). Hot gas bypass pipe connecting between the compressor (32a) side of the part and the outdoor side heat exchanger (33a) side of the connecting part of the liquid side extension pipe (47a) in the liquid side junction pipe (36a) (49a) and a bypass on-off valve (51a) for opening and closing the hot gas bypass pipe (49a) are provided. In the defrosting operation of the first air conditioner (14a), the bypass on-off valve (51a) ) Is set to an open state, and the refrigerant discharged from the compressor (32a) is supplied to the outdoor heat exchanger (33a) through the hot gas bypass pipe (49a).

  In the fifth aspect of the invention, during the defrosting operation of the first air conditioner (14a), the bypass on-off valve (51a) of the hot gas bypass pipe (49a) is set to the open state. In the first air conditioner (14a), the refrigerant discharged from the compressor (32a) passes through the hot gas bypass pipe (49a) and is supplied to the outdoor heat exchanger (33a).

  According to a sixth aspect, in the fourth aspect, the refrigerant circuit (5a) of the first air conditioner (14a) includes the gas side merge pipe (16a) and the outdoor heat during the defrosting operation. A gas side communication pipe (53a) for communicating with the gas side of the exchanger (33a) and a communication on-off valve (54a) for opening and closing the gas side communication pipe (53a) are provided, and the first air In the defrosting operation of the conditioner (14a), the open / close valve for communication (54a) is set to an open state, and the first air conditioner is connected through the gas side connection circuit (70) with the second heating operation. Part of the refrigerant discharged from the compressor (32b) of the second air conditioner (14b) supplied to the gas-side merging pipe (16a) of (14a) is exchanged with the outdoor heat through the gas-side communication pipe (53a). Is supplied to the vessel (33a).

  In the sixth aspect of the invention, during the defrosting operation of the first air conditioner (14a), the communication on-off valve (54a) of the gas side communication pipe (53a) is set to the open state. Therefore, the compressor of the second air conditioner (14b) supplied to the gas side merging pipe (16a) of the first air conditioner (14a) through the gas side connection circuit (70) with the second heating operation ( Part of the discharged refrigerant of 32b) is supplied to the outdoor heat exchanger (33a) of the first air conditioner (14a) through the gas side communication pipe (53a). In the outdoor heat exchanger (33a) of the first air conditioner (14a), the attached frost is melted by the high-temperature refrigerant. The refrigerant that has radiated heat to the frost in the outdoor heat exchanger (33a) of the first air conditioner (14a) returns to the liquid side merge pipe (36b) of the second air conditioner (14b) through the liquid side connection circuit (60). Then, after evaporating in the outdoor heat exchanger (33b) of the second air conditioner (14b), it is sucked into the compressor (32b) of the second air conditioner (14b). In the sixth aspect of the invention, during the defrosting operation of the first air conditioner (14a), the outdoor heat exchanger (33a) of the first air conditioner (14a) and the outdoor of the second air conditioner (14b) Between the heat exchanger (33b), the outdoor heat exchanger (33a) of the first air conditioner (14a) becomes a radiator and the outdoor heat exchanger (33b) of the second air conditioner (14b) evaporates. A refrigeration cycle is performed.

  In a seventh aspect of the present invention, in any one of the second to sixth aspects, the second heating operation is performed when the compressor (32a) of the first air conditioner (14a) becomes inoperable. Is configured to run.

  In the seventh invention, the second heating operation is performed when the compressor (32a) of the first air conditioner (14a) becomes inoperable. That is, the second heating operation is performed when the first air conditioner (14a) cannot perform the normal heating operation.

  In an eighth invention according to any one of the second to seventh inventions, the liquid side branch pipes (37, 38) of the air conditioners (14) include the liquid side branch pipes (37, 38). The flow rate control valves (42, 43) for adjusting the refrigerant flow rate of 38) are respectively provided.

  In the eighth invention, the flow rate regulating valves (42, 43) for regulating the refrigerant flow rate of each indoor heat exchanger (56) are arranged in the outdoor unit (23). For this reason, the refrigerant radiated by the indoor heat exchanger (56) during the first and second heating operations passes through the flow rate control valves (42, 43) in the outdoor unit (23).

  In a ninth aspect based on the eighth aspect, each gas side branch pipe (17, 18) of each air conditioner (14) includes the gas side branch pipe during the first and second heating operations. (17,18) Gas shut-off valve (8,8) that is closed when the flow control valve (42,43) of the liquid side branch pipe (37,38) connected to the same indoor heat exchanger (56) is closed 9) is provided.

  In the ninth aspect of the invention, the gas cutoff valves (8, 9) are provided in the gas side branch pipes (17, 18). During the first and second heating operations, the gas shut-off valve (8, 9) is the same indoor heat exchanger (56 as the gas side branch pipe (17, 18) provided with the gas shut-off valve (8, 9). ) Is closed when the flow control valve (42, 43) of the liquid side branch pipe (37, 38) connected to) is closed. In other words, the gas shut-off valve (8, 9) is used when the heating operation is stopped in the indoor unit (24) connected to the gas side branch pipe (17, 18) provided with the gas shut-off valve (8, 9). Closed. For this reason, even if heating operation is performed in another indoor unit (24) of the same air conditioner (14), the indoor heat exchanger (56) of the stopped indoor unit (24) The refrigerant is prevented from flowing in.

  In a tenth aspect of the present invention based on any one of the first to ninth aspects, the air conditioner (14) uses the refrigerant discharged from the compressor (32) of the refrigerant circuit (5) as the refrigerant. The first air conditioner (14a), which is one of the plurality of air conditioners (14), is configured to be able to perform a normal cooling operation that is evaporated by the indoor heat exchanger (56) of the circuit (5). ) Performs a normal cooling operation, and when the first air conditioner (14a) cannot perform a normal cooling operation, the second air conditioner is different from the first air conditioner (14a). The refrigerant discharged from the compressor (32b) of the refrigerant circuit (5b) of (14b) is supplied to the first air conditioner (70) using the gas side connection circuit (70) and the liquid side connection circuit (60). 14a) is supplied to the indoor heat exchanger (56a) of the refrigerant circuit (5a), and the second cooling operation is performed to evaporate the refrigerant in the indoor heat exchanger (56a). It has become possible.

  In the tenth aspect of the invention, the first air conditioner (14a) can perform the first cooling operation in which the normal cooling operation is performed. In the normal cooling operation of the first air conditioner (14a), the refrigerant discharged from the compressor (32) of the first air conditioner (14a) is converted into the indoor heat exchanger (56 of the first air conditioner (14a). ) To evaporate. Further, in the tenth invention, when the first air conditioner (14a) cannot perform the normal cooling operation, the first air conditioner (14a) is discharged from the compressor (32b) of the refrigerant circuit (5b) of the second air conditioner (14b). The refrigerant is supplied to the indoor heat exchanger (56a) of the refrigerant circuit (5a) of the first air conditioner (14a) using the gas side connection circuit (70) and the liquid side connection circuit (60). A second cooling operation for evaporating the refrigerant in the indoor heat exchanger (56a) is performed.

  Specifically, in the second cooling operation, the refrigerant discharged from the compressor (32b) of the second air conditioner (14b) dissipates heat in the outdoor heat exchanger (33b) of the second air conditioner (14b), The refrigerant radiated by the outdoor heat exchanger (33b) passes through the liquid side connection circuit (60), from the liquid side junction pipe (36b) of the second air conditioner (14b) to the liquid side of the first air conditioner (14a). The refrigerant introduced into the junction pipe (36a) and introduced into the liquid side junction pipe (36a) is supplied to the indoor unit (24) of the first air conditioner (14a). In the first air conditioner (14a), the refrigerant supplied from the second air conditioner (14b) evaporates in the indoor heat exchanger (56a), so that the cooling operation is performed. Then, the refrigerant evaporated in the indoor heat exchanger (56a) returns to the outdoor unit (23a) and passes through the gas side junction pipe (16a) to the second air conditioner (14b) through the gas side connection circuit (70). Return to the gas side merge pipe (16b). The refrigerant returned to the gas side merge pipe (16b) of the second air conditioner (14b) is sucked into the compressor (32b) of the second air conditioner (14b). Thus, according to the tenth aspect of the present invention, the gas side merging pipes (16) and the liquid side merging pipes (36) communicate with each other between the first outdoor unit (23a) and the second outdoor unit (23b). Therefore, even when the first air conditioner (14a) cannot perform the normal cooling operation, the compressor (32b) and the outdoor heat exchanger (32b) of the second air conditioner (14b) The cooling operation is performed in the indoor unit (24) of the first air conditioner (14a) using 33b).

  The eleventh invention is configured to execute the second cooling operation in the tenth invention when the compressor (32a) of the first air conditioner (14a) becomes inoperable. Yes.

  In the eleventh invention, the second cooling operation is performed when the compressor (32a) of the first air conditioner (14a) becomes inoperable. In other words, the second cooling operation is performed when the first air conditioner (14a) cannot perform the normal cooling operation.

  According to a twelfth aspect of the present invention, in any one of the first to eleventh aspects, the gas side connection portion (64, 65) for connecting to the outdoor gas side connection portion (46) of the outdoor unit (23). And a plurality of liquid side connection portions (61, 62) for connection to the outdoor liquid side connection portion (45) of the outdoor unit (23), and one set of the gas side connection circuit (70). The gas side connection pipe (70a) constituting the part extends between the plurality of gas side connection parts (64, 65), and the liquid side connection pipe (60a) constituting a part of the liquid side connection circuit (60) A connection unit (26) extending between the plurality of liquid side connection parts (61, 62) is provided, and the gas side connection part (64, 65) and the liquid side connection part (61, 62) of the connection unit (26) are provided. The outdoor gas side connection part (46) and the outdoor liquid side connection part (45) of the outdoor unit (23) of the plurality of air conditioners (14) are respectively connected to each set by refrigerant pipes. The gas side connection circuit (70) and the liquid-side connection circuit (60) is constituted by.

  In the twelfth invention, the gas side connection portions (64, 65) and the liquid side connection for connecting to the outdoor gas side connection portion (46) and the outdoor liquid side connection portion (45) of each outdoor unit (23). The first outdoor unit (23a) and the second outdoor unit (23b) are connected using the connection unit (26) in which the parts (61, 62) are formed. The first outdoor unit (23a) and the second outdoor unit (23b) are connected to the gas side connection (64, 65) of the connection unit (26) and the outdoor gas side connection (46) of each outdoor unit (23). The refrigerant pipes are connected, and the liquid side connection parts (61, 62) of the connection unit (26) and the outdoor liquid side connection parts (45) of the outdoor units (23) are connected by the refrigerant pipes. Connected by.

  In a thirteenth aspect of the present invention based on any one of the first to twelfth aspects of the present invention, the gas-side connection circuit (70) is configured to individually distribute the refrigerant between each outdoor gas-side connection section (46). The refrigerant flow between each gas-side on-off valve (74, 75, 76) for intermittent connection to the liquid-side connection circuit (60) and the liquid-side connection circuit (45) for each outdoor And a plurality of liquid-side on-off valves (71, 72, 73) for intermittent connection.

  In the thirteenth invention, the gas side connection circuit (70) is provided with a plurality of gas side on / off valves (74, 75, 76), and the liquid side connection circuit (60) is provided with a plurality of liquid side on / off valves (71, 72, 73). Each gas side on-off valve (74, 75, 76) individually interrupts the circulation of the refrigerant with each outdoor gas side connection (46). Each liquid side on-off valve (71, 72, 73) individually interrupts the circulation of the refrigerant with each outdoor liquid side connection part (45).

  The fourteenth invention is directed to an outdoor unit that houses an outdoor circuit (31) provided with a compressor (32) and an outdoor heat exchanger (33). In the outdoor circuit (31), the outdoor unit includes a pair of indoor gas side connection parts (19, 20) for connecting an indoor unit (24) provided with an indoor heat exchanger (56) and an indoor unit. Gas side branching in which a plurality of liquid side connection parts (39, 40) are formed and each indoor gas side connection part (19, 20) branches off from a gas side junction pipe (16) extending from the compressor (32) A liquid side branch pipe (37) which is an end portion of the pipe (17, 18) and the liquid side connection parts (39, 40) for each indoor branch from the liquid side junction pipe (36) extending from the outdoor heat exchanger (33). , 38), and in the outdoor circuit (31), a pair of outdoor gas side connection (46) and outdoor liquid side connection (45) for connecting other outdoor units (23). And a gas side extension pipe (48) extending from the outdoor gas side connection (46) extends to the gas side junction pipe (16) from the outdoor liquid side connection (45). Liquid side extension pipe (47) is connected to the liquid-side junction pipe (36).

  In the fourteenth invention, an indoor heat exchanger (56) is provided for each of a plurality of sets of indoor gas side connection portions (19, 20) and indoor liquid side connection portions (39, 40). Refrigerant that performs a refrigeration cycle by circulating the refrigerant discharged from the compressor (32) between each indoor heat exchanger (56) and the outdoor heat exchanger (33) by connecting the indoor units (24) respectively. It is possible to form the circuit (5), that is, to configure the air conditioner (14) as in the first invention. Then, by connecting the outdoor units (23) of the air conditioner (14) to each other by using a pair of the outdoor gas side connection part (46) and the outdoor liquid side connection part (45), the outdoor unit (23 ) Between the gas side merging pipes (16) and the liquid side merging pipes (36) can be configured as in the first aspect of the invention. That is, when the outdoor unit (23) of the fourteenth invention is used, the indoor heat exchanger (56) of one air conditioner (14) and the outdoor heat exchanger (33) of another air conditioner (14) It is possible to constitute an air conditioning system capable of performing a refrigeration cycle by circulating the refrigerant discharged from the compressor (32) of the other air conditioner (14).

  In each of the first to thirteenth inventions, each outdoor unit (23) is connected so that the gas side merging pipes (16) and the liquid side merging pipes (36) communicate with each other. (14), another air conditioner (14) between the indoor heat exchanger (56) of the air conditioner (14) and the outdoor heat exchanger (33) of the other air conditioner (14). The refrigerant discharged from the compressor (32) can be circulated to perform a refrigeration cycle. In other words, in the indoor unit (24) of each air conditioner (14), it is possible to perform air conditioning operation using the compressor (32) and the outdoor heat exchanger (33) of the other outdoor unit (23). It is. Therefore, even if the refrigerant cannot be supplied from the compressor (32) of the outdoor unit (23) to the indoor unit (24) in the air conditioner (14), the indoor unit (24) of the air conditioner (14) It is possible to avoid the situation in which the air conditioning operation cannot be performed.

  In the second aspect of the invention, even when the first air conditioner (14a) cannot perform the normal heating operation, the compressor (32b) and the outdoor heat exchanger ( The heating operation is performed in the indoor unit (24) of the first air conditioner (14a) using 33b). That is, for example, even if the compressor (32a) of the first air conditioner (14a) fails, the second heating operation is performed, so that the indoor unit (24) of the first air conditioner (14a) It is possible to perform heating operation. Therefore, even when the refrigerant cannot be supplied from the compressor (32a) of the outdoor unit (23a) to the indoor unit (24) in the first air conditioner (14a), the indoor unit of the first air conditioner (14a) (24) can avoid the situation where the heating operation cannot be performed.

  In the third aspect of the invention, in the second heating operation for the first air conditioner (14a), the refrigerant radiated by the indoor heat exchanger (56a) of the first air conditioner (14a) is the second air conditioner. The pressure is reduced by the heating pressure reducing valve (41) of the machine (14b). For this reason, since the ratio of the liquid component of the refrigerant | coolant which returns from a 1st air conditioner (14a) to a 2nd air conditioner (14b) increases, a 1st air conditioner (14a) to a 2nd air conditioner (14b) The pressure loss of the refrigerant returning to can be reduced. Therefore, it can suppress that the operating efficiency at the time of 2nd heating operation falls by pressure loss. In addition, if the heating pressure reducing valve (41) of the air conditioner (14) that cannot perform normal heating operation is closed during the second heating operation, the air conditioner (14) that cannot perform normal heating operation is closed. Liquid refrigerant can be prevented from accumulating in the outdoor heat exchanger (33).

  Moreover, in the said 4th invention, when a 1st air conditioner (14a) cannot perform normal heating operation by defrost operation, 2nd heating operation is performed. Therefore, the indoor unit (24) of the first air conditioner (14a) can continue the heating operation by the second heating operation even during the defrosting operation.

  In the sixth aspect of the invention, after the refrigerant used for defrosting in the first air conditioner (14a) evaporates in the outdoor heat exchanger (33b) of the second air conditioner (14b), the second air conditioner Into the compressor (32b) of the machine (14b). For this reason, the danger that the compressor (32b) of a 2nd air conditioner (14b) will be damaged by liquid compression can be reduced. Further, the enthalpy of the refrigerant sucked by the compressor (32b) of the second air conditioner (14b) is compared with the case where the refrigerant used for defrosting in the first air conditioner (14a) is not evaporated by the heat exchanger. The value of increases. Therefore, since the temperature of the refrigerant | coolant which the compressor (32b) of a 2nd air conditioner (14b) discharges becomes high, the defrost time in a 1st air conditioner (14a) can be shortened.

  In the seventh invention, the second heating operation is performed when the compressor (32a) becomes inoperable and the first air conditioner (14a) cannot perform the normal heating operation. Therefore, the indoor unit (24) of the first air conditioner (14a) can perform the heating operation by the second heating operation even if the compressor (32a) becomes inoperable.

  In the eighth aspect of the invention, the refrigerant that has dissipated heat in the indoor heat exchanger (56) during the first and second heating operations passes through the flow rate control valves (42, 43) in the outdoor unit (23). When the refrigerant passes through the flow control valves (42, 43), its pressure decreases. That is, the refrigerant radiated by the indoor heat exchanger (56) during the first and second heating operations returns to the outdoor unit (23), and then the pressure is reduced by the flow rate control valves (42, 43). For this reason, since the ratio of the liquid component of the refrigerant that radiates heat in the indoor heat exchanger (56) and returns to the outdoor unit (23) increases, the pressure loss of the refrigerant can be reduced, and the first and second heating operations It is possible to suppress a reduction in operating efficiency due to pressure loss.

  In the ninth aspect of the invention, the gas shut-off valve which is closed when the heating operation is stopped in the indoor unit (24) in each gas side branch pipe (17, 18) connected to each indoor unit (24). (8,9) is provided, so that even if the heating operation is performed in another indoor unit (24) of the same air conditioner (14), the indoor heat exchanger ( 56) prevents refrigerant from flowing in from the gas side.

  Here, in the conventional air conditioner in which a plurality of indoor units (24) are connected to the outdoor unit (23), after the heating operation is stopped in a certain indoor unit (24), other indoor units If the heating operation is performed in (24), even if the flow control valve (42, 43) corresponding to the indoor unit (24) that stopped the heating operation is closed, the indoors of the stopped indoor unit (24) The refrigerant flows into the heat exchanger (56) from the gas side and condenses. And a refrigerant | coolant accumulates in the indoor heat exchanger (56) of the indoor unit (24) in a stop, and there exists a possibility that a refrigerant | coolant may run short in another indoor unit (24). For this reason, in the conventional air conditioner, in order to make it difficult for the refrigerant to accumulate in the stopped indoor unit (24), the flow control valves (42, 43) corresponding to the stopped indoor unit (24) are slightly opened. A small amount of refrigerant was circulated through the stopped indoor unit (24). However, in this case, there is a problem that the heat of the refrigerant is wasted in the stopped indoor unit (24).

  On the other hand, in the ninth aspect of the invention, the indoor heat exchanger of the stopped indoor unit (24) even when the heating operation is performed in another indoor unit (24) of the same air conditioner (14). In (56), the gas shutoff valve (8, 9) prevents the refrigerant from flowing in from the gas side. Therefore, it is possible to prevent the refrigerant from accumulating in the stopped indoor unit (24), and to prevent wasteful heat consumption of the refrigerant in the stopped indoor unit (24). can do.

  In the tenth aspect of the invention, even if the first air conditioner (14a) cannot perform the normal cooling operation, the compressor (32b) and the outdoor heat exchanger ( The cooling operation is performed in the indoor unit (24) of the first air conditioner (14a) using 33b). That is, for example, even if the compressor (32a) of the first air conditioner (14a) fails, the indoor unit (24) of the first air conditioner (14a) can be operated by performing the second cooling operation. It is possible to perform cooling operation. Therefore, even when the refrigerant cannot be supplied from the compressor (32a) of the outdoor unit (23a) to the indoor unit (24) in the first air conditioner (14a), the indoor unit of the first air conditioner (14a) It is possible to avoid the situation where the cooling operation cannot be executed in (24).

  In the eleventh aspect of the invention, the second cooling operation is performed when the compressor (32a) becomes inoperable and the first air conditioner (14a) cannot perform the normal cooling operation. Therefore, the indoor unit (24) of the first air conditioner (14a) can perform the cooling operation by the second cooling operation even if the compressor (32) becomes inoperable.

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

<Overall configuration of air conditioning system>
The present embodiment is an air conditioning system (10) according to the present invention. As shown in FIG. 1, the air conditioning system (10) includes a first air conditioner (14a) and a refrigerant circuit (14) having a refrigerant circuit (5) that circulates a refrigerant and performs a vapor compression refrigeration cycle. A second air conditioner (14b) and a third air conditioner (14c) are provided. In the air conditioning system (10), these three air conditioners (14) are connected to each other by the connection unit (26), thereby forming one air conditioning circuit (15). The air conditioning circuit (15) is filled with a mixed refrigerant containing two or more HFC refrigerants such as R410A.

  In each air conditioner (14), a plurality of indoor units (24) are connected to the outdoor unit (23). Specifically, the first indoor unit (24a) and the second indoor unit (24b) are connected to the first outdoor unit (23a) of the first air conditioner (14a). The third indoor unit (24c) and the fourth indoor unit (24d) are connected to the second outdoor unit (23b) of the second air conditioner (14b). The fifth indoor unit (24e) and the sixth indoor unit (24f) are connected to the third outdoor unit (23c) of the third air conditioner (14c). The number of indoor units (24) connected to each outdoor unit (23) is merely an example.

《Outdoor unit》
An outdoor circuit (31) is accommodated in the outdoor unit (23). The outdoor circuit (31) is provided with a compressor (32), an outdoor heat exchanger (33), and a four-way switching valve (34).

  The compressor (32) is configured as, for example, a fully sealed high-pressure dome type scroll compressor. Electric power is supplied to the compressor (32) via an inverter. The compressor (32) is configured such that its operating capacity can be adjusted in stages by changing the output frequency of the inverter. The compressor (30) has a discharge side connected to the first port (P1) of the four-way switching valve (34) and a suction side connected to the second port (P2) of the four-way switching valve (34). .

  The outdoor heat exchanger (33) is a cross-fin type fin-and-tube heat exchanger. An outdoor fan (35) for sending outdoor air to the outdoor heat exchanger (33) is provided in the vicinity of the outdoor heat exchanger (33). In the outdoor heat exchanger (33), heat is exchanged between the refrigerant and the outdoor air. The gas side of the outdoor heat exchanger (33) is connected to the fourth port (P4) of the four-way switching valve (34). A liquid side junction pipe (36) constituting a part of the liquid line (13) is connected to the liquid side of the outdoor heat exchanger (33). The liquid line (13) extends from the liquid side of the outdoor heat exchanger (33) to each indoor heat exchanger (56) described later.

  The liquid side junction pipe (36) is provided with a first expansion valve (41) constituted by an electronic expansion valve having a variable opening. The first expansion valve (41) constitutes a heating pressure reducing valve (41). The liquid side junction pipe (36) is branched to the first liquid side branch pipe (37) and the second liquid side branch pipe (38) on the side opposite to the side connected to the outdoor heat exchanger (33). is doing. The first liquid side branch pipe (37) and the second liquid side branch pipe (38) constitute part of the liquid line (13).

  The first liquid side branch pipe (37) is connected to the first liquid side stop valve (39), and the second liquid side branch pipe (38) is connected to the second liquid side stop valve (40). Each liquid side shut-off valve (39, 40) constitutes an indoor liquid side connection (39, 40) for connecting the indoor unit (24). The first liquid side branch pipe (37) is provided with a second expansion valve (42), and the second liquid side branch pipe (38) is provided with a third expansion valve (43). The second expansion valve (42) and the third expansion valve (43) are electronic expansion valves with variable opening. The second expansion valve (42) and the third expansion valve (43) constitute a flow rate adjustment valve (42, 43). Each of the second expansion valve (42) and the third expansion valve (43) is closed when the air conditioning operation is stopped in the corresponding indoor unit (24).

  A gas side merging pipe (16) constituting a part of the gas line (12) is connected to the third port (P3) of the four-way switching valve (34). The gas line (12) extends from the gas side of the outdoor heat exchanger (33) to each indoor heat exchanger (56) described later. The gas side junction pipe (16) is branched to the first gas side branch pipe (17) and the second gas side branch pipe (18) on the opposite side to the side connected to the four-way switching valve (34). Yes. The first gas side branch pipe (17) and the second gas side branch pipe (18) constitute part of the gas line (12).

  The first gas side branch pipe (17) is connected to the first gas side on-off valve (19), and the second gas side branch pipe (18) is connected to the second gas side on-off valve (20). Each gas side on-off valve (19, 20) constitutes an indoor gas side connection (19, 20) for connecting the indoor unit (24), and constitutes a gas shut-off valve (8, 9). Yes. The first gas side on-off valve (19) and the second gas side on-off valve (20) are constituted by electromagnetic closing valves. Each of the first gas side on / off valve (19) and the second gas side on / off valve (20) is closed when the air conditioning operation is stopped in the corresponding indoor unit (24).

  In the outdoor unit (23), the gas side opening / closing valve (19, 20) and the liquid side closing valve (39, 40) are paired. Two sets of the gas-side on / off valves (19, 20) and the liquid-side stop valves (39, 40) are provided, but three or more sets may be provided.

  The four-way selector valve (34) is in a first state in which the first port (P1) and the third port (P3) communicate with each other and the second port (P2) and the fourth port (P4) communicate with each other (FIG. 1). And a second state (FIG. 1) in which the first port (P1) and the fourth port (P4) communicate with each other and the second port (P2) and the third port (P3) communicate with each other. (State indicated by a broken line).

  The outdoor unit (23) of the present embodiment is provided with a pair of outdoor liquid side closing valves (45) and an outdoor gas side closing valve (46) for connecting other outdoor units (23). . The outdoor liquid side closing valve (45) constitutes an outdoor liquid side connection part (45), and the outdoor gas side closing valve (46) constitutes an outdoor gas side connection part (46). A liquid side extension pipe (47) branched from the liquid side junction pipe (36) is connected to the outdoor liquid side shut-off valve (45). The liquid side extension pipe (47) branches off from a position on the indoor side of the first expansion valve (41). A gas side extension pipe (48) branched from the gas side junction pipe (16) is connected to the outdoor gas side shut-off valve (46).

  In the outdoor circuit (31) of the present embodiment, the liquid side junction pipe (36) and the gas side junction pipe (16) are connected by a hot gas bypass pipe (49). The hot gas bypass pipe (49) is connected between the outdoor heat exchanger (33) and the first expansion valve (41) in the liquid side merging pipe (36), and four ways in the gas side merging pipe (16). It is connected between the connection points of the switching valve (34) and the gas side extension pipe (48). The hot gas bypass pipe (49) is provided with a capillary tube (50) and a bypass on-off valve (51) in order from the liquid side merge pipe (36) side. The bypass on-off valve (51) is configured by an openable / closable solenoid valve. The capillary tube (50) is provided to take a differential pressure between the inlet side and the outlet side of the compressor (32).

《Indoor unit》
An indoor circuit (55) is accommodated in the indoor unit (24). The indoor circuit (55) is provided with an indoor gas side connector (58) at its gas side end, and with an indoor liquid side connector (57) at its liquid side end. Connected to the indoor gas side connector (58) is a gas side communication pipe connected to the gas side on-off valve (19, 20) of the outdoor unit (23). Connected to the indoor liquid side connector (57) is a liquid side communication pipe connected to the liquid side closing valve (39, 40) of the outdoor unit (23). The gas side communication pipe constitutes a part of the gas line (12), and the liquid side communication pipe constitutes a part of the liquid line (13).

  The indoor circuit (55) is connected to an indoor heat exchanger (56) configured by a cross fin type fin-and-tube heat exchanger. An indoor fan (59) for sending room air to the indoor heat exchanger (56) is provided in the vicinity of the indoor heat exchanger (56). In the indoor heat exchanger (56), heat is exchanged between the refrigerant and the room air.

《Connection unit》
The connection unit (26) accommodates a liquid side connection pipe (60a) and a gas side connection pipe (70a). The liquid side connection pipe (60a) constitutes a part of the liquid side connection circuit (60), and the gas side connection pipe (70a) constitutes a part of the gas side connection circuit (70). The liquid side connecting pipe (60a) and the gas side connecting pipe (70a) are independent of each other.

  The liquid side connection pipe (60a) connects the first liquid side connection part (61), the second liquid side connection part (62), and the third liquid side connection part (63) to each other. In the liquid side connection pipe (60a), the first connection side on-off valve (71) is connected to the pipe branched to the first liquid side connection part (61), and the pipe branched to the second liquid side connection part (62). The second connection side on-off valve (72) is provided with a third connection side on-off valve (73) in the pipe branched to the third liquid side connection portion (63). The first to third connection side on-off valves (71 to 73) constitute liquid side on-off valves (71, 72, 73). Each liquid side connection part (61-63) is connected to the outdoor liquid side shut-off valve (45) of the outdoor unit (23) via a refrigerant pipe constituting a part of the liquid side connection circuit (60). Yes.

  On the other hand, the gas side connection pipe (70a) connects the first gas side connection part (64), the second gas side connection part (65), and the third gas side connection part (66) to each other. In the gas side connection pipe (70a), the fourth connection side on-off valve (74) is connected to the pipe branched to the first gas side connection part (64), and the pipe branched to the second gas side connection part (65). A sixth connection-side on-off valve (76) is provided in the pipe branched from the fifth connection-side on-off valve (75) to the third gas-side connection portion (66). The fourth to sixth connection side on-off valves (74 to 76) constitute gas side on-off valves (74, 75, 76). Each gas side connection part (64-66) is connected to the outdoor gas side shut-off valve (46) of the outdoor unit (23) via a refrigerant pipe constituting a part of the gas side connection circuit (70). Yes.

-Operation of air conditioning system-
Below, the operation | movement operation | movement of the air conditioning system (10) of this embodiment is demonstrated.

<Cooling operation>
The flow of the refrigerant when the indoor unit (24) performs the cooling operation will be described. This air conditioning system (10) selectively performs two types of cooling operations on the air conditioner (14) as operations during the cooling operation of the indoor unit (24) of each air conditioner (14). Is possible. Hereinafter, the first cooling operation and the second cooling operation performed on the first air conditioner (14a) will be described. In addition, the 1-2 cooling operation performed with respect to a 2nd air conditioner (14b) and the 1-3 cooling operation performed with respect to a 3rd air conditioner (14c) are 1st cooling operation. It is the flow of the same refrigerant, and the 2-2 cooling operation performed on the second air conditioner (14b) and the second-3 cooling operation performed on the third air conditioner (14c) Since the refrigerant flow is the same as that in the second cooling operation, description thereof is omitted.

≪First cooling operation≫
First, the first cooling operation for the first air conditioner (14a) will be described with reference to FIG. In the first cooling operation, the four-way switching valve (34a) is set to the second state, and the first expansion valve (41a) is set to fully open. Further, the bypass on-off valve (51a) of the hot gas bypass pipe (49a) is set to a closed state.

  In this state, the first air conditioner (14a) performs a normal cooling operation by operating the compressor (32a) and the outdoor fan (35a). The indoor unit (24) that performs the cooling operation by the normal cooling operation operates the indoor fan (59a, 59b), and further, the second and third expansion valves (42a, 43a) corresponding to the indoor unit (24). Are superheat controlled so that the superheat degree of the refrigerant at the outlet of the indoor heat exchanger (56a, 56b) of the corresponding indoor unit (24) becomes a constant value (for example, 5 ° C.). The refrigerant flow rate of each indoor heat exchanger (56a, 56b) is adjusted by the second expansion valve (42a) and the third expansion valve (43a).

  In normal cooling operation, the outdoor heat exchanger (33a) of the first air conditioner (14a) serves as a condenser (radiator) and each indoor heat exchanger (56a, 56b) of the first air conditioner (14a). A vapor compression refrigeration cycle in which becomes an evaporator is performed. In this refrigeration cycle, the refrigerant discharged from the compressor (32a) of the first air conditioner (14a) flows into the outdoor heat exchanger (33a) of the first air conditioner (14a) and the first air conditioner (14a). ) Between each indoor heat exchanger (56a, 56b).

  Specifically, the refrigerant compressed by the compressor (32a) is discharged from the compressor (32a) and sent to the outdoor heat exchanger (33a) by the four-way switching valve (34a). In the outdoor heat exchanger (33a), the refrigerant dissipates heat to the outdoor air and condenses. The refrigerant condensed in the outdoor heat exchanger (33a) passes through the liquid side junction pipe (36) and branches into the first liquid side branch pipe (37a) and the second liquid side branch pipe (38a). The refrigerant distributed to the first liquid side branch pipe (37a) is depressurized by the second expansion valve (42a), and then absorbs heat from the indoor air by the indoor heat exchanger (56a) and evaporates. On the other hand, the refrigerant distributed to the second liquid side branch pipe (38a) is depressurized by the third expansion valve (43a) and then evaporates by absorbing heat from the indoor air in the indoor heat exchanger (56b). In each indoor unit (24), air cooled by the refrigerant is supplied into the room.

  The refrigerant evaporated in each indoor heat exchanger (56a, 56b) returns to the outdoor circuit (31a) and merges with the refrigerant evaporated in the other indoor heat exchanger (56a, 56b). The merged refrigerant is sucked into the compressor (32a) and compressed again.

  If the second and third air conditioners (14b, 14c) are in normal cooling operation, all the first to sixth connection side on-off valves (71 to 76) of the connection unit (26) are set to the open state. Is done. However, when the normal cooling operation is stopped in each of the second and third air conditioners (14b, 14c), the connection side opening / closing valves (72, 73, 72) corresponding to the air conditioners (14b, 14c) to be stopped are used. 75, 76) are set to the closed state. According to the cooling load of the indoor unit (24) of each air conditioner (14), the indoor unit (24b) of the other air conditioner (14b, 14c) 24), the refrigerant flow rate is balanced through the gas side connection circuit (70) and the liquid side connection circuit (60). In addition, you may set all the connection side on-off valves (71-76) of a connection unit (26) to a closed state so that a refrigerant | coolant may not distribute | circulate between air conditioners (14).

≪Second cooling operation≫
Next, the second cooling operation for the first air conditioner (14a) will be described with reference to FIG. This second cooling operation is performed when there is an abnormality in the compressor (32a) of the first air conditioner (14a), that is, when the first air conditioner (14a) cannot perform the normal cooling operation.

  In the second cooling operation, all the connection side on-off valves (71 to 76) of the connection unit (26) are set to the open state. The other settings are basically the same as in the first cooling operation. However, if the normal cooling operation is stopped in one of the second and third air conditioners (14b, 14c), the stopped air conditioner (14b, 14c) The connection side on-off valves (72, 73, 75, 76) corresponding to are set to the closed state. If there is a stopped air conditioner (14b, 14c), only the compressor (32b, 32c) is installed in the stopped air conditioner (14b, 14c) with the start of the second cooling operation. It may be activated. In this case, the connection side on-off valves (72, 73, 75, 76) corresponding to the air conditioners (14b, 14c) for starting the compressors (32b, 32c) are set to the open state.

  In the second cooling operation, the outdoor heat exchangers (33b, 33c) of the second and third air conditioners (14b, 14c) serve as condensers (heat radiators) and each room of the first air conditioner (14a). A vapor compression refrigeration cycle in which the heat exchanger (56a, 56b) serves as an evaporator is performed. In this refrigeration cycle, the refrigerant discharged from the compressors (32b, 32c) of the second and third air conditioners (14b, 14c) exchanges outdoor heat with the second and third air conditioners (14b, 14c). It circulates between each indoor heat exchanger (56a, 56b) of a heat exchanger (33b, 33c) and a 1st air conditioner (14a).

  Specifically, in the second and third air conditioners (14b, 14c), a part of the refrigerant condensed in the outdoor heat exchanger (33b, 33c) and flowing through the liquid side merge pipe (36b, 36c) is liquid. It flows into the side extension pipes (47b, 47c). The remaining refrigerant flowing through the liquid side merge pipe (36b, 36c) is supplied to each indoor heat exchanger (56) of the air conditioner (14b, 14c). In the second and third air conditioners (14b, 14c), the normal cooling operation is continued even after the start of the second cooling operation for the first air conditioner (14a).

  The refrigerant flowing into the liquid side extension pipe (47b) of the second air conditioner (14b) and the refrigerant flowing into the liquid side extension pipe (47c) of the third air conditioner (14c) are connected to the connection unit (26). It joins at the liquid side connecting pipe (60a) and flows into the liquid side joining pipe (36a) of the first air conditioner (14a) through the liquid side extension pipe (47a) of the first air conditioner (14a).

  In the first air conditioner (14a), the refrigerant flowing into the liquid side junction pipe (36a) branches into the first liquid side branch pipe (37a) and the second liquid side branch pipe (38a). The flow of the refrigerant branched into each liquid side branch pipe (37a, 37b) is the same as that in the first cooling operation. In each indoor unit (24a, 24b), the cooling operation is performed by evaporating the refrigerant supplied from the second and third air conditioners (14b, 14c) in the indoor heat exchanger (56a, 56b).

  The refrigerant returned from the indoor units (24a, 24b) to the outdoor unit (23a) flows into the gas side connection pipe (70a) of the connection unit (26) through the gas side extension pipe (48a). Part of the refrigerant that has flowed into the gas side connection pipe (70a) flows into the gas side junction pipe (16b) of the second air conditioner (14b) through the gas side extension pipe (48b), and the rest is the gas side extension pipe. It flows into the gas side merge pipe (16c) of the third air conditioner (14c) through (48c).

  In the second air conditioner (14b), the refrigerant flowing into the gas side merge pipe (16b) merges with the refrigerant evaporated in each indoor unit (24c, 24d), and then sucked into the compressor (32b) and again. Compressed. In addition, since the flow of the refrigerant | coolant which flowed into the gas side merge pipe (16b) of a 3rd air conditioner (14c) is the same as that of a 2nd air conditioner (14b), description is abbreviate | omitted. Thus, in the first air conditioner (14a), even if the compressor (32a) cannot be operated, the compressors (32 of the second and third air conditioners (14b, 14c)). ) And the outdoor heat exchanger (33), each indoor unit (24) can perform a cooling operation.

<Heating operation>
The flow of the refrigerant when the indoor unit (24) performs the heating operation will be described. In this embodiment, it is possible to selectively perform two types of heating operations on the air conditioner (14) as operations during the heating operation of the indoor unit (24) of each air conditioner (14). is there. Below, the 1st heating operation and 2nd heating operation performed with respect to a 1st air conditioner (14a) are each demonstrated. In addition, the 1-2 heating operation performed with respect to a 2nd air conditioner (14b) and the 1-3 heating operation performed with respect to a 3rd air conditioner (14c) are 1st heating operation. It is the flow of the same refrigerant, and the 2-2 heating operation performed for the second air conditioner (14b) and the 2-3 heating operation performed for the third air conditioner (14c) Since the refrigerant flow is the same as that in the second heating operation, the description thereof is omitted.

≪First heating operation≫
First, the 1st heating operation | movement with respect to a 1st air conditioner (14a) is demonstrated with reference to FIG. In the first heating operation, the four-way switching valve (34a) is set to the first state. Further, the first expansion valve (41a) is set to an open state. Further, the bypass on-off valve (51a) of the hot gas bypass pipe (49a) is set to a closed state.

  In this state, the first air conditioner (14a) performs the normal heating operation by operating the compressor (32a) and the outdoor fan (35a). The indoor unit (24) that performs the heating operation by the normal heating operation operates the indoor fan (59a, 59b), and further, the second and third expansion valves (42a, 43a) corresponding to the indoor unit (24). The subcool control is performed so that the degree of supercooling of the refrigerant at the outlet of the indoor heat exchanger (56a, 56b) of the corresponding indoor unit (24) becomes a constant value (for example, 5 ° C.). The opening of the first expansion valve (41a) is superheat controlled so that the degree of superheat of the refrigerant at the outlet of the outdoor heat exchanger (33a) becomes a constant value (for example, 5 ° C.). In normal heating operation, the first expansion valve (41a) mainly depressurizes the refrigerant condensed in the indoor heat exchanger (56a, 56b), and the refrigerant flow rate of each indoor heat exchanger (56a, 56b) is the second expansion valve. (42a) and the third expansion valve (43a).

  In normal heating operation, the outdoor heat exchanger (33a) of the first air conditioner (14a) serves as an evaporator, and each indoor heat exchanger (56a, 56b) of the first air conditioner (14a) serves as a condenser ( A vapor compression refrigeration cycle serving as a radiator is performed. In this refrigeration cycle, the refrigerant discharged from the compressor (32a) of the first air conditioner (14a) flows into the outdoor heat exchanger (33a) of the first air conditioner (14a) and the first air conditioner (14a). ) Between each indoor heat exchanger (56a, 56b).

  Specifically, the refrigerant compressed by the compressor (32a) is discharged from the compressor (32a), sent to the gas side junction pipe (16a) by the four-way switching valve (34a), and the first gas side branch Branches into a pipe (17a) and a second gas side branch pipe (18a). The refrigerant distributed to the first gas side branch pipe (17a) dissipates heat to the indoor air and condenses in the indoor heat exchanger (56a) of the first indoor unit (24a). On the other hand, the refrigerant distributed to the second gas side branch pipe (18a) dissipates heat to the indoor air and condenses in the indoor heat exchanger (56b) of the second indoor unit (24b). In each indoor unit (24), air heated by the refrigerant is supplied into the room.

  The refrigerant condensed in each indoor heat exchanger (56a, 56b) returns to the outdoor circuit (31a) and merges with the refrigerant condensed in the other indoor heat exchanger (56a, 56b), and then the first expansion valve (41a ). The refrigerant decompressed by the first expansion valve (41a) absorbs heat from the outdoor air and evaporates by the outdoor heat exchanger (33a), and is sucked into the compressor (32a) and compressed again.

  If the second and third air conditioners (14b, 14c) are in normal heating operation, all the first to sixth connection side on-off valves (71 to 76) of the connection unit (26) are set to the open state. Is done. However, when the normal heating operation is stopped in each of the second and third air conditioners (14b, 14c), the connection-side on / off valves (72, 73, 72) corresponding to the air conditioners (14b, 14c) to be stopped are used. 75, 76) are set to the closed state. Depending on the heating load of the indoor unit (24) of each air conditioner (14), the indoor unit (24b) of the first air conditioner (14a) 24), the refrigerant flow rate is balanced through the gas side connection circuit (70) and the liquid side connection circuit (60). In addition, you may set all the connection side on-off valves (71-76) of a connection unit (26) to a closed state so that a refrigerant | coolant may not distribute | circulate between air conditioners (14).

≪Second heating operation≫
Then, the 2nd heating operation | movement with respect to a 1st air conditioner (14a) is demonstrated with reference to FIG. This second heating operation is performed when there is an abnormality in the compressor (32a) of the first air conditioner (14a) and when the defrosting operation described later is performed in the first air conditioner (14a), that is, the first This is performed when the air conditioner (14a) cannot perform the normal heating operation.

  In the second heating operation, all the connection side on-off valves (71 to 76) of the connection unit (26) are set to the open state. The other settings are basically the same as in the first heating operation. However, if the normal heating operation is stopped in one of the second and third air conditioners (14b, 14c), the stopped air conditioner (14b, 14c) The connection side on-off valves (72, 73, 75, 76) corresponding to are set to the closed state. In addition, when there is a stopped air conditioner (14b, 14c), only the compressor (32b, 32c) in the stopped air conditioner (14b, 14c) is moved with the start of the second heating operation. It may be activated. In this case, the connection side on-off valves (72, 73, 75, 76) corresponding to the air conditioners (14b, 14c) for starting the compressors (32b, 32c) are set to the open state.

  In the second heating operation, the outdoor heat exchangers (33b, 33c) of the second and third air conditioners (14b, 14c) serve as evaporators, and the indoor heat exchangers of the first air conditioner (14a) ( A vapor compression refrigeration cycle in which 56a and 56b) become condensers is performed. In this refrigeration cycle, the refrigerant discharged from the compressors (32b, 32c) of the second and third air conditioners (14b, 14c) exchanges outdoor heat with the second and third air conditioners (14b, 14c). It circulates between each indoor heat exchanger (56a, 56b) of a heat exchanger (33b, 33c) and a 1st air conditioner (14a).

  Specifically, in the second and third air conditioners (14b, 14c), a part of the refrigerant discharged from the compressor (32b, 32c) and flowing through the gas side merge pipe (16b, 16c) is extended to the gas side. It flows into the pipe (48b, 48c). The remaining refrigerant flowing through the gas side merge pipe (16b, 16c) is supplied to each indoor heat exchanger (56) of the air conditioner (14b, 14c). In the second and third air conditioners (14b, 14c), the normal heating operation is continued even after the start of the second heating operation for the first air conditioner (14a).

  The refrigerant flowing into the gas side extension pipe (48b) of the second air conditioner (14b) and the refrigerant flowing into the gas side extension pipe (48c) of the third air conditioner (14c) are connected to the connection unit (26). It joins at the gas side connecting pipe (70a), and flows into the gas side joining pipe (16a) of the first air conditioner (14a) through the gas side extension pipe (48a) of the first air conditioner (14a).

  In the first air conditioner (14a), the refrigerant flowing into the gas side junction pipe (16a) branches into the first gas side branch pipe (17a) and the second gas side branch pipe (18a). The flow of the refrigerant branched into each liquid side branch pipe (37a, 37b) is the same as the first heating operation. In each indoor unit (24a, 24b), the refrigerant | coolant supplied from the 2nd and 3rd air conditioner (14b, 14c) condenses with an indoor heat exchanger (56a, 56b), and heating operation is performed.

  The refrigerant that has returned from the indoor units (24a, 24b) to the outdoor unit (23a) flows into the liquid side connection pipe (60a) of the connection unit (26) through the liquid side extension pipe (47a). Part of the refrigerant that has flowed into the liquid side connection pipe (60a) flows into the liquid side junction pipe (36b) of the second air conditioner (14b) through the liquid side extension pipe (47b), and the rest is the liquid side extension pipe. It flows into the liquid side junction pipe (36c) of the third air conditioner (14c) through (47c).

  In the second air conditioner (14b), the refrigerant flowing into the liquid side merge pipe (36b) merges with the refrigerant condensed in the indoor units (24c, 24d), and then decompressed by the first expansion valve (41b). The The refrigerant decompressed by the first expansion valve (41b) absorbs heat from the outdoor air by the outdoor heat exchanger (33b) and evaporates, and is sucked into the compressor (32b) and compressed again. In addition, since the flow of the refrigerant | coolant which flowed into the liquid side confluence | merging pipe | tube (36c) of a 3rd air conditioner (14c) is the same as that of a 2nd air conditioner (14b), description is abbreviate | omitted. Thus, in the first air conditioner (14a), even if the compressor (32a) cannot be operated, the compressors (32 of the second and third air conditioners (14b, 14c)). ) And the outdoor heat exchanger (33), the indoor unit (24) can perform the heating operation.

<Defrosting operation>
Each air conditioner (14) of the air conditioning system (10) of the present embodiment has a large amount of frost formation on the outdoor heat exchanger (33) of the air conditioner (14) during normal heating operation. The outdoor heat exchanger (33) is configured to perform a defrosting operation for melting frost. Below, the case where a 1st air conditioner (14a) performs a defrost operation is demonstrated with reference to FIG.

  In the first air conditioner (14a), when the defrosting operation is started, the bypass on-off valve (51a) of the hot gas bypass pipe (49a) is set to an open state. The first expansion valve (41a) is set to be fully closed. Further, the outdoor fan (35a) is stopped. When the compressor (32a) is operated in this state, the refrigerant circulates between the compressor (32a) and the outdoor heat exchanger (33a) in the first air conditioner (14a).

  Specifically, in the defrosting operation of the first air conditioner (14a), the refrigerant discharged from the compressor (32a) is sent to the gas-side merging pipe (16a) by the four-way switching valve (34a), and hot It flows into the gas bypass pipe (49a). The refrigerant flowing into the hot gas bypass pipe (49a) is decompressed by the capillary tube (50a) and then flows into the outdoor heat exchanger (33a) through the liquid side merge pipe (36a). In the outdoor heat exchanger (33a), the attached frost is melted by the high-temperature refrigerant. The refrigerant cooled by the outdoor heat exchanger (33a) is sucked into the compressor (32a) and compressed again.

  In the air conditioning system (10), when the first air conditioner (14a) performs the defrosting operation, the first heating is performed for the first air conditioner (14a) that performs the defrosting operation. Switching from the operation to the second heating operation is performed. In each indoor unit (24a, 24b) of the first air conditioner (14a), the heating operation is continued by the high-temperature refrigerant supplied from the second air conditioner (14b) and the third air conditioner (14c).

-Effect of the embodiment-
According to the said embodiment, since it connects so that between each outdoor unit (23) and gas side merge pipes (16) and liquid side merge pipes (36) may communicate, each air conditioner (14 ), The compressor of the other air conditioner (14) between the indoor heat exchanger (56) of the air conditioner (14) and the outdoor heat exchanger (33) of the other air conditioner (14). It is possible to perform the refrigeration cycle by circulating the refrigerant discharged from (32). In other words, in the indoor unit (24) of each air conditioner (14), it is possible to perform air conditioning operation using the compressor (32) and the outdoor heat exchanger (33) of the other outdoor unit (23). It is. Therefore, even if the refrigerant cannot be supplied from the compressor (32) of the outdoor unit (23) to the indoor unit (24) in the air conditioner (14), the indoor unit (24) of the air conditioner (14) It is possible to avoid the situation in which the air conditioning operation cannot be performed.

  Moreover, in the said embodiment, even if it is a case where a 1st air conditioner (14a) cannot perform normal heating operation, the compressor (32b, 32c) of a 2nd and 3rd air conditioner (14b, 14c) and Heating operation is performed in the indoor unit (24) of the first air conditioner (14a) using the outdoor heat exchangers (33b, 33c). For example, even when the compressor (32a) of the first air conditioner (14a) fails or when the first air conditioner (14a) performs a defrosting operation, the second heating operation is performed. The heating operation can be performed in the indoor unit (24) of the first air conditioner (14a). In addition, even when the compressor (32b) of the second air conditioner (14b) fails or when the second air conditioner (14b) performs a defrosting operation, the first and third air conditioners By performing the 2-2 heating operation using the compressor (32a, 32c) and the outdoor heat exchanger (33a, 33c) of (14a, 14c), the indoor unit (24 of the second air conditioner (14b)) ) Heating operation is performed. Even if the compressor (32c) of the third air conditioner (14c) breaks down or the third air conditioner (14c) performs a defrosting operation, the first and second air conditioners By performing the 2-3 heating operation using the compressor (32a, 32b) and the outdoor heat exchanger (33a, 33b) of (14a, 14b), the indoor unit (24 of the third air conditioner (14c)) ) Heating operation is performed. In each air conditioner (14), even when refrigerant cannot be supplied from the compressor (32) of the outdoor unit (23) to the indoor unit (24), the indoor unit (24 of the air conditioner (14) ) Can avoid the situation where the heating operation cannot be performed.

  Moreover, in the said embodiment, in the 2nd heating operation | movement with respect to a 1st air conditioner (14a), the refrigerant | coolant thermally radiated with the indoor heat exchanger (56a) of the 1st air conditioner (14a) is the 2nd air conditioner ( The pressure is reduced by the pressure reducing valve (41) for heating in 14b). For this reason, since the ratio of the liquid component of the refrigerant | coolant which returns from a 1st air conditioner (14a) to a 2nd air conditioner (14b) increases, a 1st air conditioner (14a) to a 2nd air conditioner (14b) The pressure loss of the refrigerant returning to can be reduced. Therefore, it can suppress that the operating efficiency at the time of 2nd heating operation falls by pressure loss. In addition, if the first pressure reducing valve (41) of the air conditioner (14) that cannot perform the normal heating operation due to a failure of the compressor (32) or the like is closed during the second heating operation, the normal heating operation is not performed. It is possible to prevent liquid refrigerant from accumulating in the outdoor heat exchanger (33) of the air conditioner (14) that cannot be executed. Even during the second cooling operation, the first pressure reducing valve (41) of the air conditioner (14) that cannot perform the normal cooling operation due to a failure of the compressor (32) or the like is closed.

  Moreover, in the said embodiment, when the 1st air conditioner (14a) cannot perform normal heating operation by defrost operation, 2nd heating operation is performed. Therefore, the indoor unit (24) of the first air conditioner (14a) can continue the heating operation by the second heating operation even during the defrosting operation.

  In the above embodiment, the second heating operation is performed when the compressor (32a) becomes inoperable and the first air conditioner (14a) cannot perform the normal heating operation. Therefore, the indoor unit (24) of the first air conditioner (14a) can perform the heating operation by the second heating operation even if the compressor (32a) becomes inoperable.

  Moreover, in the said embodiment, the refrigerant | coolant thermally radiated with the indoor heat exchanger (56) during the 1st and 2nd heating operation | movement passes a flow control valve (42, 43) by the outdoor unit (23). When the refrigerant passes through the flow control valves (42, 43), its pressure decreases. That is, the refrigerant radiated by the indoor heat exchanger (56) during the first and second heating operations returns to the outdoor unit (23), and then the pressure is reduced by the flow rate control valves (42, 43). For this reason, since the ratio of the liquid component of the refrigerant that radiates heat in the indoor heat exchanger (56) and returns to the outdoor unit (23) increases, the pressure loss of the refrigerant can be reduced, and the first and second heating operations It is possible to suppress a reduction in operating efficiency due to pressure loss.

  Further, in the above embodiment, the gas cutoff valve (8) that is closed when the heating operation is stopped in the indoor unit (24) in each gas side branch pipe (17, 18) connected to each indoor unit (24). , 9), the indoor heat exchanger (56) of the stopped indoor unit (24) even if heating operation is performed in another indoor unit (24) of the same air conditioner (14) Further, the refrigerant is prevented from flowing in from the gas side. Therefore, it is possible to prevent the refrigerant from accumulating in the stopped indoor unit (24), and to prevent wasteful heat consumption of the refrigerant in the stopped indoor unit (24). can do.

  In the above embodiment, even if the first air conditioner (14a) cannot perform the normal cooling operation, the compressors (32b, 32c) of the second and third air conditioners (14b, 14c) and Cooling operation is performed in the indoor unit (24) of the first air conditioner (14a) using the outdoor heat exchangers (33b, 33c). For example, even if the compressor (32a) of the first air conditioner (14a) fails, the second air conditioning operation is performed to cool the indoor air unit (24a) of the first air conditioner (14a). It is possible to drive. Even if the compressor (32b) of the second air conditioner (14b) fails, the compressor (32a, 32c) and the outdoor heat exchange of the first and third air conditioners (14a, 14c) By performing the 2-2 cooling operation using the chambers (33a, 33c), the cooling operation is performed in the indoor unit (24) of the second air conditioner (14b). Even if the compressor (32c) of the third air conditioner (14c) fails, the compressor (32a, 32b) and the outdoor heat exchange of the first and second air conditioners (14a, 14b) The cooling operation is performed in the indoor unit (24) of the third air conditioner (14c) by performing the 2-3 cooling operation using the coolers (33a, 33b). In each air conditioner (14), even when refrigerant cannot be supplied from the compressor (32) of the outdoor unit (23) to the indoor unit (24), the indoor unit (24 of the air conditioner (14) ) Can avoid the situation where the cooling operation cannot be executed.

  In the above embodiment, the second cooling operation is performed when the compressor (32a) becomes inoperable and the first air conditioner (14a) cannot perform the normal cooling operation. Therefore, the indoor unit (24) of the first air conditioner (14a) can perform the cooling operation by the second cooling operation even if the compressor (32) becomes inoperable.

  Moreover, in the said embodiment, between the three outdoor units (23), the gas side connection part (64-66) of a connection unit (26) and the outdoor side gas side closing valve (46) of each outdoor unit (23) Between the liquid side connection (61 to 63) of the connection unit (26) and the outdoor liquid side shut-off valve (45) of each outdoor unit (23). Connected by. The connection unit (26) is provided with a liquid side connection pipe (60a) and a gas side connection pipe (70a) in which pipes are connected so as to be branched with respect to each outdoor unit (23). For this reason, when connecting between the outdoor units (23) in the installation work of the air conditioning system (10), it is not necessary to configure a branching pipe for each outdoor unit (23), so the installation work is facilitated. can do. Moreover, each connection side on-off valve (71-76) is not exposed outdoors but is accommodated in the connection unit (26). For this reason, the reliability of each connection side on-off valve (71-76) can be improved.

-Modification of the embodiment-
A modification of this embodiment will be described. In each air conditioner (14) of this modification, as shown in FIG. 7, a gas side communication pipe (53) is provided instead of the hot gas bypass pipe (49) of the above embodiment. Below, a different point from the said embodiment is demonstrated.

  One end of the gas side communication pipe (53) is connected to the gas side junction pipe (16), and the other end is connected to the second port (P2) of the four-way switching valve (34) and the suction side of the compressor (32). Connected between. The gas side communication pipe (53) is for communicating the gas side merge pipe (16) and the gas side of the outdoor heat exchanger (33) during the defrosting operation. The other end of the gas side communication pipe (53) may be connected between the fourth port (P4) of the four-way switching valve (34) and the outdoor heat exchanger (33).

  The gas side communication pipe (53) is provided with a communication open / close valve (54) and a capillary tube (50) in order from the gas side merge pipe (16) side. The communication on-off valve (54) is an openable / closable solenoid valve. The gas side communication pipe (53) may not have the capillary tube (50).

  The operation of the air conditioning system (10) of this modification is different from the above embodiment only in the defrosting operation. The air conditioner (14) that performs the defrosting operation is switched from the first heating operation to the second heating operation (switching from the 1-2 heating operation to the 2-2 heating operation, Switching from the 3 heating operation to the 2-3 heating operation) is the same as the above embodiment.

  In the air conditioner (14) performing the defrosting operation, the outdoor fan (35) is stopped, the four-way selector valve (34) is set to the first state, and the communication on-off valve (54a) is set to the open state. Is done. Note that the communication on-off valve (54) is set to a closed state during a time other than the defrosting operation. In the air conditioner (14) that performs the defrosting operation, the compressor (32) is stopped and the first expansion valve (41) is maintained at a constant opening. Below, the flow of the refrigerant | coolant regarding the defrost operation of a 1st air conditioner (14a) is demonstrated with reference to FIG. In addition, when there is an air conditioner (14b, 14c) in which the normal heating operation is stopped, the connection side opening / closing valve corresponding to the stopped air conditioner (14b, 14c) with the start of the defrosting operation (72, 73, 75, 76) may be set to an open state, and only the compressor (32b, 32c) may be activated in the air conditioner (14b, 14c).

  In the first air conditioner (14a), the gas side merging pipe (16a) of the first air conditioner (14a) is passed through the gas side connection circuit (70) in association with the second heating operation for the first air conditioner (14a). Part of the refrigerant discharged from the compressor (32b, 32c) of the second and third air conditioners (14b, 14c) supplied to is supplied to the outdoor heat exchanger (33a) through the gas side communication pipe (53a) Is done. In the outdoor heat exchanger (33a), the attached frost is melted by the high-temperature refrigerant. On the other hand, the remaining refrigerant discharged from the compressors (32b, 32c) of the second and third air conditioners (14b, 14c) supplied to the first air conditioner (14a) is sent to the indoor units (24a, 24b). Supplied and condensed in each indoor heat exchanger (56a, 56b) and returns to the outdoor circuit (31a).

  The refrigerant radiated to frost in the outdoor heat exchanger (33a) merges with the refrigerant condensed in each indoor heat exchanger (56a, 56b), and then the second and third air conditioners through the liquid side connection circuit (60). Return to the liquid side junction pipe (36b, 36c) of (14b, 14c). In the second air conditioner (14b), the refrigerant that has returned to the liquid side merge pipe (36b) evaporates in the outdoor heat exchanger (33b) and then sucks into the compressor (32b) of the second air conditioner (14b). Is done. In addition, the flow of the refrigerant | coolant which returned to the 3rd air conditioner (14c) is the same as that of a 2nd air conditioner (14b).

  In this modification, during the defrosting operation of the first air conditioner (14a), the outdoor heat exchanger (33a) of the first air conditioner (14a) and the second and third air conditioners (14b, 14c). ) Circulates between the outdoor heat exchangers (33b, 33c) and the outdoor heat exchanger (33a) of the first air conditioner (14a) serves as a radiator and the second and third air conditioners. A refrigeration cycle is performed in which the outdoor heat exchangers (33b, 33c) of (14b, 14c) serve as an evaporator. For this reason, compared with the defrost operation of the said embodiment in which the heat exchanger used as an evaporator does not exist, the coefficient of performance of the refrigerating cycle of a defrost operation can be improved.

  Further, in this modified example, unlike the defrosting operation of the above embodiment, the refrigerant used for defrosting in the first air conditioner (14a) is replaced with the outdoor heat exchanger (33b) of the second air conditioner (14b). ) And then sucked into the compressor (32b) of the second air conditioner (14b). For this reason, the danger that the compressor (32b) of a 2nd air conditioner (14b) will be damaged by liquid compression can be reduced.

  Further, the enthalpy of the refrigerant sucked by the compressor (32b) of the second air conditioner (14b) is compared with the case where the refrigerant used for defrosting in the first air conditioner (14a) is not evaporated by the heat exchanger. The value of increases. Therefore, since the temperature of the refrigerant | coolant which the compressor (32b) of a 2nd air conditioner (14b) discharges becomes high, the defrost time in a 1st air conditioner (14a) can be shortened.

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  About the said embodiment, the 2nd expansion valve (42) and the 3rd expansion valve (43) are arrange | positioned at the liquid side of the indoor heat exchanger (56) in each indoor unit (24) instead of the outdoor unit (23). May be. When the second expansion valve (42) and the third expansion valve (43) are arranged in the indoor unit (24), the pressure loss of the refrigerant in the liquid side communication pipe during the cooling operation can be reduced.

  Moreover, in the said embodiment, although each gas side on-off valve (19,20) is combined with the indoor gas side connection part (19,20) and the gas cutoff valve (8,9), each gas side The on-off valve (19, 20) may be configured by a manual closing valve, and a gas cutoff valve (8, 9) configured by an electromagnetic valve may be separately installed in the gas side branch pipe (17, 18).

  Moreover, about the said embodiment, each air conditioner (14) may be comprised so that only normal heating operation | movement may be performed among normal cooling operation and normal heating operation. In this case, each air conditioner (14) is not provided with a four-way switching valve (34) for switching between cooling and heating. In each air conditioner (14), the discharge side of the compressor (32) always communicates with the indoor heat exchanger (56), and the suction side of the compressor (32) always communicates with the outdoor heat exchanger (33).

  Moreover, about the said embodiment, each air conditioner (14) may be comprised so that only normal cooling operation may be performed among normal cooling operation and normal heating operation. In this case, each air conditioner (14) is not provided with a four-way switching valve (34) for switching between cooling and heating. In each air conditioner (14), the discharge side of the compressor (32) always communicates with the outdoor heat exchanger (33), and the suction side of the compressor (32) always communicates with the indoor heat exchanger (56).

In the above embodiments, the refrigerant filled in the air conditioning circuit (15), one _C 3 _H m _{F n} refrigerant (molecular formula _{1: C 3 H m F n} ( where, m and n are 1 to 5 And a mixed refrigerant consisting of one or two or more HFC refrigerants and a refrigerant having a single double bond in the molecular structure). Good. The “HFC refrigerant” represents a hydrofluorocarbon-based refrigerant that does not contain a C ₃ H _m F _n refrigerant. This mixed refrigerant is preferably such that the proportion of the C ₃ H _m F _n refrigerant is 70% by mass or more and 94% by mass or less and the proportion of the HFC refrigerant is 6% by mass or more and 30% by mass or less.

Also, in this mixed _refrigerant, as C ₃ H m _{F n} refrigerant, it referred to as 2,3,3,3-tetrafluoro-1-propene (HFO-1234yf, a chemical formula thereof is represented by _CF 3 -CF = CH ₂ ), 1,2,3,3,3-pentafluoro-1-propene (referred to as HFO-1225ye, the chemical formula is represented by CF ₃ CF═CHF), 1,3,3,3-tetrafluoro -1-propene (referred to as HFO-1234ze, the chemical formula is represented by CF ₃ —CH═CHF), 1,2,3,3-tetrafluoro-1-propene (referred to as HFO-1234ye, the chemical formula is CHF) represented by ₂ -CF = CHF.), referred to as 3,3,3-trifluoro-1-propene (HFO-1243zf, a chemical formula thereof is represented by _{CF 3 -CH = CH 2.)} , 1,2 , 2-trif Oro-1-propene (a chemical formula thereof is represented by _{CH 3 -CF = CF 2.)} , 2- fluoro-1-propene (a chemical formula thereof is represented by _CH 3 -CF = _{CH 2.)} Any one of Can be used.

In this mixed refrigerant, HFC-32 (difluoromethane) can be used as the HFC refrigerant. In this _case, preferably if C ₃ H m _{F n} refrigerant is 77 wt% or more 87 wt% HFC-32 ratio is less 23 mass% 13 mass% or more of the _following, the ratio of C ₃ H m _{F n} refrigerant 77 It is more preferable that the ratio of HFC-32 is 21% by mass or more and 23% by mass or less in the range of mass% to 79% by mass. For example, a mixed refrigerant in which the ratio of HFO-1234yf is 78.2% by mass and the ratio of HFC-32 is 21.8% by mass can be used.

  In this mixed refrigerant, HFC-125 (pentafluoroethane) can be used as the HFC refrigerant. In this case, the proportion of HFC-125 in the mixed refrigerant is preferably 10% by mass or more, and more preferably 20% by mass or less.

  In this mixed refrigerant, two or more types of HFC refrigerants may be used. Specifically, a mixed refrigerant using two types of HFC-125 and HFC-32 can be used as the HFC refrigerant.

  In this mixed refrigerant, a refrigerant other than HFC-32 and HFC-125 can also be used as the HFC refrigerant. Specifically, as the HFC refrigerant, HFC-134 (1,1,2,2-tetrafluoroethane), HFC-134a (1,1,1,2-tetrafluoroethane), HFC-143a (1,1 , 1-trifluoroethane), HFC-152a (1,1-difluoroethane), HFC-161 (fluoroethane), HFC-227ea (1,1,1,2,3,3,3-heptafluoropropane), HFC-236ea (1,1,1,2,3,3-hexafluoropropane), HFC-236fa (1,1,1,3,3,3-hexafluoropropane), HFC-365mfc (1,1, 1,3,3-pentafluorobutane) can be used.

In the above embodiments, it is possible to use a mixed refrigerant containing a hydrocarbon and C ₃ H _m F _n refrigerant. Specifically, methane, ethane, propane, propene, butane, isobutane, pentane, 2-methylbutane, and cyclopentane can be used as the hydrocarbon refrigerant used for the mixed refrigerant. The hydrocarbon refrigerant may be one type or a plurality of types. _Further, it is possible to use a mixed refrigerant containing the C ₃ H m _{F n} refrigerant and dimethyl ether. Also, a mixed refrigerant containing C ₃ H _m F _n refrigerant and bis-trifluoromethyl-sulfide can be used. Further, a mixed refrigerant containing a C ₃ H _m F _n refrigerant and helium can be used. Alternatively, a mixed refrigerant containing HFO-1234yf and carbon dioxide can be used.

In the embodiment, a single refrigerant composed of only one component of the above-described refrigerants such as the C ₃ H _m F _n refrigerant, the HFC refrigerant, hydrocarbon, carbon dioxide, or the like may be used.

  In the above embodiment, the air conditioning system (10) may be configured to perform a supercritical cycle in which the high pressure of the refrigeration cycle is set to a value higher than the critical pressure of the refrigerant. In this case, for example, a single refrigerant of carbon dioxide is used as the refrigerant, and in a normal refrigeration cycle in which the high pressure of the refrigeration cycle is set to a value lower than the critical pressure of the refrigerant, a heat exchanger that serves as a condenser serves as a gas cooler. Operate.

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

  As described above, the present invention is useful for an air conditioning system including an air conditioner in which a plurality of indoor units are connected to an outdoor unit, and an outdoor unit of the air conditioning system.

1 is a schematic configuration diagram of an air conditioning system according to an embodiment of the present invention. It is a schematic block diagram showing the refrigerant | coolant flow at the time of the 1st air_conditionaing | cooling operation | movement of the air conditioning system in embodiment. It is a schematic block diagram showing the flow of the refrigerant at the time of the 2nd air conditioning operation of the air-conditioning system in an embodiment. It is a schematic block diagram showing the flow of the refrigerant at the time of the 1st heating operation of the air-conditioning system in an embodiment. It is a schematic block diagram showing the flow of the refrigerant at the time of the 2nd heating operation of the air-conditioning system in an embodiment. It is a schematic structure figure showing the flow of the refrigerant at the time of defrosting operation of the air-conditioning system in an embodiment. It is a schematic block diagram of the air conditioning system which concerns on the modification of embodiment of this invention. It is a schematic block diagram showing the flow of the refrigerant at the time of defrosting operation of the air-conditioning system in the modification of an embodiment.

Explanation of symbols

10 Air conditioning system
14a First air conditioner
14b 2nd air conditioner
16 Gas side merge pipe
23 Outdoor unit
24 indoor units
32 Compressor
33 Outdoor heat exchanger
36 Liquid side merge pipe
45 Outdoor liquid side shut-off valve (outdoor liquid side connection)
46 Outdoor gas side shutoff valve (outdoor gas side connection)
47 Liquid extension tube
48 Gas side extension pipe
56 Indoor heat exchanger
60 Liquid side connection pipe
61 Gas side connection pipe

Claims (14)

With multiple air conditioners (14)
Each air conditioner (14) includes an outdoor unit (23) provided with a compressor (32) and an outdoor heat exchanger (33), and a plurality of indoor units each provided with an indoor heat exchanger (56). An air conditioning system comprising a refrigerant circuit (5) formed by a unit (24) and configured to perform a refrigeration cycle by circulating refrigerant in the refrigerant circuit (5),
A part of the refrigerant circuit (5) of each air conditioner (14) accommodated in the outdoor unit (23) has a plurality of gas side branch pipes connected to the indoor units (24) one by one. (17,18), gas side junction pipes (16) for connecting all gas side branch pipes (17,18) to the compressor (32), and one for each indoor unit (24) A plurality of connected liquid side branch pipes (37, 38) and a liquid side junction pipe (36) for connecting all the liquid side branch pipes (37, 38) to the outdoor heat exchanger (33) Provided,
The outdoor unit (23) of each air conditioner (14) has a gas side extension pipe having one end connected to the gas side merge pipe (16) and the other end constituting an outdoor gas side connection (46). (48) and a liquid side extension pipe (47) having one end connected to the liquid side junction pipe (36) and the other end constituting the outdoor liquid side connection part (45),
A gas side connection circuit (70) for connecting the outdoor gas side connection portions (46) of the outdoor units (23) to each other;
An air conditioning system comprising: a liquid side connection circuit (60) for connecting the outdoor liquid side connection portions (45) of the outdoor units (23) to each other. In claim 1,
Each air conditioner (14) performs a normal heating operation in which the refrigerant discharged from the compressor (32) of the refrigerant circuit (5) dissipates heat in the indoor heat exchanger (56) of the refrigerant circuit (5). While configured to be possible
A first heating operation in which a first air conditioner (14a) that is one of the plurality of air conditioners (14) performs the normal heating operation;
When the first air conditioner (14a) cannot perform the normal heating operation, the compressor (5b) of the refrigerant circuit (5b) of the second air conditioner (14b) different from the first air conditioner (14a) ( The indoor heat exchanger of the refrigerant circuit (5a) of the first air conditioner (14a) is supplied to the refrigerant discharged from 32b) using the gas side connection circuit (70) and the liquid side connection circuit (60). An air conditioning system characterized in that the second heating operation for supplying heat to (56a) and dissipating heat can be executed. In claim 2,
The liquid side junction pipe (36) of each air conditioner (14) is provided with a heating pressure reducing valve (41) for reducing the pressure of the refrigerant radiated by the indoor heat exchanger (56) during the normal heating operation. The liquid-side extension pipe (47) is connected to a position closer to the indoor heat exchanger (56) than the heating pressure reducing valve (41). In claim 2 or 3,
The first air conditioner (14a) removes frost adhering to the outdoor heat exchanger (33) during the normal heating operation from the first air conditioner (14a) or the second air conditioner (14b). While configured to be able to perform a defrosting operation to be melted by the refrigerant discharged from the compressor (32),
An air conditioning system configured to perform the second heating operation when the first air conditioner (14a) performs a defrosting operation. In claim 4,
The refrigerant circuit (5a) of the first air conditioner (14a) includes a compressor (32a) side and a liquid side of the gas side merging pipe (16a) from the connecting part of the gas side extension pipe (48a). A hot gas bypass pipe (49a) connecting the outdoor heat exchanger (33a) side of the junction pipe (36a) to the outdoor heat exchanger (33a) side rather than a connection point of the liquid side extension pipe (47a), and the hot gas bypass pipe (49a) And a bypass on-off valve (51a) for opening and closing
In the defrosting operation of the first air conditioner (14a), the bypass on-off valve (51a) is set in an open state, and the refrigerant discharged from the compressor (32a) passes through the hot gas bypass pipe (49a). An air conditioning system, wherein the air conditioning system is supplied to the outdoor heat exchanger (33a). In claim 4,
The refrigerant circuit (5a) of the first air conditioner (14a) communicates with the gas side merge pipe (16a) and the gas side of the outdoor heat exchanger (33a) during the defrosting operation. A gas side communication pipe (53a) and a communication on-off valve (54a) for opening and closing the gas side communication pipe (53a),
In the defrosting operation of the first air conditioner (14a), the communication on-off valve (54a) is set in an open state, and the second heating operation is performed through the gas side connection circuit (70). Part of the refrigerant discharged from the compressor (32b) of the second air conditioner (14b) supplied to the gas side merge pipe (16a) of the first air conditioner (14a) passes through the gas side communication pipe (53a). An air conditioning system, wherein the air conditioning system is supplied to the outdoor heat exchanger (33a). In any one of Claims 2 thru | or 6,
An air conditioning system configured to perform the second heating operation when the compressor (32a) of the first air conditioner (14a) becomes inoperable. In any one of Claims 2 thru | or 7,
Each liquid side branch pipe (37, 38) of each air conditioner (14) has a flow rate control valve (42, 43) for adjusting the refrigerant flow rate of the liquid side branch pipe (37, 38). An air conditioning system characterized by being provided. In claim 8,
The gas side branch pipes (17, 18) of the air conditioners (14) include the same indoor heat exchanger (56 as the gas side branch pipes (17, 18) during the first and second heating operations. Gas shut-off valves (8, 9) that are closed when the flow control valves (42, 43) of the liquid side branch pipes (37, 38) connected to Air conditioning system. In any one of Claims 1 thru | or 9,
Each air conditioner (14) performs a normal cooling operation in which the refrigerant discharged from the compressor (32) of the refrigerant circuit (5) is evaporated by the indoor heat exchanger (56) of the refrigerant circuit (5). While configured to be possible
A first cooling operation in which a first air conditioner (14a) which is one of the plurality of air conditioners (14) performs the normal cooling operation;
When the first air conditioner (14a) cannot perform the normal cooling operation, the compressor (5b) of the refrigerant circuit (5b) of the second air conditioner (14b) different from the first air conditioner (14a) ( The indoor heat exchanger of the refrigerant circuit (5a) of the first air conditioner (14a) is supplied to the refrigerant discharged from 32b) using the gas side connection circuit (70) and the liquid side connection circuit (60). The air-conditioning system is characterized in that the second air-cooling operation that supplies the refrigerant to (56a) and evaporates the refrigerant in the indoor heat exchanger (56a) can be performed. In claim 10,
An air conditioning system configured to perform the second cooling operation when the compressor (32a) of the first air conditioner (14a) becomes inoperable. In any one of Claims 1 thru | or 11,
Connected to the gas side connection part (64, 65) for connecting to the outdoor gas side connection part (46) of the outdoor unit (23) and the liquid side connection part (45) for outdoor use of the outdoor unit (23) A plurality of liquid side connection portions (61, 62) for forming a gas side connection pipe (70a) constituting a part of the gas side connection circuit (70). , 65), and a connection unit (26) in which a liquid side connection pipe (60a) constituting a part of the liquid side connection circuit (60) extends between a plurality of liquid side connection parts (61, 62) With
The outdoor unit (23) of the plurality of air conditioners (14) with respect to each set of the gas side connection (64, 65) and the liquid side connection (61, 62) of the connection unit (26) The gas side connection circuit (70) and the liquid side connection circuit (60) are configured by connecting the gas side connection part (46) and the outdoor liquid side connection part (45) with refrigerant pipes, respectively. An air conditioning system characterized by In any one of claims 1 to 12,
In the gas side connection circuit (70), a plurality of gas side on-off valves (74, 75, 76) for individually interrupting the circulation of the refrigerant between each outdoor gas side connection part (46),
The liquid side connection circuit (60) includes a plurality of liquid side opening / closing valves (71, 72, 73) for individually interrupting the circulation of the refrigerant between the outdoor liquid side connection portions (45). An air conditioning system characterized by being provided. An outdoor unit for accommodating an outdoor circuit (31) provided with a compressor (32) and an outdoor heat exchanger (33),
In the outdoor circuit (31), a pair of indoor gas side connections (19, 20) and an indoor liquid side connection (for connecting an indoor unit (24) provided with an indoor heat exchanger (56) ( 39, 40) are formed in plural sets, and the gas side branch pipes (17, 18) in which the indoor gas side connection parts (19, 20) branch from the gas side junction pipe (16) extending from the compressor (32) are formed. The ends of the liquid side branch pipes (37, 38) branching from the liquid side junction pipes (36) extending from the outdoor heat exchanger (33) with the liquid side connection parts (39, 40) for indoor use. Part
Furthermore, in the outdoor circuit (31), a pair of outdoor gas side connection portions (46) and an outdoor liquid side connection portion (45) for connecting other outdoor units (23) are formed. A gas side extension pipe (48) extending from the gas side connection section (46) is connected to the gas side junction pipe (16), and a liquid side extension pipe (47) extending from the outdoor liquid side connection section (45) is connected to the liquid side. An outdoor unit connected to the junction pipe (36).

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