JP2008116073A - Air conditioning apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent occurrence of excess heating while preventing retention of a refrigerant in an indoor unit when heater operation stops or pauses. <P>SOLUTION: An expansion valve 42 and a first control valve 31 are slightly opened by a controller 50 when heater operation by the indoor unit 40A stops or pauses with a second control valve 32 fully closed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an air conditioner, and more particularly, to a technique for eliminating shortage of refrigerant and suppressing excess heating when heating operation is stopped or stopped.

  Conventionally, various control valves such as an electromagnetic valve for blocking a refrigerant flow and a check valve for allowing a refrigerant flow in only one direction are provided in a refrigerant circuit such as an air conditioner. For example, the air conditioning apparatus of Patent Document 1 includes an outdoor unit and a plurality of indoor units. A BS unit as an intermediate unit for switching the refrigerant flow path is connected between the outdoor unit and each indoor unit.

The BS unit has a refrigerant piping structure provided with a plurality of on-off valves and the like. In the BS unit, the refrigerant evaporated in the indoor unit flows in and flows out toward the compressor of the outdoor unit, and the refrigerant discharged from the compressor of the outdoor unit flows in by switching each on-off valve. It is configured to switch to a state of flowing out toward the indoor unit. Thereby, cooling and heating are switched individually for each indoor unit.
Japanese Patent Laid-Open No. 11-241844

  However, in this type of air conditioner, when the indoor expansion valve and the open / close valve of the BS unit are closed in order to stop or pause the indoor unit during the heating operation, the gas pipe between the indoor expansion valve and the open / close valve As a result, the refrigerant stays in the air conditioner, and the amount of refrigerant circulating in the entire air conditioner becomes insufficient, so that the refrigerant capacity required for other indoor units may not be ensured.

  Here, it is possible to prevent the refrigerant from staying in the gas pipe by slightly opening the indoor expansion valve. In this case, the refrigerant staying in the gas pipe passes through the indoor heat exchanger. There is a problem that so-called surplus heating is generated, in which heat is exchanged when the heating operation is performed and the heating operation is stopped or suspended.

  The present invention has been made in view of such a point, and the object of the present invention is to prevent generation of excess heating while preventing refrigerant from staying in an indoor unit that has stopped or suspended heating operation. It is to suppress.

The first invention includes a high pressure gas pipe (11), a low pressure gas pipe (12), and a liquid pipe (13), and a plurality of use side heat exchangers (41),
One end of each use side heat exchanger (41) is connected to the liquid pipe (13) via an expansion valve (42) whose opening is adjustable, while the other end is provided with a switching mechanism (30A, 30B). Through the high-pressure gas pipe (11) and the low-pressure gas pipe (12) through a switchable,
Each of the use side heat exchangers (41) is an air conditioner capable of individually cooling and heating,
The switching mechanism (30A, 30B)
A high-pressure passage (38) having a first control valve (31) whose opening is adjustable, and connecting the use-side heat exchanger (41) and the high-pressure gas pipe (11);
A second control valve (32) having an adjustable opening, and a low pressure passage (39) connecting the use side heat exchanger (41) and the low pressure gas pipe (12);
When the heating operation of the use side heat exchanger (41) with the second control valve (32) fully closed is stopped or stopped, the expansion valve (42) is slightly opened while the first control valve An opening degree control means (50) for slightly opening (31) is provided.

  In the first invention, when the heating operation of the use side heat exchanger (41) with the second control valve (32) fully closed is stopped or stopped, the opening control means (50) causes the expansion valve (42 ) Is slightly opened, while the first control valve (31) is slightly opened.

  For this reason, even when the heating operation is stopped or stopped, it is possible to prevent the refrigerant from staying in the high-pressure passage (38) from the first control valve (31) to the use side heat exchanger (41). . As a result, the refrigerant circulation amount of the entire air conditioner is insufficient, and it is possible to solve the problem that the necessary refrigerant capacity cannot be secured in the other use side heat exchanger (40B).

  In a second aspect based on the first aspect, the opening control means (50) opens the expansion valve (42) when the room temperature reaches a predetermined temperature after the first control valve (31) is slightly opened. ) Is closed, while the second control valve (32) is opened.

  In the second invention, when the room temperature reaches a predetermined temperature after the first control valve (31) is slightly opened, the opening control means (50) closes the expansion valve (42), while the second control The valve (32) is opened.

  For this reason, when the room temperature becomes equal to or higher than a predetermined temperature (for example, the indoor set temperature + predetermined value), the refrigerant flows from the high pressure passage (38) of the switching mechanism (30A) toward the use side heat exchanger (41). Can be changed so as to flow from the high-pressure passage (38) toward the low-pressure passage (39), and so-called surplus heating is generated in which heating is performed even when the heating operation is stopped or stopped. You can avoid that.

  Specifically, as described in the first aspect of the invention, in order to prevent the refrigerant from staying in the high-pressure passage (38), it is necessary to continue circulating the refrigerant while the heating operation is stopped or stopped. However, when the refrigerant passes through the use-side heat exchanger (41), heat is exchanged little by little, and the so-called surplus that the heater is heated despite the heating operation being stopped or stopped. Heating may occur. According to this invention, generation | occurrence | production of the excessive heating at the time of a heating operation stop or a stop can be avoided, and it is preferable.

The third invention includes a high-pressure gas pipe (11), a low-pressure gas pipe (12), and a liquid pipe (13), and a plurality of use side heat exchangers (41),
One end of each use side heat exchanger (41) is connected to the liquid pipe (13) via an expansion valve (42) whose opening is adjustable, while the other end is provided with a switching mechanism (30A, 30B). Through the high-pressure gas pipe (11) and the low-pressure gas pipe (12) through a switchable,
Each of the use side heat exchangers (41) is an air conditioner capable of individually cooling and heating,
The switching mechanism (30A, 30B)
A high-pressure passage (38) having a first control valve (31) whose opening is adjustable, and connecting the use-side heat exchanger (41) and the high-pressure gas pipe (11);
The first sub control valve (33) that is adjustable in opening and has a refrigerant flow rate when fully opened is smaller than that of the first control valve (31), and is formed with a smaller inner diameter than the high pressure gas pipe (11). A first bypass pipe (18) connected to the high pressure passage (38) so as to bypass the first control valve (31);
A low-pressure passage (39) having a second control valve (32) having an adjustable opening and connecting the use-side heat exchanger (41) and the low-pressure gas pipe (12);
The second sub control valve (34) having a freely adjustable opening and a refrigerant flow rate when fully opened is smaller than that of the second control valve (32), and is formed with a pipe inner diameter smaller than that of the low pressure gas pipe (12). A second bypass pipe (19) connected to the low pressure passage (39) so as to bypass the second control valve (32),
When the heating operation of the use side heat exchanger (41) with the second control valve (32) fully closed is stopped or stopped, the expansion valve (42) is slightly opened while the first control valve Opening control means (50) for closing (31) and slightly opening the first sub control valve (33) is provided.

  In the third invention, when the heating operation of the use side heat exchanger (41) with the second control valve (32) fully closed is stopped or stopped, the opening control means (50) causes the expansion valve (42 ) Is slightly opened, while the first control valve (31) is closed and the first sub-control valve (33) is slightly opened.

  Therefore, even when the heating operation is stopped or stopped, the refrigerant is prevented from staying in the high-pressure passage (38) from the first sub-control valve (33) to the use side heat exchanger (41). it can. As a result, the refrigerant circulation amount of the entire air conditioner is insufficient, and it is possible to solve the problem that the necessary refrigerant capacity cannot be secured in the other use side heat exchanger (40B).

  Here, as the first sub control valve (33), a control valve having a refrigerant flow rate smaller than that of the first control valve (31) when fully opened is used, so that the refrigerant flow rate is adjusted with a smaller opening adjustment width. Can do.

  In a fourth aspect based on the third aspect, the opening control means (50) opens the expansion valve (50) when the indoor temperature reaches a predetermined temperature after the first sub control valve (33) is slightly opened. 42) is closed, while the second sub control valve (34) is opened.

  In the fourth invention, when the room temperature reaches a predetermined temperature after the first sub control valve (33) is slightly opened, the opening control means (50) closes the expansion valve (42), while The sub control valve (34) is opened.

  For this reason, when the room temperature becomes equal to or higher than the predetermined temperature, the refrigerant flow from the high pressure passage (38) of the switching mechanism (30A) to the use side heat exchanger (41) is transferred from the high pressure passage (38) to the low pressure passage. It can change so that it may flow toward (39), and it can avoid that what is called excess heating that heating is carried out even if heating operation is stopped or stopped.

  Here, as the second sub control valve (34), a control valve having a refrigerant flow rate smaller than that of the second control valve (32) when fully opened is used, so that the refrigerant flow rate is adjusted with a smaller opening adjustment width. Can do.

  The fifth invention is characterized in that a capillary tube (37) is connected to the high-pressure passage (38) so as to bypass the first control valve (31).

  In the fifth invention, the capillary tube (37) is connected to the high-pressure passage (38) so as to bypass the first control valve (31). Therefore, when the heating operation is stopped or stopped, the refrigerant flows into the high-pressure passage (38) through the capillary tube (37) to the use side heat exchanger (41), and the refrigerant stays in the high-pressure passage (38). Can be prevented. As a result, the refrigerant circulation amount of the entire air conditioner is insufficient, and it is possible to solve the problem that the necessary refrigerant capacity cannot be secured in the other use side heat exchanger (40B).

  In addition, the simple configuration of connecting the capillary tube (37) to the high-pressure passage (38) can prevent the stagnation of the refrigerant, and it is necessary to perform complicated opening control of the first control valve (31) and the like. This is preferable.

  According to the present invention, the refrigerant stays in the high-pressure passage (38) between the first control valve (31) and the use side heat exchanger (41) even when the heating operation is stopped or stopped. Can be prevented. As a result, the refrigerant circulation amount of the entire air conditioner is insufficient, and it is possible to solve the problem that the necessary refrigerant capacity cannot be secured in the other use side heat exchanger (40B).

  According to the second aspect of the present invention, when the indoor temperature becomes equal to or higher than a predetermined temperature (for example, indoor set temperature + predetermined value), the use side heat exchanger is switched from the high pressure passage (38) of the switching mechanism (30A). The refrigerant flow toward (41) can be changed to flow from the high-pressure passage (38) toward the low-pressure passage (39), and the refrigerant is heated despite the heating operation being stopped or stopped. It is possible to avoid the occurrence of so-called surplus heating.

  Further, according to the third aspect of the invention, even when the heating operation is stopped or stopped, the high pressure passage (38) between the first sub control valve (33) and the use side heat exchanger (41) is provided. It is possible to prevent the refrigerant from staying in the tank. As a result, the refrigerant circulation amount of the entire air conditioner is insufficient, and it is possible to solve the problem that the necessary refrigerant capacity cannot be secured in the other use side heat exchanger (40B).

  Here, as the first sub control valve (33), a control valve having a refrigerant flow rate smaller than that of the first control valve (31) when fully opened is used, so that the refrigerant flow rate is adjusted with a smaller opening adjustment width. Can do.

  Further, according to the fourth invention, when the indoor temperature becomes equal to or higher than the predetermined temperature, the flow of the refrigerant from the high pressure passage (38) of the switching mechanism (30A) toward the use side heat exchanger (41) is It can be changed to flow from the high-pressure passage (38) toward the low-pressure passage (39), and so-called surplus heating is generated in which the heating operation is stopped even when the heating operation is stopped or stopped. Can be avoided.

  Here, as the second sub control valve (34), a control valve having a refrigerant flow rate smaller than that of the second control valve (32) when fully opened is used, so that the refrigerant flow rate is adjusted with a smaller opening adjustment width. Can do.

  According to the fifth aspect of the present invention, when the heating operation is stopped or stopped, the refrigerant flows into the high-pressure passage (38) through the capillary tube (37) to the use side heat exchanger (41), and the high-pressure passage (38) It is possible to prevent the refrigerant from staying inside. As a result, the refrigerant circulation amount of the entire air conditioner is insufficient, and it is possible to solve the problem that the necessary refrigerant capacity cannot be secured in the other use side heat exchanger (40B).

  In addition, the simple configuration of connecting the capillary tube (37) to the high-pressure passage (38) can prevent the stagnation of the refrigerant, and it is necessary to perform complicated opening control of the first control valve (31) and the like. This is preferable.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

<Embodiment 1>
As shown in FIG. 1, the air conditioner (10) of the first embodiment is provided in a building or the like and heats and cools each room. The air conditioner (10) includes an outdoor unit (20), two BS units (30A, 30B) as switching mechanisms, and two indoor units (40A, 40B). And these outdoor units (20) etc. are connected by the communication piping which is refrigerant piping, and comprise the refrigerant circuit (R). In the refrigerant circuit (R), the refrigerant circulates and a vapor compression refrigeration cycle is performed.

  The outdoor unit (20) constitutes the heat source unit of the first embodiment. The outdoor unit (20) includes a main pipe (2c), a first branch pipe (2d), and a second branch pipe (2e), which are refrigerant pipes. The outdoor unit (20) includes a compressor (21), an outdoor heat exchanger (23), an outdoor expansion valve (24), and two electromagnetic valves (26, 27).

  One end of the main pipe (2c) is connected to a liquid pipe (13) which is a communication pipe disposed outside the outdoor unit (20), and the other end is connected to a first branch pipe (2d) and a second branch pipe (2e). ) Is connected to one end. The other end of the first branch pipe (2d) is connected to a high-pressure gas pipe (11) that is a communication pipe disposed outside the outdoor unit (20). The other end of the second branch pipe (2e) is connected to a low-pressure gas pipe (12) that is a connecting pipe disposed outside the outdoor unit (20).

  The compressor (21) is a fluid machine for compressing a refrigerant, and is constituted by, for example, a high-pressure dome type scroll compressor. The discharge pipe (2a) of the compressor (21) is connected in the middle of the first branch pipe (2d), and the suction pipe (2b) is connected in the middle of the second branch pipe (2e). The suction pipe (2b) is provided with an accumulator (22).

  The outdoor heat exchanger (23) is a cross fin type fin-and-tube heat exchanger, and is provided in the middle of the main pipe (2c). The outdoor expansion valve (24) is constituted by an electronic expansion valve, and is provided closer to the liquid pipe (13) than the outdoor heat exchanger (23) in the main pipe (2c). An outdoor fan (25) is provided in the vicinity of the outdoor heat exchanger (23). The outdoor heat exchanger (23) is configured so that the refrigerant exchanges heat with the air taken in by the outdoor fan (25).

  The two solenoid valves (26, 27) are a first solenoid valve (26) and a second solenoid valve (27). The first solenoid valve (26) is provided closer to the outdoor heat exchanger (23) than the connection point of the discharge pipe (2a) in the first branch pipe (2d). The second solenoid valve (27) is provided closer to the outdoor heat exchanger (23) than the connection point of the suction pipe (2b) in the second branch pipe (2e). These solenoid valves (26, 27) constitute a control valve that allows or blocks the refrigerant flow.

  Each said indoor unit (40A, 40B) comprises the utilization unit of this Embodiment 1. FIG. Each indoor unit (40A, 40B) is connected to each BS unit (30A, 30B) by an intermediate pipe (17) which is a connecting pipe. That is, the first indoor unit (40A) and the first BS unit (30A) are connected in pairs with the second indoor unit (40B) and the second BS unit (30B). On the other hand, the liquid pipe (13) is connected to the first indoor unit (40A). The second indoor unit (40B) is connected to a branch liquid pipe (16) branched from the middle of the liquid pipe (13).

  Each of the indoor units (40A, 40B) includes an indoor heat exchanger (41) and an indoor expansion valve (42) connected to each other through a refrigerant pipe. The indoor heat exchanger (41) is connected to the intermediate pipe (17). The indoor expansion valve (42) of the first indoor unit (40A) is connected to the liquid pipe (13), and the indoor expansion valve (42) of the second indoor unit (40B) is connected to the branch liquid pipe (16). . The indoor heat exchanger (41) is a cross-fin type fin-and-tube heat exchanger. The indoor expansion valve (42) is an electronic expansion valve. An indoor fan (43) is provided in the vicinity of the indoor heat exchanger (41). The indoor heat exchanger (41) is configured so that the refrigerant exchanges heat with the air taken in by the indoor fan (43).

  In addition to the intermediate pipe (17), a high pressure gas pipe (11) and a low pressure gas pipe (12) are connected to the first BS unit (30A). In the first BS unit (30A), the intermediate pipe (17) and the high pressure gas pipe (11) form a high pressure passage (38), and the intermediate pipe (17) and the low pressure gas pipe (12) form a low pressure passage (39). Therefore, the high-pressure passage (38) and the low-pressure passage (39) are joined and connected. In the first BS unit (30A), the high pressure gas pipe (11) forming the high pressure passage (38) is provided with a first control valve (31) whose opening is adjustable, and the low pressure gas pipe forming the low pressure passage (39). (12) is provided with a second control valve (32) whose opening is adjustable. The liquid pipe (13) passes through the first BS unit (30A) to form a liquid pipe (40).

  The first BS unit (30A) is provided with a supercooling heat exchanger (51) and a supercooling pipe (52) for constituting a supercooling circuit. The supercooling heat exchanger (51) is for supercooling the liquid refrigerant flowing through the liquid pipe (13) forming the liquid pipe (40). One end of the subcooling pipe (52) is connected to the liquid pipe (40), and after passing through the supercooling heat exchanger (51), the other end is connected to the low pressure gas pipe (12). ing.

  A supercooling control valve (53) whose opening degree is adjustable is provided between one end of the supercooling pipe (52) and the supercooling heat exchanger (51). The amount of liquid refrigerant flowing into the supercooling circuit is adjusted by adjusting the opening degree of the supercooling control valve (53).

  The liquid refrigerant flowing through the supercooling pipe (52) is depressurized by the supercooling control valve (53) and exchanged heat with the liquid refrigerant flowing through the liquid pipe (40) by the supercooling heat exchanger (51). It evaporates and is recovered from the low pressure gas pipe (12).

  In addition to the intermediate pipe (17), the second BS unit (30B) is branched from the middle of the high-pressure gas pipe (11) and from the middle of the low-pressure gas pipe (12). A branch low-pressure gas pipe (15) is connected. In the second BS unit (30B), the branch high-pressure gas pipe (14) forming the high-pressure passage (38) is provided with the first control valve (31), and the branch low-pressure gas pipe (15) forming the low-pressure passage (39). ) Is provided with a second control valve (32). The branch liquid pipe (16) passes through the second BS unit (30B) to form a liquid pipe (40).

  The second BS unit (30B) is provided with a supercooling heat exchanger (51) and a supercooling pipe (52) for constituting a supercooling circuit. The supercooling heat exchanger (51) is for supercooling the liquid refrigerant flowing through the branch liquid pipe (16) forming the liquid pipe (40). One end of the supercooling pipe (52) is connected to the liquid pipe (40), and after passing through the supercooling heat exchanger (51), the other end is connected to the branch low-pressure gas pipe (15). Has been.

  A supercooling control valve (53) whose opening degree is adjustable is provided between one end of the supercooling pipe (52) and the supercooling heat exchanger (51). The amount of liquid refrigerant flowing into the supercooling circuit is adjusted by adjusting the opening degree of the supercooling control valve (53).

  The first and second control valves (31, 32) of each BS unit (30A, 30B) constitute an electric valve that adjusts the refrigerant flow rate by adjusting the opening. And these 1st and 2nd control valves (31, 32) switch a refrigerant | coolant flow by opening-and-closing switching, and switch air-conditioning in each indoor unit (40A, 40B).

  For example, when the indoor units (40A, 40B) are in the cooling state, the first control valve (31) is set to the closed state, and the second control valve (32) is set to the open state, and the indoor heat exchanger (41) The evaporated refrigerant flows into the low pressure gas pipe (12). When the indoor units (40A, 40B) are in heating, the first control valve (31) is set to the open state and the second control valve (32) is set to the closed state, and the gas is supplied from the high pressure gas pipe (11). The refrigerant flows into the indoor heat exchanger (41) and condenses (dissipates heat).

  The air conditioner (10) is provided with various pressure sensors (28, 29, 44). Specifically, the discharge pipe (2a) of the compressor (21) is provided with a discharge pressure sensor (28) for detecting the discharge pressure of the compressor (21). The suction pipe (2b) of the compressor (21) is provided with a suction pressure sensor (29) that detects the suction pressure of the compressor (21) upstream of the accumulator (22). A heat exchange pressure sensor (44) for detecting the pressure of the indoor heat exchanger (41) is provided between the indoor heat exchanger (41) and the indoor expansion valve (42).

  The air conditioner (10) includes a controller (50). The controller (50) constitutes an opening degree control means for performing a pressure equalizing operation when switching between the air conditioning operation of at least one of the indoor units (40A, 40B). In this pressure equalization operation, when switching from cooling to heating, the indoor heat exchanger (41) equalizes pressure with the high-pressure gas pipe (11), and when switching from heating to cooling, the indoor heat exchanger (41) is low-pressure gas. The first and second control valves (31, 32) are controlled so as to equalize pressure with the pipe (12).

  Hereinafter, the pressure equalizing operation performed when switching from the cooling operation to the heating operation will be specifically described. In addition, the 1st control valve (31), the 2nd control valve (32), the indoor expansion valve (42), etc. which are mentioned below are in the 2nd BS unit (30B) and the 2nd indoor unit (40B). To do.

  First, the second control valve (32) is closed. Thereby, the distribution of the refrigerant to the second BS unit (30B) and the second indoor unit (40B) is blocked.

  Next, the first control valve (31) is slightly opened. That is, the refrigerant discharged from the compressor (21) passes through the high-pressure passage (38) of the second BS unit (30B), that is, the branch high-pressure gas pipe (14) and the intermediate pipe (17), and the low-pressure indoor heat exchanger (41). Pour into small amounts. Thereby, the indoor heat exchanger (41) in a low pressure state is gradually equalized to the same high pressure state as the branch high pressure gas pipe (14).

  Next, the first control valve (31) is fully opened. Thereby, the refrigerant discharged from the compressor (21) flows into the indoor heat exchanger (41) through the branch high-pressure gas pipe (14) and the intermediate pipe (17), and the switching from cooling to heating is completed.

  On the other hand, when switching from the heating operation to the cooling operation, first, the first control valve (31) is closed. Thereby, the distribution of the refrigerant to the second BS unit (30B) and the second indoor unit (40B) is blocked.

  Next, the second control valve (32) is slightly opened. That is, the refrigerant discharged from the compressor (21) flows into the branch low-pressure gas pipe (15) little by little through the indoor heat exchanger (41) and the intermediate pipe (17). Thereby, the indoor heat exchanger (41) in a high pressure state is gradually equalized to the same low pressure state as the branch low pressure gas pipe (15).

  Next, the control valve (32) is fully opened. Thereby, the refrigerant discharged from the compressor (21) flows into the branch low-pressure gas pipe (15) through the indoor heat exchanger (41) and the intermediate pipe (17), and the switching from heating to cooling is completed.

  The controller (50) is provided with a pressure input unit (55), a compressor control unit (56), and a valve operation unit (57).

  The pressure input unit (55) receives detection pressures of the discharge pressure sensor (28), the suction pressure sensor (29), and the heat exchange pressure sensor (44) during pressure equalization operation. The valve operating section (57) adjusts the opening of the first and second control valves (31, 32) in the pressure equalizing operation.

  The compressor control unit (56) constitutes pressure control means for controlling the inlet pressure of the first and second control valves (31, 32) to a predetermined value or more in the pressure equalizing operation. Here, the inlet pressure of the first control valve (31) is the refrigerant pressure flowing into the first control valve (31) from the discharge pipe (2a) side of the compressor (21). The inlet pressure of the second control valve (32) is the refrigerant pressure flowing into the second control valve (32) from the indoor heat exchanger (41) side.

  In the first embodiment, the detected pressure of the heat exchange pressure sensor (44) is used as the inlet pressure of the first and second control valves (31, 32). If the heat exchange pressure sensor (44) cannot be detected due to a failure or the like, the detected pressure of the discharge pressure sensor (28) is substituted for the inlet pressure of the first control valve (31) and detected by the suction pressure sensor (29). The pressure is substituted for the inlet pressure of the second control valve (32).

-Driving action-
Next, the operation of the air conditioner (10) will be described with reference to the drawings. In the air conditioner (10), there are an operation in which both of the two indoor units (40A, 40B) perform cooling or heating, and an operation in which one performs cooling and the other performs heating.

<Cooling operation>
A case where both the first indoor unit (40A) and the second indoor unit (40B) perform cooling will be described with reference to FIG. In this cooling operation, in the outdoor unit (20), the first solenoid valve (26) is set to the open state, the second solenoid valve (27) is set to the closed state, and the outdoor expansion valve (24) is set to the fully open state. The In each BS unit (30A, 30B), the first control valve (31) is set to the closed state, and the second control valve (32) is set to the open state. In each indoor unit (40A, 40B), the indoor expansion valve (42) is set to an appropriate opening degree.

  In this state, when the compressor (21) is driven, the high-pressure gas refrigerant discharged from the compressor (21) flows through the first branch pipe (2d) to the outdoor heat exchanger (23). In the outdoor heat exchanger (23), the refrigerant exchanges heat with the air taken in by the outdoor fan (25) and condenses. The condensed refrigerant flows out of the outdoor unit (20) through the main pipe (2c) and flows into the liquid pipe (13). Part of the refrigerant in the liquid pipe (13) flows into the branch liquid pipe (16) and flows into the second indoor unit (40B), and the rest flows into the first indoor unit (40A).

  In the first and second BS units (30A, 30B), a part of the refrigerant flowing through the liquid pipe (40) flows to the supercooling pipe (52), and the rest passes through the supercooling heat exchanger (51). Then, it flows into the first and second indoor units (40A, 40B).

  At this time, the liquid refrigerant that has flowed into the supercooling pipe (52) is decompressed by the supercooling control valve (53) and then passes through the supercooling heat exchanger (51). In the supercooling heat exchanger (51), the liquid refrigerant flowing through the supercooling pipe (52) exchanges heat with the liquid refrigerant flowing through the liquid pipe (40) and evaporates. The evaporated refrigerant flows into the low pressure passage (39) and returns to the compressor (21).

  In the first indoor unit (40A) and the second indoor unit (40B), the refrigerant is depressurized by the indoor expansion valve (42) and then flows to the indoor heat exchanger (41). In the indoor heat exchanger (41), the refrigerant exchanges heat with the air taken in by the indoor fan (43) and evaporates. Thereby, air is cooled and indoor cooling is performed. The gas refrigerant evaporated in the indoor heat exchanger (41) flows out of the indoor units (40A, 40B), and flows into the BS units (30A, 30B) through the intermediate pipe (17).

  In the first BS unit (30A), the gas refrigerant flows from the intermediate pipe (17) into the low-pressure gas pipe (12). In the second BS unit (30B), the gas refrigerant flows from the intermediate pipe (17) into the branch low-pressure gas pipe (15) and flows into the low-pressure gas pipe (12). The gas refrigerant in the low-pressure gas pipe (12) flows into the outdoor unit (20), returns to the compressor (21) through the suction pipe (2b), and this circulation is repeated.

<Heating operation>
A case where both the first indoor unit (40A) and the second indoor unit (40B) perform heating will be described with reference to FIG. In this heating operation, in the outdoor unit (20), the first solenoid valve (26) is closed, the second solenoid valve (27) is opened, and the outdoor expansion valve (24) is set to an appropriate opening degree. Is set. In each BS unit (30A, 30B), the first control valve (31) is set in the open state, and the second control valve (32) is set in the closed state. In each indoor unit (40A, 40B), the indoor expansion valve (42) is set to a fully open state.

  When the compressor (21) is driven in such a state, the high-pressure gas refrigerant discharged from the compressor (21) flows out of the outdoor unit (20) and flows into the high-pressure gas pipe (11). A part of the refrigerant in the high-pressure gas pipe (11) flows from the branch high-pressure gas pipe (14) to the second BS unit (30B), and the rest flows into the first BS unit (30A). The refrigerant flowing into each BS unit (30A, 30B) flows into each indoor unit (40A, 40B) through the intermediate pipe (17).

  In the first and second BS units (30A, 30B), a part of the refrigerant flowing through the liquid pipe (40) flows to the supercooling pipe (52), and the rest passes through the supercooling heat exchanger (51). To do.

  At this time, the liquid refrigerant that has flowed into the supercooling pipe (52) is decompressed by the supercooling control valve (53) and then passes through the supercooling heat exchanger (51). In the supercooling heat exchanger (51), the liquid refrigerant flowing through the supercooling pipe (52) exchanges heat with the liquid refrigerant flowing through the liquid pipe (40) and evaporates. The evaporated refrigerant flows into the low pressure passage (39) and returns to the compressor (21).

  In each indoor unit (40A, 40B), the refrigerant condenses by exchanging heat with air. Thereby, air is heated and indoor heating is performed. The refrigerant condensed in the first indoor unit (40A) flows to the liquid pipe (13). The refrigerant condensed in the second indoor unit (40B) flows into the liquid pipe (13) through the branch liquid pipe (16). The refrigerant in the liquid pipe (13) flows into the outdoor unit (20) and flows through the main pipe (2c). The refrigerant in the main pipe (2c) is decompressed by the outdoor expansion valve (24) and then flows into the outdoor heat exchanger (23). In the outdoor heat exchanger (23), the refrigerant evaporates by exchanging heat with air. The evaporated gas refrigerant returns to the compressor (21) again through the second branch pipe (2e) and the suction pipe (2b), and this circulation is repeated.

<Air conditioning operation>
Next, a description will be given of a case where cooling is performed with one indoor unit (40A, 40B) and heating is performed with the other indoor unit (40A, 40B).

  First, an operation in which the first indoor unit (40A) performs cooling and the second indoor unit (40B) performs heating (hereinafter referred to as air conditioning operation 1) will be described. Here, differences from the cooling operation will be described.

  In the case of this cooling / heating operation 1, as shown in FIG. 3, in the above-described cooling operation state, the first control valve (31) of the second BS unit (30B) is in the open state, and the second control valve (32) is closed. Each state is set. Further, the indoor expansion valve (42) of the second indoor unit (40B) is set to a fully open state. Then, a part of the high-pressure gas refrigerant discharged from the compressor (21) flows to the first branch pipe (2d) and the rest flows to the high-pressure gas pipe (11).

  The refrigerant flowing into the high-pressure gas pipe (11) passes from the branch high-pressure gas pipe (14) through the second BS unit (30B) and the intermediate pipe (17) to the indoor heat exchanger (41) of the second indoor unit (40B). To flow. In the indoor heat exchanger (41) of the second indoor unit (40B), the refrigerant exchanges heat with air and condenses. Thereby, air is heated and indoor heating is performed.

  The refrigerant condensed in the second indoor unit (40B) flows into the liquid pipe (40) of the second BS unit (30B) through the branch liquid pipe (16). In the second BS unit (30B), a part of the refrigerant flowing through the liquid pipe (40) flows to the supercooling pipe (52), and the rest passes through the supercooling heat exchanger (51) to the liquid pipe (13). Flow into.

  At this time, the liquid refrigerant that has flowed into the supercooling pipe (52) is decompressed by the supercooling control valve (53) and then passes through the supercooling heat exchanger (51). In the supercooling heat exchanger (51), the liquid refrigerant flowing through the supercooling pipe (52) exchanges heat with the liquid refrigerant flowing through the liquid pipe (40) and evaporates. The evaporated refrigerant flows into the low pressure passage (39) and returns to the compressor (21).

  And the refrigerant | coolant which flowed into the liquid piping (13) merges with the refrigerant | coolant from an outdoor unit (20). The combined refrigerant flows through the liquid pipe (13) as it is, and evaporates in the first indoor unit (40A). Thereby, indoor cooling is performed.

  Next, an operation in which heating is performed in the first indoor unit (40A) and cooling is performed in the second indoor unit (40B) (hereinafter referred to as air conditioning operation 2) will be described. Here, differences from the heating operation will be described.

  In the case of this cooling / heating operation 2, as shown in FIG. 4, in the heating operation state described above, the first control valve (31) of the second BS unit (30B) is closed and the second control valve (32) is opened. Each state is set. Moreover, the indoor expansion valve (42) of the second indoor unit (40B) is set to an appropriate opening degree. Then, the entire amount of refrigerant flowing from the compressor (21) to the high pressure gas pipe (11) flows into the first BS unit (30A). The refrigerant flowing through the first BS unit (30A) flows to the first indoor unit (40A) and condenses. Thereby, heating is performed in the first indoor unit (40A).

  The refrigerant condensed in the first indoor unit (40A) flows into the liquid pipe (40) of the first BS unit (30A) through the liquid pipe (13). In the first BS unit (30A), a part of the refrigerant flowing through the liquid pipe (40) flows to the supercooling pipe (52), and the rest passes through the supercooling heat exchanger (51) to the liquid pipe (13). Flow into.

  At this time, the liquid refrigerant that has flowed into the supercooling pipe (52) is decompressed by the supercooling control valve (53) and then passes through the supercooling heat exchanger (51). In the supercooling heat exchanger (51), the liquid refrigerant flowing through the supercooling pipe (52) exchanges heat with the liquid refrigerant flowing through the liquid pipe (40) and evaporates. The evaporated refrigerant flows into the low pressure passage (39) and returns to the compressor (21).

  A part of the refrigerant flowing into the liquid pipe (13) flows into the second indoor unit (40B) through the branch liquid pipe (16), and the rest flows into the outdoor unit (20). In the second indoor unit (40B), the refrigerant is depressurized by the indoor expansion valve (42) and then evaporated by the indoor heat exchanger (41). Thereby, cooling is performed in the second indoor unit (40B).

  The gas refrigerant evaporated in the second indoor unit (40B) flows into the low-pressure gas pipe (12) through the intermediate pipe (17), the second BS unit (30B), and the branch low-pressure gas pipe (15) in this order. The refrigerant in the low pressure gas pipe (12) flows into the second branch pipe (2e) of the outdoor unit (20) and merges with the refrigerant from the outdoor heat exchanger (23). The merged refrigerant returns to the compressor (21) again through the suction pipe (2b).

<Stop or stop heating operation>
Next, the operation of the air conditioner (10) when the indoor unit (40A) during the heating operation is stopped or stopped will be described with reference to FIGS. In addition, although the case where the 1st indoor unit (40A) performs heating operation is demonstrated here, the same control is performed also when the 2nd indoor unit (40B) performs heating operation.

  FIG. 5 is a refrigerant circuit diagram partially omitted for explaining the refrigerant flow of the first BS unit (30A) and the first indoor unit (40A) of the air-conditioning apparatus (10) according to the first embodiment. .

  In this heating operation, in the first BS unit (30A), the first control valve (31) is set to the open state, and the second control valve (32) is set to the closed state. In the first indoor unit (40A), the indoor expansion valve (42) is set to a fully open state.

  Then, the high-pressure gas refrigerant discharged from the compressor (21) flows into the first BS unit (30A) from the high-pressure gas pipe (11). The refrigerant flowing into the first BS unit (30A) flows into the first indoor unit (40A) through the intermediate pipe (17). In the first indoor unit (40A), the refrigerant exchanges heat with air and condenses. Thereby, air is heated and indoor heating is performed. The refrigerant condensed in the first indoor unit (40A) flows to the liquid pipe (13).

  FIG. 6 is a flowchart showing the operation of the air conditioner (10) when the heating operation is stopped or paused.

  First, in step S11, a command to stop or pause the heating operation is issued to the first indoor unit (40A) that is in the heating operation. For example, when the user presses a stop button such as a remote controller, a stop or pause command is output from the controller (50) to the first BS unit (30A) and the first indoor unit (40A). Then, the process proceeds to subsequent step S12.

  In step S12, the indoor expansion valve (42) of the first indoor unit (40A) is slightly opened, while the first control valve (31) of the first BS unit (30A) is slightly opened.

  Thus, when the heating operation is stopped or stopped, the refrigerant can be prevented from staying in the intermediate pipe (17) by slightly opening the indoor expansion valve (42) and the first control valve (31). As a result, the refrigerant circulation amount of the entire air conditioner (10) becomes insufficient, and it is possible to solve the problem that the refrigerant capacity necessary for the other indoor units (40B) cannot be ensured.

  On the other hand, as described above, if the refrigerant continues to be circulated even while the heating operation is stopped or paused, when the refrigerant passes through the indoor heat exchanger (41), heat is exchanged little by little, There is a possibility that so-called surplus heating, in which heating is performed even when the heating operation is stopped or stopped, may occur. Therefore, in the first embodiment, the process proceeds to step S13 following step S12. FIG. 7 is a refrigerant circuit diagram illustrating the flow of refrigerant when avoiding excessive heating.

  In step S13, it is determined whether the room temperature is equal to or higher than a predetermined temperature. If the determination in step S13 is “NO”, it is determined that excess heating has not occurred, and the process waits as it is. If the determination in step S13 is “YES”, it is determined that excess heating has occurred, and the process proceeds to subsequent step S14.

  In step S14, the indoor expansion valve (42) of the first indoor unit (40A) is closed, and the process proceeds to subsequent step S15. In step S15, the 2nd control valve (32) of a 1st BS unit (30A) is opened, and a process is complete | finished.

  As described above, according to the first embodiment, when the indoor temperature becomes equal to or higher than the predetermined temperature, the indoor heat exchanger is connected from the high-pressure passage (38) of the first BS unit (30A) through the intermediate pipe (17). Since the refrigerant flow toward (41) has been changed to flow from the high pressure passage (38) toward the low pressure passage (39), it is heated despite the heating operation being stopped or suspended. The occurrence of so-called surplus heating can be avoided.

<Embodiment 2>
FIG. 8 is a refrigerant circuit diagram showing the overall configuration of the air-conditioning apparatus (30) according to Embodiment 2 of the present invention and the operation of the cooling operation. The difference from the first embodiment is that the first and second bypass pipes (18, 19) bypassing the first and second control valves (31, 32) and the first and second bypass pipes (18, 19). Since the first and second sub control valves (33, 34) provided in the first embodiment are provided, the same portions as those in the first embodiment are denoted by the same reference numerals, and only different points will be described.

  As shown in FIG. 8, in addition to the intermediate pipe (17), a high-pressure gas pipe (11) and a low-pressure gas pipe (12) are connected to the first BS unit (30A). In the first BS unit (30A), the intermediate pipe (17) and the high pressure gas pipe (11) form a high pressure passage (38), and the intermediate pipe (17) and the low pressure gas pipe (12) form a low pressure passage (39). Therefore, the high-pressure passage (38) and the low-pressure passage (39) are joined and connected. In the first BS unit (30A), the high pressure gas pipe (11) is provided with a first control valve (31), and the low pressure gas pipe (12) is provided with a second control valve (32).

  Further, a first bypass pipe (18) is connected to the high pressure passage (38) so as to bypass the first control valve (31), and a second control valve (32) is bypassed to the low pressure passage (39). The 2nd bypass piping (19) is connected to. The first and second bypass pipes (18, 19) are formed with smaller pipe inner diameters than the high-pressure gas pipe (11) and the low-pressure gas pipe (12), respectively. In the first and second bypass pipes (18, 19), the first and second sub-controls are adjustable in opening and the refrigerant flow rate when fully opened is smaller than that of the first and second control valves (31, 32). Valves (33, 34) are provided.

  In addition to the intermediate pipe (17), the second BS unit (30B) is branched from the middle of the high-pressure gas pipe (11) and from the middle of the low-pressure gas pipe (12). A branch low-pressure gas pipe (15) is connected. In the second BS unit (30B), the branch high-pressure gas pipe (14) is provided with a first control valve (31), and the branch low-pressure gas pipe (15) is provided with a second control valve (32). Yes.

  Further, a first bypass pipe (18) is connected to the branch high-pressure gas pipe (14) so as to bypass the first control valve (31), and a second control valve (32) is connected to the branch low-pressure gas pipe (15). ) Is connected to the second bypass pipe (19). The first and second bypass pipes (18, 19) have smaller pipe inner diameters than the branch high-pressure gas pipe (14) and the branch low-pressure gas pipe (15), respectively. The first and second bypass pipes (18, 19) include first and second sub control valves (33, 34) in which the refrigerant flow rate when fully opened is smaller than that of the first and second control valves (31, 32). ) Is provided.

  The air conditioner (10) includes a controller (50). In the pressure equalizing operation, the controller (50) adjusts the opening degree of the first and second control valves (31, 32) and the first and second sub control valves (33, 34) by the valve operating unit (57). Is configured to do.

  Hereinafter, the pressure equalizing operation performed when switching from the cooling operation to the heating operation will be specifically described. In addition, the 1st control valve (31), the 2nd control valve (32), the indoor expansion valve (42), etc. which are mentioned below are in the 2nd BS unit (30B) and the 2nd indoor unit (40B). To do.

  First, the second control valve (32) and the second sub control valve (34) are closed. Thereby, the distribution of the refrigerant to the second BS unit (30B) and the second indoor unit (40B) is blocked.

  Next, the first sub control valve (33) is slightly opened. That is, the refrigerant discharged from the compressor (21) flows little by little into the low-pressure indoor heat exchanger (41) through the branch high-pressure gas pipe (14), the first bypass pipe (18), and the intermediate pipe (17). Thereby, the indoor heat exchanger (41) in a low pressure state is gradually equalized to the same high pressure state as the branch high pressure gas pipe (14).

  Next, the first control valve (31) is fully opened. The first sub control valve (33) may remain open or may be controlled to close when the first control valve (31) is opened.

  As a result, the refrigerant discharged from the compressor (21) flows into the indoor heat exchanger (41) through the branch high-pressure gas pipe (14), the first bypass pipe (18), and the intermediate pipe (17), and from the cooling to the heating. Switching is complete.

  On the other hand, when switching from the heating operation to the cooling operation, first, the first control valve (31) and the first sub control valve (33) are closed. Thereby, the distribution of the refrigerant to the second BS unit (30B) and the second indoor unit (40B) is blocked.

  Next, the second sub control valve (34) is slightly opened. That is, the refrigerant discharged from the compressor (21) flows little by little into the branch low-pressure gas pipe (15) through the indoor heat exchanger (41), the intermediate pipe (17), and the second bypass pipe (19). Thereby, the indoor heat exchanger (41) in a high pressure state is gradually equalized to the same low pressure state as the branch low pressure gas pipe (15).

  Next, the second control valve (32) is fully opened. The second sub control valve (34) may remain open or may be controlled to close when the second control valve (32) is opened.

  As a result, the refrigerant discharged from the compressor (21) flows into the branch low-pressure gas pipe (15) through the indoor heat exchanger (41), the intermediate pipe (17), and the second bypass pipe (19), and from heating to cooling. Switching is complete.

-Driving action-
Next, the operation of the air conditioner (30) will be described with reference to the drawings. In this air conditioner (30), there are an operation in which both of the two indoor units (40A, 40B) perform cooling or heating, and an operation in which one performs cooling and the other performs heating. Since the cooling operation, the heating operation, and the cooling / heating operation are substantially the same as the operation operations described in the first embodiment, only the cooling operation will be described in the second embodiment, and the other operation operations will be omitted.

<Cooling operation>
A case where both the first indoor unit (40A) and the second indoor unit (40B) perform cooling will be described with reference to FIG. In this cooling operation, in the outdoor unit (20), the first solenoid valve (26) is set to the open state, the second solenoid valve (27) is set to the closed state, and the outdoor expansion valve (24) is set to the fully open state. The In each BS unit (30A, 30B), the first control valve (31), the first and second sub control valves (33, 34) are set to the closed state, and the second control valve (32) is set to the open state. The In each indoor unit (40A, 40B), the indoor expansion valve (42) is set to an appropriate opening degree.

  In this state, when the compressor (21) is driven, the high-pressure gas refrigerant discharged from the compressor (21) flows through the first branch pipe (2d) to the outdoor heat exchanger (23). In the outdoor heat exchanger (23), the refrigerant exchanges heat with the air taken in by the outdoor fan (25) and condenses. The condensed refrigerant flows out of the outdoor unit (20) through the main pipe (2c) and flows into the liquid pipe (13). Part of the refrigerant in the liquid pipe (13) flows into the branch liquid pipe (16) and flows into the second indoor unit (40B), and the rest flows into the first indoor unit (40A).

  In the first and second BS units (30A, 30B), a part of the refrigerant flowing through the liquid pipe (40) flows to the supercooling pipe (52), and the rest passes through the supercooling heat exchanger (51). Then, it flows into the first and second indoor units (40A, 40B).

  At this time, the liquid refrigerant that has flowed into the supercooling pipe (52) is decompressed by the supercooling control valve (53) and then passes through the supercooling heat exchanger (51). In the supercooling heat exchanger (51), the liquid refrigerant flowing through the supercooling pipe (52) exchanges heat with the liquid refrigerant flowing through the liquid pipe (40) and evaporates. The evaporated refrigerant flows into the low pressure passage (39) and returns to the compressor (21).

  In the first indoor unit (40A) and the second indoor unit (40B), the refrigerant is depressurized by the indoor expansion valve (42) and then flows to the indoor heat exchanger (41). In the indoor heat exchanger (41), the refrigerant exchanges heat with the air taken in by the indoor fan (43) and evaporates. Thereby, air is cooled and indoor cooling is performed. The gas refrigerant evaporated in the indoor heat exchanger (41) flows out of the indoor units (40A, 40B), and flows into the BS units (30A, 30B) through the intermediate pipe (17).

  In the first BS unit (30A), the gas refrigerant flows from the intermediate pipe (17) into the low-pressure gas pipe (12). In the second BS unit (30B), the gas refrigerant flows from the intermediate pipe (17) into the branch low-pressure gas pipe (15) and flows into the low-pressure gas pipe (12). The gas refrigerant in the low-pressure gas pipe (12) flows into the outdoor unit (20), returns to the compressor (21) through the suction pipe (2b), and this circulation is repeated.

<Stop or stop heating operation>
Next, the operation of the air conditioner (30) when the indoor unit (40A) during the heating operation is stopped or suspended will be described with reference to FIGS. In addition, although the case where the 1st indoor unit (40A) performs heating operation is demonstrated here, the same control is performed also when the 2nd indoor unit (40B) performs heating operation.

  FIG. 9 is a refrigerant circuit diagram partially omitted for explaining the refrigerant flow of the first BS unit (30A) and the first indoor unit (40A) of the air conditioner (30) according to the second embodiment. .

  In this heating operation, in the first BS unit (30A), the first control valve (31) is set to the open state, and the second control valve (32) is set to the closed state. In the first indoor unit (40A), the indoor expansion valve (42) is set to a fully open state.

  Then, the high-pressure gas refrigerant discharged from the compressor (21) flows into the first BS unit (30A) from the high-pressure gas pipe (11). The refrigerant flowing into the first BS unit (30A) flows into the first indoor unit (40A) through the intermediate pipe (17). In the first indoor unit (40A), the refrigerant exchanges heat with air and condenses. Thereby, air is heated and indoor heating is performed. The refrigerant condensed in the first indoor unit (40A) flows to the liquid pipe (13).

  FIG. 10 is a flowchart showing the operation of the air conditioner (10) when the heating operation is stopped or paused.

  First, in step S21, an instruction to stop or pause the heating operation is issued to the first indoor unit (40A) that is in the heating operation. For example, when the user presses a stop button such as a remote controller, a stop or pause command is output from the controller (50) to the first BS unit (30A) and the first indoor unit (40A). Then, the process proceeds to subsequent step S22.

  In step S22, the indoor expansion valve (42) of the first indoor unit (40A) is slightly opened, while the first control valve (31) of the first BS unit (30A) is closed and the first sub control valve (33). To slightly open.

  As described above, when the heating operation is stopped or stopped, the first control valve (31) is closed and the indoor expansion valve (42) and the first sub control valve (33) are slightly opened, so that the refrigerant is connected to the intermediate pipe ( 17) It can be prevented from staying inside. As a result, the refrigerant circulation amount of the entire air conditioner (10) becomes insufficient, and it is possible to solve the problem that the refrigerant capacity necessary for the other indoor units (40B) cannot be ensured. Here, as the first sub control valve (33), a control valve having a refrigerant flow rate smaller than that of the first control valve (31) when fully opened is used, so that the refrigerant flow rate is adjusted with a smaller opening adjustment width. Can do.

  On the other hand, as described above, if the refrigerant continues to be circulated even while the heating operation is stopped or paused, when the refrigerant passes through the indoor heat exchanger (41), heat is exchanged little by little, There is a possibility that so-called surplus heating, in which heating is performed even when the heating operation is stopped or stopped, may occur. Therefore, in the first embodiment, the process proceeds to step S23 following step S22. In addition, FIG. 11 is a refrigerant circuit diagram showing the flow of refrigerant when avoiding excessive heating.

  In step S23, it is determined whether the room temperature is equal to or higher than a predetermined temperature. If the determination in step S23 is “NO”, it is determined that excess heating has not occurred, and the process waits as it is. If the determination in step S23 is “YES”, it is determined that excess heating has occurred, and the process proceeds to subsequent step S24.

  In step S24, the indoor expansion valve (42) of the first indoor unit (40A) is closed, and the process proceeds to subsequent step S25. In step S25, the 2nd control valve (32) of a 1st BS unit (30A) is opened, and a process is complete | finished.

  As described above, according to the second embodiment, when the indoor temperature becomes equal to or higher than the predetermined temperature, the indoor heat exchanger is connected from the high pressure passage (38) of the first BS unit (30A) via the intermediate pipe (17). Since the refrigerant flow toward (41) has been changed to flow from the high pressure passage (38) toward the low pressure passage (39), it is heated despite the heating operation being stopped or suspended. The occurrence of so-called surplus heating can be avoided.

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

  For example, in the air conditioner (30) of the second embodiment, as shown in FIG. 12, the first control valve (31) is bypassed in the high-pressure passage (38) of the first and second BS units (30A, 30B). In this manner, the capillary tube (37) may be connected. Further, when the heating operation is stopped or stopped, the first control valve (31) and the first sub control valve (33) are closed.

  In this way, even when the heating operation is stopped or stopped, the refrigerant flowing from the high pressure gas pipe (11) into the first BS unit (30A) passes through the capillary tube (37) to the first indoor unit (40A). Therefore, the refrigerant can be prevented from staying in the intermediate pipe (17). As a result, the refrigerant circulation amount of the entire air conditioner (30) becomes insufficient, and it is possible to solve the problem that the refrigerant capacity necessary for other indoor units (40B) cannot be ensured.

  In the first and second embodiments, two indoor units (40A, 40B) and two BS units (30A, 30B) have been described. The occurrence of excess heating can be suppressed while preventing the refrigerant from staying in the indoor unit.

  As described above, the present invention has a highly practical effect that it is possible to suppress the occurrence of excess heating while preventing the refrigerant from staying in the indoor unit in which the heating operation is stopped or suspended. Since it is obtained, it is extremely useful and has high industrial applicability.

It is a refrigerant circuit diagram which shows the whole structure of the air conditioning apparatus which concerns on this Embodiment 1, and shows the operation | movement of a cooling operation. It is a refrigerant circuit diagram which shows the operation | movement of heating operation. It is a refrigerant circuit diagram which shows the operation | movement of the air conditioning operation. It is a refrigerant circuit diagram which shows the operation | movement of the air conditioning operation 2. FIG. FIG. 5 is a refrigerant circuit diagram partially omitted in order to explain the refrigerant flow of the first BS unit and the first indoor unit. It is a flowchart figure which shows operation | movement of the air conditioning apparatus when heating operation is stopped or stopped. It is a refrigerant circuit figure which shows the flow of the refrigerant | coolant when avoiding excessive heating. It is a refrigerant circuit figure which shows the whole structure of the air conditioning apparatus which concerns on this Embodiment 2, and shows the operation | movement of air_conditionaing | cooling operation. FIG. 5 is a refrigerant circuit diagram partially omitted in order to explain the refrigerant flow of the first BS unit and the first indoor unit. It is a flowchart figure which shows operation | movement of the air conditioning apparatus when heating operation is stopped or stopped. It is a refrigerant circuit figure which shows the flow of the refrigerant | coolant when avoiding excessive heating. It is another refrigerant circuit figure which abbreviate | omits and shows the whole structure of an air conditioning apparatus.

Explanation of symbols

10 Air conditioner
11 High-pressure gas piping
12 Low pressure gas piping
13 Liquid piping
18 First bypass piping
19 Second bypass piping
30 Air conditioner
30 Air conditioner
30A 1st BS unit (switching mechanism)
30B 2nd BS unit (switching mechanism)
31 First control valve
32 Second control valve
33 1st sub control valve
34 Second sub control valve
37 Capillary tube
38 High pressure passage
39 Low pressure passage
41 Indoor heat exchanger (use side heat exchanger)
42 Indoor expansion valve (expansion valve)
50 controller (opening control means)

Claims (5)

A high-pressure gas pipe (11), a low-pressure gas pipe (12), and a liquid pipe (13), and a plurality of use side heat exchangers (41),
One end of each use side heat exchanger (41) is connected to the liquid pipe (13) via an expansion valve (42) whose opening is adjustable, while the other end is provided with a switching mechanism (30A, 30B). Through the high-pressure gas pipe (11) and the low-pressure gas pipe (12) through a switchable,
Each of the use side heat exchangers (41) is an air conditioner capable of individually cooling and heating,
The switching mechanism (30A, 30B)
A high-pressure passage (38) having a first control valve (31) whose opening is adjustable, and connecting the use-side heat exchanger (41) and the high-pressure gas pipe (11);
A second control valve (32) having an adjustable opening, and a low pressure passage (39) connecting the use side heat exchanger (41) and the low pressure gas pipe (12);
When the heating operation of the use side heat exchanger (41) with the second control valve (32) fully closed is stopped or stopped, the expansion valve (42) is slightly opened while the first control valve An air conditioning apparatus comprising opening degree control means (50) for slightly opening (31). In claim 1,
The opening control means (50) closes the expansion valve (42) when the room temperature reaches a predetermined temperature after slightly opening the first control valve (31), while the second control valve (32) An air conditioner configured to open the air. A high-pressure gas pipe (11), a low-pressure gas pipe (12), and a liquid pipe (13), and a plurality of use side heat exchangers (41),
One end of each use side heat exchanger (41) is connected to the liquid pipe (13) via an expansion valve (42) whose opening is adjustable, while the other end is provided with a switching mechanism (30A, 30B). Through the high-pressure gas pipe (11) and the low-pressure gas pipe (12) through a switchable,
Each of the use side heat exchangers (41) is an air conditioner capable of individually cooling and heating,
The switching mechanism (30A, 30B)
A high-pressure passage (38) having a first control valve (31) whose opening is adjustable, and connecting the use-side heat exchanger (41) and the high-pressure gas pipe (11);
The first sub control valve (33) that is adjustable in opening and has a refrigerant flow rate when fully opened is smaller than that of the first control valve (31), and is formed with a smaller inner diameter than the high pressure gas pipe (11). A first bypass pipe (18) connected to the high pressure passage (38) so as to bypass the first control valve (31);
A low-pressure passage (39) having a second control valve (32) having an adjustable opening and connecting the use-side heat exchanger (41) and the low-pressure gas pipe (12);
The second sub control valve (34) having a freely adjustable opening and a refrigerant flow rate when fully opened is smaller than that of the second control valve (32), and is formed with a pipe inner diameter smaller than that of the low pressure gas pipe (12). A second bypass pipe (19) connected to the low pressure passage (39) so as to bypass the second control valve (32),
When the heating operation of the use side heat exchanger (41) with the second control valve (32) fully closed is stopped or stopped, the expansion valve (42) is slightly opened while the first control valve An air conditioner comprising an opening degree control means (50) for closing (31) and slightly opening the first sub control valve (33). In claim 3,
The opening control means (50) closes the expansion valve (42) and closes the second sub control valve (42) when the room temperature reaches a predetermined temperature after the first sub control valve (33) is slightly opened. 34) An air conditioner configured to open. In any one of Claims 1 thru | or 4,
A capillary tube (37) is connected to the high pressure passage (38) so as to bypass the first control valve (31).

Images