Patent Grant
9175890
This application is based on Japanese Patent Application No. 2012-153762 filed with the Japan Patent Office on Jul. 9, 2012, the entire contents of which are hereby incorporated by reference.
1. Technical Field
The present disclosure relates to an outdoor unit for an air-conditioning apparatus, and an air-conditioning apparatus.
2. Related Art
Heretofore, an air-conditioning apparatus having at least one outdoor unit and a plurality of indoor units has been known. The indoor units are coupled in parallel to the outdoor unit via a plurality of refrigerant pipes. The air-conditioning apparatus is capable of allowing the indoor units to be individually set to (or select) either a cooling operation or a heating operation and allowing them to be simultaneously operated (a so-called “cooling/heating-free operation”).
Such an air-conditioning apparatus is described in, for example, JP-A-2004-286253 (Patent Document 1). This air-conditioning apparatus is provided with one outdoor unit, two indoor units, and two electromagnetic valve units. The outdoor unit is provided with a compressor, an accumulator, an oil separator, a receiver tank, and two outdoor heat exchangers. The outdoor unit also includes an outdoor expansion valve, a discharge valve, and an intake valve coupled to each of the outdoor heat exchangers. Each of the indoor units is provided with an indoor heat exchanger. Each of the electromagnetic valve units is provided with two electromagnetic valves. The electromagnetic valve units switch the couplings of the respective indoor heat exchangers to the discharge side (high-pressure side) of the compressor or the intake side (low-pressure side) of the compressor.
In the air-conditioning apparatus disclosed in Patent Document 1, the outdoor unit, the indoor units, and the electromagnetic valve units are coupled via refrigerant pipes as follows. A discharge pipe coupled to the discharge side of the compressor is coupled to the oil separator and branched therefrom. One branch pipe is coupled to the outdoor heat exchangers via the discharge valves. The other branch pipe is coupled to the indoor heat exchangers via the electromagnetic valve units. The discharge pipe and the branch pipes constitute a high-pressure gas pipe.
An intake pipe coupled to the intake side of the compressor is coupled to the accumulator and branched therefrom. One branch pipe from the accumulator is coupled to the outdoor heat exchangers via the intake valves. The other branch pipe from the accumulator is coupled to the indoor heat exchangers via the electromagnetic valve units. The intake pipe and the branch pipes constitute a low-pressure gas pipe.
The outdoor heat exchangers each have two coupling ports. To one of the coupling ports, the discharge valves and the intake valves are coupled. To the other of the coupling ports, one end of a branched refrigerant pipe is coupled via the outdoor expansion valves. The other end of the refrigerant pipe is coupled to the receiver tank and branched therefrom. The branch pipes from the receiver tank are coupled to the coupling ports of the indoor heat exchangers on the side on which the electromagnetic valve units are not coupled. The refrigerant pipe and the branch pipes constitute a liquid pipe.
In the air-conditioning apparatus described above, the coupling between the indoor heat exchangers and the compressor is switched by opening or closing the electromagnetic valves of the electromagnetic valve units. Namely, by opening or closing the electromagnetic valves, the coupling between the indoor heat exchangers and the discharge side or intake side of the compressor is switched. Thus, each of the indoor heat exchangers can be caused to individually serve as a condenser or an evaporator. Thus, the cooling operation or the heating operation can be selected for the individual indoor units while the indoor units are simultaneously operated.
An outdoor unit for an air-conditioning apparatus includes: a compressor; an outdoor fan; a plurality of outdoor heat exchangers coupled to a plurality of indoor units; a switching member configured to switch functions of the outdoor heat exchangers to either condensers or evaporators by switching of coupling states between the compressor and the outdoor heat exchangers; and a control unit configured to calculate a low pressure saturation temperature during a cooling operation or a cooling-main operation, and configured to cause all of the plurality of outdoor heat exchangers to serve as condensers by controlling the switching member when a state in which an open-air temperature is lower than the low pressure saturation temperature continues for a predetermined time.
In the following detailed description, for purpose of explanation, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. It will be apparent, however, that one or more embodiments may be practiced without these specific details. In other instances, well-known structures and devices are schematically shown in order to simplify the drawing.
In an air-conditioning apparatus such as discussed above, all (such as two) of the indoor units may perform the cooling operation, or one indoor unit may perform the heating operation while the remaining indoor units may perform the cooling operation. In these cases, the capacity required from the indoor unit performing the cooling operation may be greater than the capacity required from the indoor unit performing the heating operation (hereafter referred to as a “cooling-main operation”). In this case, the opening and closing of the various valves are controlled so that the outdoor heat exchangers can serve as condensers.
When the air-conditioning apparatus performs the cooling operation or the cooling-main operation, the open-air temperature may be decreased. As a result, the condensation temperature may be lowered, resulting in a decrease in the high pressure (pressure of the refrigerant flowing in the high-pressure gas pipe). In such a case, the rotation speed of the compressor is increased to a performance upper-limit rotation speed so as to increase the lowered high pressure. However, increasing the rotation speed of the compressor may lead to a decrease in the low pressure (pressure of refrigerant flowing in the low-pressure gas pipe) below a target low pressure. There is also the case in which, relative to the evaporation capacity of the indoor heat exchanger serving as an evaporator, the condensation capacity of the indoor heat exchanger and the outdoor heat exchangers serving as condensers is excessive. In this case, the condensation capacity of the indoor heat exchanger and the outdoor heat exchangers is decreased.
In the above case, a flow passage switching means corresponding to one of the outdoor heat exchangers, which serve as condensers, may be switched so as to couple the one outdoor heat exchanger to the low-pressure side (whereby the one outdoor heat exchanger is caused to serve as an evaporator). In addition, the outdoor expansion valve corresponding to the one outdoor heat exchanger may be fully closed so as not to use the one outdoor heat exchanger. Thus, by not using one of the outdoor heat exchangers, the number of the outdoor heat exchangers that serve as condensers can be reduced. In this way, condensation capacity can be decreased and the low pressure can be increased to approach the target low pressure by the decrease in condensation capacity.
However, in the above approach, the outdoor heat exchanger that is not used is coupled on the low-pressure side. Thus, some of the refrigerant that has been evaporated in the indoor units and returned back into the outdoor unit may flow into the unused outdoor heat exchanger and remain therein. In this case, if the open-air temperature is lower than the low pressure saturation temperature of the refrigerant (such as −10° C.), the refrigerant remaining in the unused outdoor heat exchanger may be condensed, producing liquid refrigerant (i.e., so-called refrigerant stagnation is caused). The stagnation of the refrigerant in the unused outdoor heat exchanger may result in a lack of refrigerant in the indoor units. The lack of refrigerant decreases the cooling capacity or heating capacity of the indoor units.
An object of the present disclosure is to provide an air-conditioning apparatus that can suppress the decrease in cooling capacity and/or heating capacity due to a lack of refrigerant by eliminating or mitigating the refrigerant stagnation in the unused outdoor heat exchanger.
An outdoor unit for an air-conditioning apparatus according to the present disclosure includes: a compressor; an outdoor fan; a plurality of outdoor heat exchangers coupled to a plurality of indoor units; a switching member configured to switch functions of the outdoor heat exchangers to either condensers or evaporators by switching of coupling states between the compressor and the outdoor heat exchangers; and a control unit configured to calculate a low pressure saturation temperature during a cooling operation or a primarily cooling operation, and configured to cause all of the plurality of outdoor heat exchangers to serve as condensers by controlling the switching member when a state in which an open-air temperature is lower than the low pressure saturation temperature continues for a predetermined time.
According to this outdoor unit, when the probability of refrigerant stagnation in the outdoor heat exchanger at rest is increased during the cooling operation or the cooling-main operation, all of the outdoor heat exchangers including the outdoor heat exchanger at rest are caused to serve as condensers. Thus, the stagnated refrigerant can be caused to flow out of the outdoor heat exchanger. Namely, refrigerant stagnation can be mitigated or eliminated, so that the lack of refrigerant in the indoor units performing the cooling operation can be remedied or eliminated. As a result, the decrease in cooling and/or heating capacity can be suppressed.
In the following, an embodiment (example) of the present disclosure will be described with reference to the attached drawings. In the air-conditioning apparatus according to the present example, five indoor units are coupled in parallel to two outdoor units. In the air-conditioning apparatus, the operation state of each indoor unit can be set (selected) for the cooling operation or the heating operation, and the indoor units can be simultaneously operated (the so-called “cooling/heating-free operation).
The present disclosure is not limited to the following embodiment (example). The present disclosure may be variously modified without departing from the scope of the disclosure.
As illustrated in
In the air-conditioning apparatus 1, various operations can be selected depending on the open/close state of various valves disposed at the outdoor units 2a and 2b and the switching units 6a to 6e. In the heating operation, all of the indoor units may perform the heating operation. In a heating-main operation, the total capacity required from the indoor units performing the heating operation is greater than the total capacity required from the indoor units performing the cooling operation. In the cooling operation, all of the indoor units may perform the cooling operation. In the cooling-main operation, the total capacity required from the indoor units performing the cooling operation is greater than the total capacity required from the indoor units performing the heating operation. In the following description, the cooling-main operation among the above operations will be described by way of example with reference to
In the refrigerant circuit illustrated in
As illustrated in
The compressor 21a is driven by a motor (not shown) whose rotation speed is controlled by an inverter. Namely, the compressor 21a is a capacity variable compressor with variable operation capacity. As illustrated in
The first three-way valve 22a and the second three-way valve 23a are valves configured to switch the direction of flow of refrigerant. Namely, the first three-way valve 22a and the second three-way valve 23a switch the coupling of one of refrigerant inlet/outlet openings of the corresponding outdoor heat exchangers 24a and 25a to the discharge side (refrigerant discharge opening) or the intake side (refrigerant intake opening) of the compressor 21a.
In other words, the first three-way valve 22a switches the function of the outdoor heat exchanger 24a to either a condenser or an evaporator by switching of a coupling state between the outdoor heat exchanger 24a and the compressor 21a. On the other hand, the second three-way valve 23a switches the function of the outdoor heat exchanger 25a to either a condenser or an evaporator by switching of a coupling state between the outdoor heat exchanger 25a and the compressor 21a.
The first three-way valve 22a has three ports a, b, and c. The second three-way valve 23a has three ports d, e, and f. A refrigerant pipe coupled to the port a of the first three-way valve 22a is coupled to the outdoor unit high-pressure gas pipe 33a at a coupling point A. The port b and the first outdoor heat exchanger 24a are coupled via a refrigerant pipe. A refrigerant pipe coupled to the port c is coupled to the outdoor unit low-pressure gas pipe 34a at a coupling point D.
A refrigerant pipe coupled to the port d of the second three-way valve 23a is coupled at the coupling point A to the refrigerant pipe coupled to the outdoor unit high-pressure gas pipe 33a and the port a of the first three-way valve 22a. The port e and the second outdoor heat exchanger 25a are coupled via a refrigerant pipe. A refrigerant pipe coupled to the port f is coupled at a coupling point C to the refrigerant pipe coupled to the port c of the first three-way valve 22a.
The first outdoor heat exchanger 24a and the second outdoor heat exchanger 25a include a number of fins (not shown) made primarily of aluminum material and a plurality of copper pipes (not shown) in which refrigerant is circulated. As described above, one refrigerant inlet/outlet opening of the first outdoor heat exchanger 24a is coupled to the port b of the first three-way valve 22a. The other refrigerant inlet/outlet opening of the first outdoor heat exchanger 24a is coupled to one port of the first outdoor expansion valve 40a via a refrigerant pipe. The other port of the first outdoor expansion valve 40a is coupled to the closing valve 46a via an outdoor unit liquid pipe 35a.
One refrigerant inlet/outlet opening of the second outdoor heat exchanger 25a is coupled to the port e of the second three-way valve 23a via refrigerant pipe, as described above. The other refrigerant inlet/outlet opening of the second outdoor heat exchanger 25a is coupled to one port of the second outdoor expansion valve 41a via a refrigerant pipe. The other port of the second outdoor expansion valve 41a is coupled to the outdoor unit liquid pipe 35a at a coupling point B via a refrigerant pipe.
The first outdoor expansion valve 40a and the second outdoor expansion valve 41a are electric expansion valves driven by a pulse motor (not shown). The degree of opening of each of the outdoor expansion valves is adjusted by the number of pulses given to the pulse motor.
The outdoor fan 26a is disposed in the vicinity of the first outdoor heat exchanger 24a and the second outdoor heat exchanger 25a. The outdoor fan 26a is a propeller fan made of a resin material and is rotated by a fan motor (not shown). Open-air taken into the outdoor unit 2a by the outdoor fan 26a exchanges heat with the refrigerant in the first outdoor heat exchanger 24a and/or the second outdoor heat exchanger 25a and is then expelled outside the outdoor unit 2a. According to the present example, a performance upper-limit rotation speed of 900 rpm is set for the outdoor fan 26a (fan motor of the outdoor fan 26a).
The inflow side of the accumulator 27a is coupled to the outdoor unit low-pressure gas pipe 34a. The outflow side of the accumulator 27a is coupled to the intake side of the compressor 21a via a refrigerant pipe. The accumulator 27a separates the inflow refrigerant into gas refrigerant and liquid refrigerant. The separated gas refrigerant is suctioned into the compressor 21a.
The inflow side of the oil separator 28a is coupled to the discharge side of the compressor 21a via a refrigerant pipe. The outflow side of the oil separator 28a is coupled to the outdoor unit high-pressure gas pipe 33a. The oil separator 28a separates refrigerant oil for the compressor 21a, which is contained in the refrigerant discharged, from the compressor 21a. The separated refrigerant oil is suctioned into the compressor 21a via the oil return pipe 37a (as will be described later).
The receiver tank 29a is disposed between the coupling point B of the outdoor unit liquid pipe 35a and the closing valve 46a. The receiver tank 29a is a container that can contain the refrigerant. The receiver tank 29a adjusts the amount of refrigerant in the first outdoor heat exchanger 24a and the second outdoor heat exchanger 25a. Namely, the receiver tank 29a provides the role of a buffer. The receiver tank 29a has functions such as one for gas-liquid separation of the refrigerant.
One end of the hot gas bypass pipe 36a is coupled to the outdoor unit high-pressure gas pipe 33a at a coupling point E. The other end of the hot gas bypass pipe 36a is coupled to the outdoor unit low-pressure gas pipe 34a at a coupling point F. The hot gas bypass pipe 36a is provided with the first electromagnetic valve 42a. By opening or closing the first electromagnetic valve 42a, the state of the hot gas bypass pipe 36a can be switched between a refrigerant flow state and a non-refrigerant flow state.
One end of the oil return pipe 37a is coupled to an oil return opening of the oil separator 28a. The other end of the oil return pipe 37a is coupled at a coupling point G to a refrigerant pipe coupling the intake side of the compressor 21a and the outflow side of the accumulator 27a. The oil return pipe 37a is provided with the second electromagnetic valve 43a. By opening or closing the second electromagnetic valve 43a, the state of the oil return pipe 37a can be switched between the refrigerant flow state and the non-refrigerant flow state.
In addition, the outdoor unit 2a is provided with various sensors. As illustrated in
Between the coupling point F of the outdoor unit low-pressure gas pipe 34a and the inflow side of the accumulator 27a, a low pressure sensor 51a and an intake temperature sensor 54a are provided. The low pressure sensor 51a (low-pressure detection means, or a low-pressure detector) detects the pressure of the refrigerant suctioned into the compressor 21a. The intake temperature sensor 54a detects the temperature of the refrigerant suctioned into the compressor 21a.
Between the coupling point B of the outdoor unit liquid pipe 35a and the closing valve 46a, an intermediate pressure sensor 52a and a refrigerant temperature sensor 55a are provided. The intermediate pressure sensor 52a detects the pressure of the refrigerant flowing in the outdoor unit liquid pipe 35a. The refrigerant temperature sensor 55a detects the temperature of the refrigerant flowing in the outdoor unit liquid pipe 35a.
The refrigerant pipe coupling the port b of the first three-way valve 22a and the first outdoor heat exchanger 24a is provided with a first gas side refrigerant temperature sensor 56a. The first gas side refrigerant temperature sensor 56a detects the temperature of the refrigerant that flows out of the first outdoor heat exchanger 24a or into the first outdoor heat exchanger 24a.
The refrigerant pipe coupling the first outdoor heat exchanger 24a and the first outdoor expansion valve 40a is provided with a first liquid side refrigerant temperature sensor 59a. The first liquid side refrigerant temperature sensor 59a detects the temperature of the refrigerant that flows out of the first outdoor heat exchanger 24a or into the first outdoor heat exchanger 24a.
The refrigerant pipe coupling the port e of the second three-way valve 23a and the second outdoor heat exchanger 25a is provided with a second gas side refrigerant temperature sensor 57a. The second gas side refrigerant temperature sensor 57a detects the temperature of the refrigerant that flows out of the second outdoor heat exchanger 25a or into the second outdoor heat exchanger 25a.
The refrigerant pipe coupling the second outdoor heat exchanger 25a and the second outdoor expansion valve 41a is provided with a second liquid-side refrigerant temperature sensor 60a. The second liquid-side refrigerant temperature sensor 60a detects the temperature of the refrigerant that flows out of the second outdoor heat exchanger 25a or into the second outdoor heat exchanger 25a.
Around a suction opening (not shown) of the outdoor unit 2a, an open-air temperature sensor 58a is installed. The open-air temperature sensor 58a is an open-air temperature detection means (open-air temperature detector) that detects the temperature of open-air that flows into the outdoor unit 2a.
The outdoor unit 2a is provided with a control means (control unit) 100a mounted on a control substrate (not shown). The control means 100a includes a CPU 110a, a storage unit 120a, and a communication unit 130a. The CPU 110a receives detection signals from the sensors installed in the outdoor unit 2a. The CPU 110a also receives control signals outputted from the indoor units 8a to 8e via the communication unit 130a. The CPU 110a performs various controls on the basis of the detection signals and the control signals. For example, the CPU 110a performs drive control for the compressor 21a; switching control for the first three-way valve 22a and the second three-way valve 23a; rotation control for the fan motor of the outdoor fan 26a; and opening degree control for the first outdoor expansion valve 40a and the second outdoor expansion valve 41a.
The storage unit 120a includes a ROM and/or a RAM. The storage unit 120a may store a control program for the outdoor unit 2a and detection values corresponding to the detection signals from the sensors. The communication unit 130a provides an interface for enabling communications between the outdoor unit 2a and the indoor units 8a to 8e.
The configuration of the outdoor unit 2b is the same as the configuration of the outdoor unit 2a. Namely, the constituent elements (devices and members) of the outdoor unit 2b are designated by the signs designating the corresponding constituent elements of the outdoor unit 2a with the letter at the end of each sign changed from “a” to “b”. However, the signs for the first three-way valve, the second three-way valve, and the coupling points of the refrigerant pipes are varied between the outdoor unit 2a and the outdoor unit 2b. Namely, the ports a, b, and c of the first three-way valve 22a of the outdoor unit 2a correspond to ports g, h, and j of the first three-way valve 22b of the outdoor unit 2b. The ports d, e, and f of the second three-way valve 23a of the outdoor unit 2a correspond to the ports k, m, and n of the second three-way valve 23b of the outdoor unit 2b. The coupling points A, B, C, D, E, F, and G of the outdoor unit 2a correspond to the coupling points H, J, K, M, N, P, and Q of the outdoor unit 2b.
As illustrated in
Specifically, the first three-way valve 22a of the outdoor unit 2a is switched to provide communication between the port a and the port b. The second three-way valve 23a of the outdoor unit 2a is switched to provide communication between the port d and the port e. The first three-way valve 22b of the outdoor unit 2b is switched to provide communication between the port g and the port h. The second three-way valve 23b of the outdoor unit 2b is switched to provide communication between the port k and the port m. In
Each of the five indoor units 8a to 8e is provided with an indoor exchanger, an indoor expansion valve, and an indoor fan. Specifically, the indoor heat exchangers 81a to 81e, the indoor expansion valves 82a to 82e, and the indoor fans 83a to 83e are provided. The respective indoor units 8a to 8e have identical configurations. Thus, in the following description, only the configuration of the indoor unit 8a will be described, and the description of the other indoor units 8b to 8e will be omitted.
One refrigerant inlet/outlet opening of the indoor heat exchanger 81a is coupled to one port of the indoor expansion valve 82a via a refrigerant pipe. The other refrigerant inlet/outlet opening of the indoor heat exchanger 81a is coupled to the switching unit 6a (as will be described later) via a refrigerant pipe. When the indoor unit 8a performs the cooling operation, the indoor heat exchanger 81a serves as an evaporator. When the indoor unit 8a performs the heating operation, the indoor heat exchanger 81a serves as a condenser.
One port of the indoor expansion valve 82a is coupled to the indoor heat exchanger 81a, as described above. The other port of the indoor expansion valve 82a is coupled to the liquid pipe 32. When the indoor heat exchanger 81a serves as an evaporator, the degree of opening of the indoor expansion valve 82a is adjusted in accordance with the cooling capacity required from the indoor unit 8a. When the indoor heat exchanger 81a serves as a condenser, the degree of opening of the indoor expansion valve 82a is adjusted in accordance with the heating capacity required from the indoor unit 8a.
The indoor fan 83a is rotated by a fan motor (not shown). The indoor air taken into the indoor unit 8a by the indoor fan 83a exchanges heat with refrigerant in the indoor heat exchanger 81a and is then supplied indoor.
In addition to the configuration described above, the indoor unit 8a is provided with various sensors. Namely, the indoor unit 8a is provided with refrigerant temperature sensors 84a and 85a, and a room temperature sensor 86a. The refrigerant temperature sensor 84a is disposed at the refrigerant pipe to the indoor heat exchanger 81a on the side closer to the indoor expansion valve 82a for detecting the temperature of refrigerant. The refrigerant temperature sensor 85a is disposed at the refrigerant pipe to the indoor heat exchanger 81a on the side closer to the switching unit 6a for detecting the temperature of refrigerant. The room temperature sensor 86a is installed in the vicinity of an indoor air suction opening (not shown) of the indoor unit 8a for detecting the temperature of the indoor air that flows into the indoor unit 8a, i.e., the indoor temperature.
The configuration of the indoor units 8b to 8e is the same as the configuration of the indoor unit 8a. Namely, the constituent elements (devices and members) of the indoor units 8b to 8e are designated by the corresponding signs designating the constituent elements of the indoor unit 8a with the letter “a” replaced with “b”, “c”, “d”, or “e”.
The air-conditioning apparatus 1 is provided with the five switching units 6a to 6e corresponding to the five indoor units 8a to 8e. Each of the switching units 6a to 6e is provided with two electromagnetic valves, a first diversion pipe, and a second diversion pipe. Specifically, the electromagnetic valves 61a to 61e, the electromagnetic valves 62a to 62e, the first diversion pipes 63a to 63e, and the second diversion pipes 64a to 64e are provided. The switching units 6a to 6e have identical configurations. Thus, in the following description, only the configuration of the switching unit 6a will be described and the description of the other switching units 6b to 6e will be omitted.
One end of the first diversion pipe 63a is coupled to the high-pressure gas pipe 30. One end of the second diversion pipe 64a is coupled to the low-pressure gas pipe 31. The other end of the first diversion pipe 63a and the other end of the second diversion pipe 64a are mutually coupled at a coupling point. The coupling point is coupled to the indoor heat exchanger 81a via a refrigerant pipe. The first diversion pipe 63a is provided with the electromagnetic valve 61a. The second diversion pipe 64a is provided with the electromagnetic valve 62a. By opening or closing the electromagnetic valve 61a and the electromagnetic valve 62a, the refrigerant flow passage in the refrigerant circuit can be switched. Namely, by opening or closing the electromagnetic valve 61a and the electromagnetic valve 62a, the coupling of the indoor heat exchanger 81a of the indoor unit 8a corresponding to the switching unit 6a to the compressor 21a and/or the compressor 21b can be switched. Specifically, depending on the opening or closing of the electromagnetic valve 61a and the electromagnetic valve 62a, the indoor heat exchanger 81a is coupled to the discharge side (high-pressure gas pipe 30 side) of the compressor 21a and/or the compressor 21b, or the indoor heat exchanger 81a is coupled to the intake side (low-pressure gas pipe 31 side) of the compressor 21a and/or the compressor 21b.
As mentioned above, the switching units 6b to 6e have the same configuration as the configuration of the switching unit 6a. Namely, the constituent elements (devices and members) of the switching units 6b to 6e are designated by the signs designating the corresponding constituent elements of the switching unit 6a with the last letter “a” replaced with “b”, “c”, “d”, or “e”.
With reference to
To the closing valve 44a of the outdoor unit 2a, one end of the high-pressure gas branch pipe 30a is coupled. To the closing valve 44b of the outdoor unit 2b, one end of the high-pressure gas branch pipe 30b is coupled. The other end of the high-pressure gas branch pipe 30a and the other end of the high-pressure gas branch pipe 30b are coupled to the branching unit 70. To the branching unit 70, one end of the high-pressure gas pipe 30 is coupled. The other end of the high-pressure gas pipe 30 is branched and coupled to the first diversion pipes 63a to 63e of the switching units 6a to 6e.
To the closing valve 45a of the outdoor unit 2a, one end of the low-pressure gas branch pipe 31a is coupled. To the closing valve 45b of the outdoor unit 2b, one end of the low-pressure gas branch pipe 31b is coupled. The other end of the low-pressure gas branch pipe 31a and the other end of the low-pressure gas branch pipe 31b are coupled to the branching unit 71. To the branching unit 71, one end of the low-pressure gas pipe 31 is coupled. The other end of the low-pressure gas pipe 31 is branched and coupled to the second diversion pipes 64a to 64e of the switching units 6a to 6e.
To the closing valve 46a of the outdoor unit 2a, one end of the liquid branch pipe 32a is coupled. To the closing valve 46b of the outdoor unit 2b, one end of the liquid branch pipe 32b is coupled. The other end of the liquid branch pipe 32a and the other end of the liquid branch pipe 32b are coupled to the branching unit 72. To the branching unit 72, one end of the liquid pipe 32 is coupled. The other end of the liquid pipe 32 is branched and coupled to the refrigerant pipes to the indoor expansion valves 82a to 82e of the indoor units 8a to 8e.
The indoor heat exchangers 81a to 81e of the indoor units 8a to 8e are coupled to the coupling points between the first diversion pipes 63a to 63e and the second diversion pipes 64a to 64e of the corresponding switching units 6a to 6e via refrigerant pipes.
Via the above-described couplings, a refrigerant circuit of the air-conditioning apparatus 1 is configured. By causing refrigerant to flow in the refrigerant circuit, a refrigeration cycle can be implemented.
An operation of the air-conditioning apparatus 1 according to the present example will be described with reference to
The arrows in the drawing indicate the flow of the refrigerant.
In the example of
The electromagnetic valves 61a to 61c of the switching units 6a to 6c corresponding to the indoor units 8a to 8c that perform the cooling operation are closed to stop the flow of refrigerant in the first diversion pipes 63a to 63c. At the same time, the electromagnetic valves 62a to 62c are opened to allow the flow of refrigerant in the second diversion pipes 64a to 64c. Thus, the indoor heat exchangers 81a to 81c of the indoor units 8a to 8c serve as evaporators
On the other hand, the electromagnetic valves 61d and 61e of the switching units 6d and 6e corresponding to the indoor units 8d and 8e that perform the heating operation are opened, so that refrigerant flows in the first diversion pipes 63d and 63e. The electromagnetic valves 62d and 62e are closed, whereby the flow of refrigerant in the second diversion pipes 64d and 64e is stopped. Thus, the indoor heat exchangers 81d and 81e of the indoor units 8d and 8e serve as condensers.
The high-pressure refrigerant discharged from the compressor 21a flows in the outdoor unit high-pressure gas pipe 33a via the oil separator 28a. The high-pressure refrigerant is divided at the coupling point A toward the first three-way valve 22a and the second three-way valve 23a and toward the closing valve 44a. Similarly, the high-pressure refrigerant discharged from the compressor 21b flows in the outdoor unit high-pressure gas pipe 33b via the oil separator 28b. The refrigerant is divided at the coupling point H toward the first three-way valve 22b and the second three-way valve 23b and toward the closing valve 44b.
The refrigerant that has flowed into the first outdoor heat exchanger 24a via the first three-way valve 22a, and the refrigerant that has flowed into the second outdoor heat exchanger 25a via the second three-way valve 23a exchanges heat with the open-air, whereby the refrigerant is condensed.
The refrigerant condensed in the first outdoor heat exchanger 24a is passed through the first outdoor expansion valve 40a and turned into intermediate-pressure refrigerant. The degree of opening of the first outdoor expansion valve 40a is set by the CPU 110a in accordance with the refrigerant subcooling degree at the exit of the first outdoor heat exchanger 24a. The refrigerant subcooling degree is calculated, for example, by using the high pressure saturation temperature calculated on the basis of the pressure detected by the high pressure sensor 50a (corresponding to the condensation temperature at the first outdoor heat exchanger 24a), and the refrigerant temperature detected by the first liquid side refrigerant temperature sensor 59a.
The refrigerant condensed in the second outdoor heat exchanger 25a is passed through the second outdoor expansion valve 41a and turned into intermediate-pressure refrigerant. The degree of opening of the second outdoor expansion valve 41a is set by the CPU 110a in accordance with the refrigerant subcooling degree at the exit of the second outdoor heat exchanger 25a. The refrigerant subcooling degree is calculated by, for example, using the high pressure saturation temperature calculated on the basis of the pressure detected by the high pressure sensor 50a (corresponding to the condensation temperature at the second outdoor heat exchanger 25a), and the refrigerant temperature detected by the second liquid-side refrigerant temperature sensor 60a.
The refrigerant that has flowed into the first outdoor heat exchanger 24b via the first three-way valve 22b and the refrigerant that has flowed into the second outdoor heat exchanger 25b via the second three-way valve 23b exchange heat with the open-air, whereby the refrigerants are condensed. The refrigerant condensed in the first outdoor heat exchanger 24b is passed through the first outdoor expansion valve 40b and turned into intermediate-pressure refrigerant. The degree of opening of the first outdoor expansion valve 40b is set by the CPU 110b in accordance with the refrigerant subcooling degree at the exit of the first outdoor heat exchanger 24b. The refrigerant subcooling degree is calculated by, for example, using the high pressure saturation temperature calculated on the basis of the pressure detected by the high pressure sensor 50b (corresponding to the condensation temperature at the first outdoor heat exchanger 24b) and the refrigerant temperature detected by the first liquid side refrigerant temperature sensor 59b.
The refrigerant condensed in the second outdoor heat exchanger 25b is passed through the second outdoor expansion valve 41b and turned into intermediate-pressure refrigerant. The degree of opening of the second outdoor expansion valve 41b is set by the CPU 110b in accordance with the refrigerant subcooling degree at the exit of the second outdoor heat exchanger 25b.
The refrigerant subcooling degree is calculated by, for example, using the high pressure saturation temperature calculated on the basis of the pressure detected by the high pressure sensor 50b (corresponding to the condensation temperature at the second outdoor heat exchanger 25b) and the refrigerant temperature detected by the second liquid-side refrigerant temperature sensor 60b.
The refrigerant that has passed through the first outdoor expansion valve 40a and the refrigerant that has passed through the second outdoor expansion valve 41a converge at the coupling point B and then flow into the outdoor unit liquid pipe 35a. The refrigerant further flows into the liquid branch pipe 32a via the closing valve 46a. The refrigerant that has passed through the first outdoor expansion valve 40b and the refrigerant that has passed through the second outdoor expansion valve 41b converge at the coupling point J and then flow into the outdoor unit liquid pipe 35b. The refrigerant further flows into the liquid branch pipe 32b via the closing valve 46b. The refrigerants that flow in the liquid branch pipes 32a and 32b converge in the branching unit 72 and then flow into the indoor units 8a to 8c via the liquid pipe 32.
The refrigerant that has flowed into the indoor units 8a to 8c has its pressure reduced by the corresponding indoor expansion valves 82a to 82c, whereby low-pressure refrigerant is produced. The low-pressure refrigerant flows into the indoor heat exchangers 81a to 81c. The refrigerant that has flowed into the indoor heat exchangers 81a to 81c exchanges heat with the indoor air and is thereby evaporated. Thus, the indoor spaces in which the indoor units 8a to 8c are installed are cooled. The degree of opening of the indoor expansion valves 82a to 82c is determined in accordance with the degree of superheating of refrigerant at the refrigerant exit of the indoor heat exchangers 81a to 81c. The degree of superheating of refrigerant is determined by, for example, subtracting the refrigerant temperature at the refrigerant entry of the indoor heat exchangers 81a to 81c that is detected by the refrigerant temperature sensors 84a to 84c from the refrigerant temperature at the refrigerant exit of the indoor heat exchangers 81a to 81c that is detected by the refrigerant temperature sensors 85a to 85c.
The refrigerant that has flowed out of the indoor heat exchangers 81a to 81c flows into the corresponding switching units 6a to 6c. The refrigerant flows through the second diversion pipes 64a to 64c provided with the open electromagnetic valves 62a to 62c and then flows into the low-pressure gas pipe 31. The refrigerant that has flowed into the branching unit 71 through the low-pressure gas pipe 31 is divided at the branching unit 71 into the low-pressure gas branch pipe 31a and the low-pressure gas branch pipe 31b. The refrigerant that has flowed into the low-pressure gas branch pipe 31a flows into the outdoor unit 2a via the closing valve 45a. The refrigerant that has flowed into the outdoor unit 2a flows in the outdoor unit low-pressure gas pipe 34a. The refrigerant is suctioned by the compressor 21a via the accumulator 27a and compressed again. The refrigerant that has flowed into the low-pressure gas branch pipe 31b flows into the outdoor unit 2b via the closing valve 45b. The refrigerant that has flowed into the outdoor unit 2b flows in the outdoor unit low-pressure gas pipe 34b. The refrigerant is suctioned by the compressor 21b via the accumulator 27b and compressed again.
Meanwhile, the high-pressure refrigerant that has flowed from the coupling point A into the outdoor unit high-pressure gas pipe 33a and flowed into the high-pressure gas branch pipe 30a via the closing valve 44a, and the high-pressure refrigerant that has flowed from the coupling point H into the outdoor unit high-pressure gas pipe 33b and flowed into the high-pressure gas branch pipe 30b via the closing valve 44b converge in the branching unit 70. The converged high-pressure refrigerant flows through the high-pressure gas pipe 30 into the switching unit 6d and the switching unit 6e.
The high-pressure refrigerant that has flowed into the switching unit 6d flows through the first diversion pipe 63d with the open electromagnetic valve 61d and then flows out of the switching unit 6d. The high-pressure refrigerant then flows into the indoor unit 8d corresponding to the switching unit 6d. The high-pressure refrigerant that has flowed into the indoor heat exchanger 81d exchange heat with the indoor air and is thereby condensed. The high-pressure refrigerant that has flowed into the switching unit 6e flows through the first diversion pipe 63e with the open electromagnetic valve 61e and then flows out of the switching unit 6e. The high-pressure refrigerant then flows into the indoor unit 8e corresponding to the switching unit 6e. The high-pressure refrigerant exchange heat with the indoor air in the indoor heat exchanger 81e and is thereby condensed. Thus, the indoor air is heated, whereby the indoor spaces in which the indoor units 8d and 8e are installed are heated.
The high-pressure refrigerant that has flowed out of the indoor heat exchanger 81d is passed through the indoor expansion valve 82d and depressurized. The degree of opening of the indoor expansion valve 82d is determined in accordance with the subcooling degree of the refrigerant at the refrigerant exit of the indoor heat exchanger 81d. The high-pressure refrigerant that has flowed out of the indoor heat exchanger 81e is passed through the indoor expansion valve 82e and depressurized. The degree of opening of the indoor expansion valve 82e is determined in accordance with the subcooling degree of the refrigerant at the refrigerant exit of the indoor heat exchanger 81e. The subcooling degree of the refrigerant is calculated by, for example, subtracting the refrigerant temperature at the refrigerant exit of the indoor heat exchanger 81d or the indoor heat exchanger 81e that is detected by the refrigerant temperature sensor 84d or the temperature sensor 84e, from the high pressure saturation temperature calculated from the pressure detected by the high pressure sensor 50a of the outdoor unit 2a and the high pressure sensor 50b of the outdoor unit 2b (corresponding to the condensation temperature in the indoor heat exchangers 81d and 81e).
The refrigerant that has flowed out of the indoor unit 8d via the indoor expansion valve 82d and the refrigerant that has flowed out of the indoor unit 8e via the indoor expansion valve 82e flow through the liquid pipe 32 into the indoor units 8a to 8c performing the cooling operation.
The operation, function, and effect of the refrigerant circuit of the air-conditioning apparatus 1 will be described with reference to
The air-conditioning apparatus 1 directed in
The control not to use the second outdoor heat exchanger 25b of the outdoor unit 2b as described above or the control to decrease the number of the outdoor exchange heaters serving as condensers is effectively performed, for example, when the low pressure is difficult to be controlled by the compressors 21a and 21b or when the condensation capacity is excessive.
There may be a case where the rotation speed of the compressors 21a and 21b is increased to a performance upper-limit rotation speed so as to increase the high pressure in a low open-air temperature state. In such a case, because the low pressure is decreased as a result, it is preferable to increase the low pressure to a target low pressure. Thus, condensation capacity can be lowered by decreasing the number of the outdoor heat exchangers serving as condensers. In this way, the low pressure can be increased.
There may be a case where the condensation capacity of the indoor heat exchangers 81d and 81e, the first outdoor heat exchangers 24a and 24b, and the second outdoor heat exchangers 25a and 25b that are serving as condensers is excessive compared with the evaporation capacity of the indoor heat exchangers 81a to 81c serving as evaporators. In this case, condensation capacity is preferably decreased by decreasing the number of the outdoor heat exchangers serving as condensers.
When the refrigerant circuit of the air-conditioning apparatus 1 is in the state illustrated in
In this case, when the following conditions (refrigerant stagnation causing conditions) are satisfied, the refrigerant may be stagnated within the second outdoor heat exchanger 25b. The refrigerant stagnation causing conditions include an open-air temperature To detected by the open-air temperature sensor 58a and/or 58b being lower than a low pressure saturation temperature Ts calculated from the pressure detected by the low pressure sensor 51a and/or 51b (Ts corresponding to the evaporation temperature at the indoor heat exchangers 81a to 81c serving as evaporators). The refrigerant stagnation causing conditions also include the state in which the operation capacity of the compressor 21a and/or 21b cannot be increased (such as when the rotation speed of the compressor 21a and/or 21b is increased to the performance upper-limit rotation speed as described above); namely, the state in which the low pressure saturation temperature Ts cannot be lowered because the low pressure cannot be lowered. The refrigerant stagnation causing conditions further include such state continuing for a predetermined time (such as 10 minutes) or more. When these conditions are satisfied, the refrigerant remaining in the second outdoor heat exchanger 25b may be condensed and stagnated within the second outdoor heat exchanger 25b.
If such state continues for a long time and the amount of refrigerant stagnated in the second outdoor heat exchanger 25b at rest is increased, the amount of refrigerant circulating through the refrigerant circuit is decreased. As a result, the amount of refrigerant that flows through the indoor units 8a to 8e is decreased, resulting in a decrease in cooling capacity or heating capacity.
Control of the air-conditioning apparatus 1 in this regard will be described. For example, suppose that the refrigerant stagnation causing conditions are satisfied during the cooling operation or the cooling-main operation in a state where there is an unused outdoor heat exchanger. In this case, in the air-conditioning apparatus 1, all of the outdoor heat exchangers including the unused outdoor heat exchanger are caused to serve as condensers. Namely, refrigerant stagnation elimination control for causing the refrigerant stagnated in the unused outdoor heat exchanger to flow out of the outdoor heat exchanger is implemented.
In the following, the refrigerant stagnation elimination control will be described in detail with reference to
First, the CPUs 110a and 110b monitors the operation mode or operation capacity required by the users of the indoor units 8a to 8e via the communication units 130a and 130b. The CPUs 110a and 110b then determine whether the cooling operation or the cooling-main operation is to be performed (ST1).
When neither the cooling operation nor the cooling-main operation is to be performed (No in ST1), the CPUs 110a and 110b determine whether the refrigerant stagnation elimination control is being carried out (ST10). When the refrigerant stagnation elimination control is not being carried out (No in ST10), the CPUs 110a and 110b advance to ST12. When the refrigerant stagnation elimination control is being carried out (Yes in ST10), the CPUs 110a and 110b terminate the refrigerant stagnation elimination control (ST11). The CPU 110a then switches the first three-way valve 22a and the second three-way valve 23a of the outdoor unit 2a, and implements the heating operation or the heating-main operation. Similarly, the CPU 110b switches the first three-way valve 22b and the second three-way valve 23b of the outdoor unit 2b, and implement the heating operation or the heating-main operation (ST12).
Specifically, the CPU 110a switches the first three-way valve 22a so as to provide communication between the port b and the port c. Also, the CPU 110a switches the second three-way valve 23a so as to provide communication between the port e and the port f (the state indicated by broken lines in
The degree of superheating of refrigerant can be determined by using the low pressure saturation temperature calculated on the basis of the pressure detected by the low pressure sensor 51a, and the refrigerant temperature detected by the first gas side refrigerant temperature sensor 56a and/or the refrigerant temperature detected by the second gas side refrigerant temperature sensor 57a, for example. The CPU 110a determines the degree of superheating of refrigerant periodically (such as at 30 second intervals), and adjusts the degree of opening of the first outdoor expansion valve 40a and/or the degree of opening of the second outdoor expansion valve 41a.
Similarly, the CPU 110b switches the first three-way valve 22b to provide communication between the port h and the port j. Also, the CPU 110b switches the second three-way valve 23b to provide communication between the port m and the port n (the state indicated by broken lines in
The degree of superheating of refrigerant can be calculated by using the low pressure saturation temperature calculated on the basis of the pressure detected by the low pressure sensor 51b, and the refrigerant temperature detected by the first gas side refrigerant temperature sensor 56b and/or by the second gas side refrigerant temperature sensor 57b, for example. The CPU 110b determines the degree of superheating of refrigerant periodically (such as at 30 second intervals), and adjusts the degree of opening of the first outdoor expansion valve 40b and/or the degree of opening of the second outdoor expansion valve 41b.
The CPUs 110a and 110b control the corresponding outdoor units 2a and 2b as described above to implement the heating operation or the heating-main operation, and then return the process to ST1.
When the cooling operation or the cooling-main operation is to be performed (Yes in ST1), the CPUs 110a and 110b determine whether there is the outdoor heat exchanger that is not used (ST2). When there is no unused outdoor heat exchanger (when all of the outdoor heat exchangers are in operation; No in ST2), the refrigerant circuit of the air-conditioning apparatus 1 is in the state illustrated in
When there is the unused outdoor heat exchanger (Yes in ST2), the refrigerant circuit of the air-conditioning apparatus 1 is in the state illustrated in
Further, the first three-way valve 22b of the outdoor unit 2b is switched to provide communication between the port g and the port h. Also, the second three-way valve 23b is switched to provide communication between the port m and the port n (the state indicated by solid lines in
In the above refrigerant circuit, the CPU 110a drives the compressor 21a at the rotation speed corresponding to the required operation capacity. Also, the CPU 110a sets the degree of opening of the first outdoor expansion valve 40a and the second outdoor expansion valve 41a to the degree of opening corresponding to the refrigerant subcooling degree at the exit of the first outdoor heat exchanger 24a and the second outdoor heat exchanger 25a. The refrigerant subcooling degree can be determined by, for example, using the high pressure saturation temperature calculated on the basis of the pressure detected by the high pressure sensor 50a and the refrigerant temperature detected by the first liquid side refrigerant temperature sensor 59a and/or the second liquid-side refrigerant temperature sensor 60a. The CPU 110a determines the refrigerant subcooling degree periodically (such as at 30 second intervals), and adjusts the degree of opening of the first outdoor expansion valve 40a and/or the second outdoor expansion valve 41a.
Further, the CPU 110b drives the compressor 21b at the rotation speed corresponding to the required operation capacity. Also, the CPU 110b sets the degree of opening of the first outdoor expansion valve 40b to the degree of opening corresponding to the refrigerant subcooling degree at the exit of the first outdoor heat exchanger 24b and the second outdoor heat exchanger 25b. The CPU 110b also fully closes the second outdoor expansion valve 41b. The refrigerant subcooling degree can be determined by using, for example, the high pressure saturation temperature calculated on the basis of the pressure detected by the high pressure sensor 50b, and the refrigerant temperature detected by the first liquid side refrigerant temperature sensor 59b and/or the second liquid-side refrigerant temperature sensor 60b. The CPU 110b determines the refrigerant subcooling degree periodically (such as at 30 second intervals), and adjusts the degree of opening of the first outdoor expansion valve 40b.
The CPUs 110a and 110b control the corresponding outdoor units 2a and 2b as described above to implement the cooling-main operation.
Next, the CPUs 110a and 110b monitor the open-air temperature To detected by the open-air temperature sensors 58a and 58b (ST3). Also, the CPUs 110a and 110b monitor the pressure detected by the low pressure sensors 51a and 51b. The CPUs 110a and 110b calculate the low pressure saturation temperature Ts by using the monitored pressure (ST4). The CPUs 110a and 110b conduct the monitoring of the open-air temperature To and the calculation of the low pressure saturation temperature Ts periodically (such as at five intervals).
Next, the CPUs 110a and 110b determine whether the refrigerant stagnation causing conditions are satisfied (ST5). As described above, the refrigerant stagnation causing conditions are used to determine the probability of refrigerant stagnation in the second outdoor heat exchanger 25b at rest. The refrigerant stagnation causing conditions include, as described above, whether the monitored open-air temperature To is lower than the calculated low pressure saturation temperature Ts, and whether the state in which the operation capacity of the compressors 21a and 21b cannot be increased continues for a predetermined time, such as 10 minutes, or longer.
When the refrigerant stagnation causing conditions are not satisfied (No in ST5), the CPUs 110a and 110b return the process to ST1. When the refrigerant stagnation causing conditions are satisfied (Yes in ST5), the CPUs 110a and 110b implement the refrigerant stagnation elimination control (ST6). The refrigerant stagnation elimination control involves causing all of the outdoor heat exchangers including the outdoor heat exchanger at rest to serve as condensers, so that the refrigerant stagnated in the unused outdoor heat exchanger can flow out of the outdoor heat exchanger. According to the present example, the second outdoor heat exchanger 25b at rest is caused to serve as a condenser. Thus, the CPU 110b controls the second three-way valve 23b and the second outdoor expansion valve 41b.
Specifically, the CPU 110b switches the second three-way valve 23b to provide communication between the port k and the port m. The CPU 110b also sets the degree of opening of the second outdoor expansion valve 41b to the degree of opening corresponding to the refrigerant subcooling degree at the exit of the second outdoor heat exchanger 25b. Thus, the second outdoor heat exchanger 25b serves as a condenser. Thus, all of the outdoor heat exchangers (the first outdoor heat exchangers 24a and 24b, and the second outdoor heat exchangers 25a and 25b) serve as condensers. Namely, the refrigerant circuit illustrated in
As described above, in the air-conditioning apparatus 1, the refrigerant stagnation elimination control such that the unused second outdoor heat exchanger 25b is caused to serve as a condenser is implemented. As a result, the refrigerant stagnated in the second outdoor heat exchanger 25b can be caused to flow out of the second outdoor heat exchanger 25b. The refrigerant then flows out of the outdoor unit 2b via the second outdoor expansion valve 41b and through the outdoor unit liquid pipe 35b. Thus, refrigerant stagnation in the second outdoor heat exchanger 25b can be eliminated.
The CPUs 110a and 110b, during the refrigerant stagnation elimination control, increase and decrease the rotation speed of the outdoor fans 26a and 26b between zero and 900 rpm at a predetermined rate (such as 100 rpm/20 sec) for the following reason. When the refrigerant stagnation elimination control is being implemented, the number of the condensers is increased compared to the refrigerant circuit illustrated in
The CPUs 110a and 110b periodically monitor the high pressure detected by the high pressure sensors 50a and 50b. The CPUs 110a and 110b cause the rotation speed of the outdoor fans 26a and 26b to be varied between 0 and 900 rpm in accordance with the pressure difference between the monitored high pressure and the target high pressure. For example, when the high pressure drops below the target high pressure due to the increase in the number of the outdoor heat exchangers serving as gas condensers with the resultant excess condensation capacity, the CPUs 110a and 110b cause the rotation speed of the outdoor fans 26a and 26b to be decreased at a predetermined rate. Namely, the CPUs 110a and 110b decrease the ventilation volume in each of the outdoor heat exchangers. Thus, the condensation capacity in each outdoor heat exchanger is lowered, and the high pressure is increased. Thus, the decrease in high pressure due to excess condensation capacity can be mitigated or eliminated, so that the decrease in heating capacity in the indoor units 8d and 8e performing the heating operation can be suppressed.
Next, the CPUs 110a and 110b determine whether a refrigerant stagnation elimination condition is satisfied (ST7). The refrigerant stagnation elimination condition is such that refrigerant stagnation is not caused in the outdoor heat exchangers even if there is the unused outdoor heat exchanger. Specifically, the refrigerant stagnation elimination condition includes whether a state in which the temperature obtained by subtracting a predetermined temperature (such as 2° C.) from the monitored open-air temperature To is higher than the low pressure saturation temperature Ts has continued for a predetermined time, such as five minutes, or more. When the refrigerant stagnation elimination condition is satisfied, the probability of refrigerant stagnation in the unused outdoor heat exchanger, if any, can be relatively decreased.
As described above, the refrigerant stagnation elimination condition involves the comparison of the temperature obtained by subtracting a predetermined temperature from the open-air temperature To and the low pressure saturation temperature Ts. If, as the refrigerant stagnation eliminating condition, the open-air temperature To and the low pressure saturation temperature Ts are compared without subtracting the predetermined temperature from the open-air temperature To and the refrigerant stagnation elimination control is stopped, the refrigerant stagnation causing condition may be satisfied again soon thereafter, followed by the implementation of the refrigerant stagnation elimination control, and this may occur frequently. Thus, in order to prevent this, the temperature obtained by subtracting a predetermined temperature from the open-air temperature To is compared with the low pressure saturation temperature Ts.
When the refrigerant stagnation eliminating condition is not satisfied (No in ST7), the CPUs 110a and 110b return the process back to ST1. When the refrigerant stagnation eliminating condition is satisfied (Yes in ST7), the CPUs 110a and 110b terminate the refrigerant stagnation elimination control (ST8).
Then, the CPUs 110a and 110b determine whether, given the operation of all of the indoor units 8a to 8e is stopped, the operation of the outdoor units 2a and 2b are to be stopped (ST9). When the operation is to be stopped (Yes in ST9), the CPUs 110a and 110b cause the corresponding compressor 21a or 21b to be stopped. Further, the CPUs 110a and 110b cause the corresponding first outdoor expansion valve 40a or 40b, and the corresponding second outdoor expansion valve 41a or 41b to be fully closed, and end the process. When the operation need not be stopped (No in ST9), the CPUs 110a and 110b return the process back to ST1.
As described above, the air-conditioning apparatus according to the present disclosure can suppress the stagnation of refrigerant in the outdoor heat exchanger at rest. Namely, when refrigerant stagnation occurs in the unused outdoor heat exchanger during the cooling operation or the cooling-main operation of the air-conditioning apparatus 1, all of the outdoor heat exchangers including the unused outdoor heat exchanger are caused to serve as condensers. Thus, the stagnated refrigerant can be caused to flow out of the outdoor heat exchanger, so that the refrigerant stagnation can be eliminated. Thus, the lack of refrigerant in the indoor units performing the cooling operation can be remedied, and, as a result, the decrease in cooling and/or heating capacity can be suppressed.
In the foregoing example, when the refrigerant stagnation causing conditions are satisfied, all of the outdoor heat exchangers including the unused outdoor heat exchanger are caused to serve as condensers. However, an outdoor fan may not be able to rotate due to a failure in its motor and the like. In such a case, the outdoor heat exchanger corresponding to the outdoor fan may preferably be not used as a condenser when the refrigerant stagnation elimination control is implemented.
The air-conditioning apparatus according to the present disclosure may be expressed as a first air-conditioning apparatus as follows. The first air-conditioning apparatus comprises: at least one outdoor unit including at least one compressor, an outdoor fan, a plurality of outdoor heat exchangers, a flow passage switching means coupled to one refrigerant inlet/outlet opening of each of the outdoor heat exchangers and configured to switch the coupling of the outdoor heat exchangers to a refrigerant discharge opening or a refrigerant intake opening of the compressor, a flow rate adjustment means coupled to another refrigerant inlet/outlet opening of each of the outdoor heat exchangers and configured to adjust the refrigerant flow rate in the outdoor heat exchangers, an open-air temperature detection means configured to detect an open-air temperature, a low-pressure detection means configured to detect the pressure on a low-pressure side of the compressor, and a control means configured to control the flow passage switching means or the flow rate adjustment means; a plurality of indoor units including an indoor heat exchanger; and a plurality of switching units corresponding to the plurality of the indoor units and configured to switch the direction of refrigerant flow in the indoor heat exchanger, wherein: the outdoor unit and the plurality of the switching units are coupled via a high-pressure gas pipe and a low-pressure gas pipe; the plurality of the indoor units is coupled to the at least one outdoor unit via a liquid pipe; the plurality of the indoor units and the corresponding plurality of the switching units are coupled via a refrigerant pipe; and the control means causes all of the outdoor heat exchangers to serve as condensers when the outdoor heat exchangers include an outdoor heat exchanger serving as a condenser and an outdoor heat exchanger at rest, and when a state in which the open-air temperature detected by the open-air temperature detection means is lower than a low pressure saturation temperature calculated by using the pressure on the low-pressure side which is detected by the low-pressure detection means continues for a predetermined time.
According to the first air-conditioning apparatus, when refrigerant stagnation is caused in the outdoor heat exchanger at rest during the cooling operation or the cooling-main operation by the outdoor heat exchanger serving as a condenser, all of the outdoor heat exchangers including the unused outdoor heat exchanger are caused to serve as condensers. In this way, the stagnated refrigerant can be caused to flow out of the outdoor heat exchanger so that the refrigerant stagnation can be eliminated. Thus, the lack of refrigerant in the indoor unit performing the cooling operation can be eliminated, and the decrease in cooling/heating capacity can be prevented.
The foregoing detailed description has been presented for the purposes of illustration and description. Many modifications and variations are possible in light of the above teaching. It is not intended to be exhaustive or to limit the subject matter described herein to the precise form disclosed. Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims appended hereto.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2012-153762 | Jul 2012 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 20130019622 | Nakashima et al. | Jan 2013 | A1 |
| 20130081417 | Tamura et al. | Apr 2013 | A1 |
| Number | Date | Country |
|---|---|---|
| 2004-286253 | Oct 2004 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20140007601 A1 | Jan 2014 | US |
