JPH0772647B2 - Pressure equalizer for air conditioner - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a pressure equalizing device for equalizing high and low pressures in an air conditioner in order to facilitate restarting after stopping a compressor.

(Prior Art) In an air conditioner, when the compressor is restarted immediately after being stopped, the pressure difference between the discharge side gas pressure (high pressure) and the suction side gas pressure (low pressure) of the compressor is large. Overcurrent may flow to the motor and its protective device may operate. In particular, in an inverter-driven compressor, a trip occurs due to an instantaneous overcurrent, and continuous operation thereafter cannot be performed.

For this reason, conventionally, in Japanese Utility Model Laid-Open No. 53-162453, the discharge side and the suction side of a compressor are connected by a bypass path, and when the compressor is stopped, the bypass path is opened so that the high pressure and the low pressure of the compressor are reduced. It has been proposed to reduce the pressure difference between. Further, in the one disclosed in Japanese Utility Model Laid-Open No. 56-149841, the restart of the compressor is stopped for a certain time from the time when the compressor is stopped, and a restart standby period is set, during which the high and low pressure difference of the compressor is set. Is designed to reduce.

(Problems to be solved by the invention) By the way, when the bypass passage is opened as in the conventional case, if the bypass passage is left open, the liquid refrigerant staying in the high-pressure side condenser or the like moves to the suction circuit. Then, when the compressor is restarted, so-called liquid back may occur, so that the bypass passage is opened only in the restart waiting period of the compressor.

However, if the bypass passage is opened only during the restart standby of the compressor in this way, when the bypass passage is closed after the restart standby period elapses, the compressor is accompanied by the closing of the bypass passage. The high / low pressure difference may increase. For example, when the outside air temperature is low in the heating operation mode, the indoor temperature is high, so the refrigerant evaporates in the indoor heat exchanger, and the high pressure rises as a result. On the contrary, when the outdoor air temperature is high in the cooling operation mode, when the refrigerant condenses in the indoor heat exchanger, it is pulled by it and the low pressure decreases,
These increase the high / low pressure difference. At this time, since the compressor is started in a high differential pressure state, there is a problem that the continuous operation becomes impossible.

The present invention has been made in view of these points, and an object of the present invention is to control the high pressure and the low pressure difference when the compressor is restarted by controlling the restart limitation and opening / closing of the bypass passage of the compressor. The purpose of this is to ensure that the amount can be reduced and to enable continuous operation without abnormally stopping the compressor.

(Means for Solving the Problems) In order to achieve the above object, in the invention according to claim (1),
The bypass is opened until a certain period of time elapses after the compressor is stopped. Further, after that, when the bypass path is once closed and there is a request to start the compressor, first, after opening the bypass path, the compressor is started after a certain time has elapsed.

Specifically, in the present invention, as shown in FIG. 1, a compressor (1), outdoor heat exchangers (2a), (2b), pressure reducing mechanisms (25a), (25b), (51) and A bypass path (42) for connecting the discharge side of the compressor (1) to the suction side of an air conditioner equipped with a refrigerant circuit (3) in which an indoor heat exchanger (5) is connected in a closed circuit. And an opening / closing means (42) for opening / closing the bypass path (42).

After the compressor (1) is stopped, the start of the compressor (1) is restricted until the first set time (T ₁ ) elapses, and the first
The opening / closing means (42) is opened until the second set time (T ₂ ) longer than the set time (T ₁ ) elapses, and the second set time (T ₂ ) is changed from the stop of the compressor (1). After a lapse of time, the opening / closing means (42) is closed, and after the closing operation of the opening / closing means (42), when the start request signal of the compressor (1) is input,
After opening the opening / closing means (42) for a predetermined time, the compressor (1)
A control means (6) for controlling to start the motor is provided.

Further, in the invention according to claim (2), since the amount of refrigerant is large, the configuration is as follows as an air conditioner that can expect particularly effective effects. That is, the air conditioner has a compressor (1), one end of which is switchably connected to the discharge side and the suction side of the compressor (1), and a plurality of heat source side heat exchangers (2a) provided in parallel, (2b) and the heat source side heat exchanger (2a),
A plurality of heat source side pressure reducing mechanisms (25a), (25b) provided corresponding to each of (2b) and capable of controlling the pressure reduction and flow rate of the refrigerant;
A utilization side heat exchanger (5), one end of which is switchably connected to the discharge side and the suction side of the compressor (1), and which is provided corresponding to each of the utilization side heat exchanger (5), the refrigerant And a switching mechanism (21a), (21b) for switching the refrigerant flow direction so that the usage-side heat exchanger (5) becomes an evaporator or a condenser. Is provided with a refrigerant circuit (3).

(Operation) With the above configuration, in the invention according to claim (1), the control means (6) causes the first time from when the compressor (1) is stopped.
The start of the compressor (1) is prohibited until the set time (T ₁ ) elapses. Further, the opening / closing means (42) is opened and the bypass path (42) is opened until the second set time (T ₂ ) elapses. Then, if the second set time (T ₂ ) is set to a time at which the high and low pressure difference of the compressor (1) is sufficiently equalized, when the compressor (1) is restarted, Since the difference between the high pressure and the low pressure is small, the compressor (1) can be started without being in the high differential pressure state.

In addition, the opening / closing means (42a) after the elapse of the second set time (T ₂ ).
Is closed and the bypass passage (42) is closed. When the start request signal of the compressor (1) is input to the control means (6) after this closing, the opening / closing means (42) is opened for a predetermined time. After that, the compressor (1) is started. Therefore, since the bypass passage (42) is opened at the time of starting the compressor (1), the high / low pressure difference is kept low, and thus the compressor (1) can be started in the low differential pressure state.

In the invention according to claim (2), the air conditioner has a plurality of heat source side heat exchangers (2a), (2b), and since this has a long pipe length and a large amount of refrigerant, it is compressed. Liquid backing is remarkable when the machine (1) is stopped, and the above effect can be effectively obtained by applying this to the air conditioner.

(Embodiment) An embodiment of the present invention will be described below with reference to the drawings starting from FIG.

FIG. 2 shows an air conditioner (X) according to an embodiment of the present invention, and this air conditioner (X) is one outdoor unit (A).
In contrast, multiple indoor units (3 in the figure) (B),
(B), ... is a multi-type air conditioner in which they are connected in parallel.

The outdoor unit (A) includes a compressor (1) and two outdoor heat exchangers (2a) and (2b) which are heat source side heat exchangers. The compressor (1) is an unloader (not shown) that differentiates the first compressor (1a) whose capacity is adjusted by an inverter (not shown) whose output frequency is variably switched, and a pilot pressure differential. Depending on the capacity, it can be fully loaded (eg 100%) and unloaded (50%).
It is a variable capacity type that is connected in parallel through a check valve (1c) and a second compressor (1b) that is adjusted in stages, and is of the above-mentioned first and second compressors (1a), (1b). On the discharge side, the oil in the gas discharged from the compressors (1a) and (1b) is separated and returned to the suction side of the compressors (1a) and (1b).
And second oil separators (1d) and (1e) are provided.

The high pressure gas line (31) of the refrigerant circuit (3) is on the discharge side of the compressor (1), and the low pressure gas line (3) is on the suction side.
2) are connected respectively. Further, the outdoor heat exchangers (2a), (2b) are provided in parallel with the compressor (1), and one end of each outdoor heat exchanger (2a), (2b) is switched to four paths. Gas pipe (22) with valves (21a) and (21b)
While being switchably connected to the high pressure gas line (31) and the low pressure gas line (32) via a) and (22b),
Liquid pipes (33a), (33b) of the liquid line (33) in the refrigerant circuit (3) are provided at the other ends of the outdoor heat exchangers (2a), (2b).
Are connected. Then, the four-way switching valves (21
a) and (21b) are gas pipes (22a) and (22b) when the outdoor heat exchangers (2a) and (2b) function as condensers.
Is switched to the solid line in the figure so as to communicate with the high pressure gas line (31), while the outdoor heat exchangers (2a) and (2b) function as evaporators, the gas pipe (22a) ,(twenty two
b) is switched to the broken line in the figure so as to communicate with the low pressure gas line (32). In addition, the four-way selector valve (21
One of the ports a) and (21b) is the capillary (23
Gas pipes (22a), (4a) between the four-way switching valves (21a), (21b) and the low-pressure gas line (32) via connection pipes (24a), (24b) equipped with (a), (23b). 22b).

Further, the high pressure gas line (31) has a gas pipe (22
a), one-way valves (4), (4) on the downstream side (indoor unit (B) side) of the connection of (22b), and gas pipes (22a), () on the low-pressure gas line (32). An accumulator (41) is arranged on the downstream side (compressor (1) side) of the connection part of 22b). In addition, the gas pipes (22a), (22
High pressure gas gas line (31) upstream of the connection in b)
And a low-pressure gas line (32) downstream of the connection between the gas pipes (22a) and (22b) and upstream of the accumulator (41), in other words, the discharge side of the compressor (1). A pressure equalizing bypass passage (42) is connected to the suction side. An opening / closing valve (42a) as an opening / closing means and a flow rate adjusting capillary (42b) are arranged in the pressure equalizing bypass passage (42).

Further, the liquid pipes (33a), (3
3b) is connected to a receiver (43) so that the respective liquid refrigerants merge with each other, and the liquid line (3) is connected to the receiver (43).
The main liquid pipe (33c) of 3) is connected. Further, outdoor electric expansion valves (25a) and (25b), which are heat source side pressure reducing mechanisms, are arranged in the liquid pipes (33a) and (33b), respectively, and the outdoor electric expansion valves (25a) and (25a) 25b) reduces the pressure of the liquid refrigerant when the outdoor heat exchangers (2a) and (2b) function as evaporators, and regulates the flow rate of the liquid refrigerant when it functions as a condenser.

Between the downstream side of the one-way valve (4) in the high pressure gas line (31), which is the discharge side of the compressor (1), and the receiver (43), so-called hot gas that is a high pressure gas refrigerant is sent to the receiver (43). The hot gas bypass line (45) is connected to the hot gas bypass line (45), and a hot gas on-off valve (45a) and a capillary (45b) for adjusting the flow rate of the hot gas are arranged in the hot gas bypass line (45).

Meanwhile, the high pressure gas line (31) and the low pressure gas line (3
2) and each of the main liquid pipe (33) are extended to the indoor side,
The high-pressure gas line (31) is connected to the high-pressure branch pipes (31b), (31b), ... via the flow divider (31a), and the low-pressure gas line (3
2) is a low pressure branch pipe (32b), (32
b), ... And the main liquid pipe (33) is branched via a flow divider (33d) into liquid branch pipes (33e), (33e), ..., and these branch pipes (31b), (32b). , (33e) are connected to the indoor units (B), (B), ....

The indoor units (B), (B), ... Have the same structure, and each have an indoor heat exchanger (5) that is a usage-side heat exchanger and an indoor electric expansion valve (51) that is a usage-side decompression mechanism. I have it. The indoor electric expansion valve (51) is the liquid branch pipe (33e).
The liquid branch pipe (33e) is connected to one end of the indoor heat exchanger (5), and the other end of the indoor heat exchanger (5) is connected to the high pressure via the gas pipe (5a). It is connected to the branch pipe (31b) and the low pressure branch pipe (32b). The high-pressure branch pipe (31b) and the low-pressure branch pipe (32b) are provided with open / close valves (52) and (53) at the gas pipe (5a) side ends, respectively. , (53) are controlled to open and close to switch the indoor heat exchanger (5) to the high pressure gas line (31) and the low pressure gas line (32), and the indoor heat exchanger (5) functions as an evaporator. Low pressure side open / close valve (53) when operating (when cooling)
Is configured to open the high-pressure side on-off valve (52) when functioning as a condenser (during heating).

Furthermore, the liquid branch pipe (33e) of the indoor unit (B) and the low pressure branch pipe (32b) downstream of the on-off valve (53) are connected by a low pressure bypass passage (54). A bypass valve (54a) and a capillary (54b) are arranged in 54). In addition, the low pressure bypass (5
Piping heat exchanger (54c) between 4) and liquid branch pipe (33e)
Is formed to prevent the flush flow of the liquid refrigerant flowing out from the indoor heat exchanger (5) during heating. Further, a high pressure bypass passage (55) having a flow rate adjusting capillary (55a) between the upstream side of the on-off valve (52) in the high pressure branch pipe (31b) and the gas pipe (5a).
And is configured to bypass the condensed liquid accumulated in the high pressure branch pipe (31b) and the like during cooling. Then, the on-off valves (52), (53) and both bypass passages (5
4) and (55) are integrally stored in a kit (56), and include a compressor (1), outdoor heat exchangers (2a) and (2b), indoor heat exchangers (5) and (5). ), ... are high pressure gas lines (3
1), a low pressure gas line (32) and a liquid line (33) are connected to form a refrigerant circuit (3).

Incidentally, (26) is an outdoor fan which is arranged in the vicinity of the outdoor heat exchangers (2a), (2b), and (44) is a low pressure gas line (3
It is a suction heat exchanger that exchanges heat between 2) and the main liquid pipe (33c). Reference numeral (57) is an indoor fan that is arranged close to the indoor heat exchanger (5).

Further, various sensors are arranged in the refrigerant circuit (3). That is, (Th1) is a liquid temperature sensor that detects the temperature of the liquid refrigerant in the indoor unit (B), (Th2) is a gas temperature sensor that detects the temperature of the gas refrigerant in the indoor unit (B),
(Th3) is a room temperature sensor that detects the temperature of the intake air of the indoor fan (57). (Th4) is the outdoor heat exchanger (2a),
Liquid temperature sensor to detect the temperature of liquid refrigerant on (2b) side, (Th5)
Is a gas temperature sensor that detects the temperature of the discharged gas refrigerant on the outdoor heat exchanger (2a), (2b) side, (Th6) is an outside air temperature sensor that detects the outside air temperature, and (Th7) is the discharge of the compressor (1) Discharge gas temperature sensor for detecting gas refrigerant temperature, (HPS) is a high pressure pressure sensor for detecting discharge gas refrigerant pressure of the compressor (1),
(LPS) is a low-pressure pressure sensor that detects the pressure of the suction gas refrigerant of the compressor (1).

And, (6) is a control device with a built-in CPU that controls the operation of each device in the refrigerant circuit (3).
Only the pressure equalization control and the compressor (1) operation control for the on-off valve (42a) in the pressure equalization bypass passage (42) will be described. In this controller (6), the control procedure for the on-off valve (42a) and the compressor (1) is performed according to the flow chart shown in FIG. That is, first, in step S ₁ , timer 1 is set to 10 minutes and timer 2 is set to 3 minutes. The timer 1 sets a second set time (T ₂ ) for opening the open / close valve (42a) and stopping the pressure equalizing bypass passage (42) after the compressor (1) is stopped.
The timer 2 sets a first set time (T ₁ ) for prohibiting restart of the compressor (1) after stopping the compressor (1). Then, opening and closing valve (42a) by ON operation causes opened in step S _2, the compressor (1) is stopped and further counts the timers 1 and 2. After this, step S
_{In 3} , it is judged whether or not the timer 2 is up,
If NO during counting, repeat steps S ₂ and S ₃ .
When the determination is YES due to the time-up of the timer 2, the process proceeds to step S ₄ , where the open / close valve (42a) is kept open and the compressor (1) is kept stopped, and the timer 1 is counted. Temperature sensor in step S ₅ (Th
The thermo-ON 3) determines whether there is a start request of the compressor (1), when the determination is NO "no start request", the timer 1 to determine whether the time is up in step S ₆ If the determination is NO, the process returns to step S ₄ .
On the other hand, if the determination made in step S ₆ is YES due to the time-up of the timer 1, the opening / closing valve (42 a) is set to OF in step S _7.
Together to close by F operation, the compressor (1) is stopped and held again at the next step S _8, it determines whether there is a start request of the compressor (1) by thermo-ON. While this determination is repeated step S _7, S ₈ when the NO "no start request", when determined by the "Yes start request" is YES, and sets the timer 4 to 10 seconds at step S _9. The timer 4 is for avoiding the high-low pressure difference of the compressor (1) remaining when the opening / closing valve (42a) is closed. After this step S _9, the opening and closing valve (42a) by ON operation causes opened in step S _10, the compressor (1) is stopped and held, further counting the timer 4. Next, in step S _11, it is determined whether or not there is a request for starting the compressor (1). If this determination is “no request for starting”, the process returns to the first step S ₁ , but it is determined by “with starting request”. There when NO, step S ₁₂
In determining the time up of the timer 4, while repeating steps S ₁₀ to S ₁₂ when not time-up, sometimes the time is up, the determination in step S ₅ YES
The process proceeds to step S ₁₃ with the time of setting the timer 3 per minute. The timer 3 is used to set the time for opening the bypass passage (42) at the start of the compressor (1), after step S _13, O-off valve (42a) in Step S ₁₄
The valve is activated by opening the valve N, the compressor (1) is started, and the timer 3 is counted. Then
Step S determines whether there is a start request of the compressor (1) at _15, but the judgment is back to the first step S ₁ is affirmative (YES) "no start request", "there start request"
If the judgment is NO due determines timeout of the timer 3 in step S _16, the process returns to step S ₁₄ in the absence of time-up, the process proceeds to step S ₁₇ when the time is up, OFF operation off valve (42a) Then, the valve is closed and the compressor (1) is started. Determining whether the next request for starting the compressor (1) in step S _18, the determination is negative (NO) "with the starting request", while repeating the steps S _17, S _18, first when the YES Return to step S ₁ .

Therefore, in this embodiment, due to the flow in the control device (6), after the compressor (1) is stopped, the compressor (1) is operated until the first set time (T ₁ ) set by the timer 2 elapses. The second set time (T ₂ ) that regulates the start and is set by the timer 1 and is longer than the first set time (T ₁ )
The opening / closing means is opened until the time elapses, and the opening / closing valve (42a) is closed when the second set time (T ₂ ) elapses from the stop of the compressor (1) to close the opening / closing valve (42a). After that, when the start request signal of the compressor (1) is input,
After opening the on-off valve (42a) for a predetermined time set by the timer 4, the compressor (1) is started.

Next, the air conditioning operation of this air conditioner (X) will be described.

First, when performing cooling operation of each indoor unit (B), (B), ..., Both four-way switching valves (21a) of the outdoor unit (A),
(21b) is switched to the solid line in Fig. 2 and the gas pipe (22a),
(22b) communicates with the high pressure gas line (31). Further, in each indoor unit (B), (B), ...
2) is closed and the low-pressure side on-off valve (53) is opened, so that the gas pipe (5a) communicates with the low-pressure branch pipe (32b). In this state, the high-pressure gas refrigerant discharged from the compressor (1) flows into the outdoor heat exchangers (2a), (2b) to be condensed, and the condensed liquid refrigerant passes through the liquid line (33). Flows to each indoor unit (B), (B), ..., Indoor electric expansion valve (51),
After expansion at (51), ..., Each indoor heat exchanger (5),
(5), ... Evaporates, flows through the low pressure gas line (32), and returns to the compressor (1).

On the other hand, when the indoor units (B), (B), ... Are heated, the refrigerant flows in the opposite direction to that during cooling. That is, the four-way switching valves (21a) (21b) of the outdoor unit (A) are switched to the broken line in FIG. 2, and the high-pressure side on-off valve (52) is opened in each indoor unit (B), (B), .... The low-pressure side on-off valve (53) is closed, and the refrigerant from the high-pressure gas line (31) is condensed in the indoor heat exchanger (5) and then flows through the liquid line (33) to the outdoor electric expansion valve (25a). ), (25b), expands, evaporates in the outdoor heat exchangers (2a), (2b) and returns to the compressor (1).

Then, during the cooling operation, for example, when the open / close state of both on-off valves (52), (53) in one indoor unit (B) is switched, heating operation is performed, and conversely, during the heating only operation, for example, 1 When the on-off valves (52) and (53) of the indoor unit (B) of one unit are switched, the cooling operation is performed, and so-called simultaneous cooling and heating operation is performed. At that time, for example, when two of all the indoor units (B), (B), ... Are operated in heating operation and the other one is operated in cooling operation, the indoor units (B), (B) in heating operation The liquid refrigerant that has flowed out merges in the flow divider (33d) of the liquid line (33), then flows to the indoor unit (B) in the cooling operation, evaporates, and returns to the compressor (1) from the low pressure gas line (32). become.

During this simultaneous cooling and heating operation, the two outdoor heat exchangers (2a) and (2b) operate as evaporators or condensers according to the indoor load, and one is operated and the other one is operated. Will stop driving.

During operation of such an air conditioner (X), for example, room temperature sensors (Th3) of all indoor units (B), (B), ...
(Th3), ... may turn off the thermostat and the compressor (1) may stop. The change in refrigerant pressure between the discharge side and the suction side of the compressor (1) at that time is shown in FIG. When the compressor (1) is stopped, at the same time, the on-off valve (42a)
Is opened and the pressure equalizing bypass passage (42) is opened, and the timer 1 and the timer 2 of the control device (6) start counting, and the timer 2 is counting, that is, the compressor (1).
The restart of the compressor (1) is prohibited until 3 minutes have elapsed since the stop of the. Further, the opening of the bypass passage (42) reduces the high-low pressure difference of the compressor (1). After the timer 2 has timed out, the open / close valve (42a) is kept open until the timer 1 times out (until 10 minutes have elapsed since the compressor (1) stopped). The high / low pressure difference of (1) is sufficiently equalized. During this time, the compressor (1) is started immediately when there is a restart request signal. At this time, since the high-low pressure difference of the compressor (1) is sufficiently low, the compressor (1) can be started without being in the high differential pressure state.

10 minutes have passed since the compressor (1) was stopped
When the time goes up, the on-off valve (42a) is closed,
The bypass (42) is closed. Then, when the on-off valve (42a) is once closed in this way, and then when there is a restart request signal for the compressor (1), the on-off valve (42a) is first opened for 10 seconds set by the timer 4. The bypass (42) is opened to open, and then the compressor (1) is started. Therefore, even if the high / low pressure difference of the compressor (1) is slightly increased due to the closing of the opening / closing valve (42a) at the time of the timer 1, the decrease is caused by the opening of the opening / closing valve (42a). As a result, the compressor (1) can be started in a low differential pressure state.

Then, the timer 3 starts counting at the same time when the compressor (1) is started, and the on-off valve (42a) is held open while the timer 3 is counting. After that, the open / close valve (42a) is closed.

Therefore, in this embodiment, the pressure on the discharge side and the pressure on the suction side can be reliably maintained at a uniform pressure when the compressor (1) is started, so that the compressor (1) can be continuously operated without abnormal stop, The reliability can be improved.

When frost is formed in the outdoor heat exchangers (2a), (2b), the outdoor heat exchangers (2a), (2b)
One of them functions as a condenser and the other functions as an evaporator to perform defrost operation. That is, all the indoor electric expansion valves (51), (51), ... Are closed, and the high pressure gas refrigerant is passed through the high pressure gas line (31) to the outdoor heat exchanger (2a or
2b) to be condensed, and the condensed liquid refrigerant is made to flow from the receiver (43) to the other liquid pipe (33b or 33a) and expanded by the outdoor electric expansion valve (25b or 25a), and then the other outdoor side. Evaporate in heat exchanger (2b or 2a), low pressure gas line (32)
Return to compressor (1) via. This operation is alternately performed in both the outdoor heat exchangers (2a) and (2b), and the outdoor heat exchangers (2a) and (2b) are defrosted. According to this defrost operation, the indoor units (B), (B), ...
Cold trough does not occur in and the indoor fan (57) does not have to be stopped.

In this embodiment, the outdoor unit (A) and the indoor unit (B) are connected by three pipes of the high pressure gas line (31), the low pressure gas line (32) and the liquid line (33). You may make it connect with two piping with a line.

Further, three or more outdoor heat exchangers (2a) and (2b) may be provided, and one indoor unit (B) may be provided.

(Effect of the invention) As described above, according to the invention of claim (1),
After the compressor of the air conditioner is stopped, the bypass path is held open even after the restart prohibition time has passed, and when the bypass path is closed, if there is a compressor start signal, the bypass path is opened and then compressed. Since the compressor is started, the high-low pressure difference can be surely reduced when the compressor is restarted, and the compressor can be continuously operated without abnormal stop.

Further, according to the invention of claim (2), the air conditioner,
Since the liquid back is remarkable when the compressor is stopped and a plurality of heat source side heat exchangers are provided, the above effect can be obtained more effectively.

[Brief description of drawings]

FIG. 1 is a diagram showing the configuration of the present invention. FIG. 2 and the following drawings show an embodiment of the present invention, FIG. 2 is a refrigerant circuit diagram showing the overall configuration of an air conditioner, FIG. 3 is a flow chart diagram showing a control procedure in a control device, and FIG. It is a characteristic view which shows the change of high and low pressure accompanying a compressor stop. (X) …… Air conditioner (A) …… Outdoor unit (B) …… Indoor unit (1) …… Compressor (2a), (2b) …… Outdoor heat exchanger (heat source side heat exchanger) (3) …… Refrigerant circuit (5) …… Indoor heat exchanger (use side heat exchanger) (6) …… Control means (21a), (21b) …… Four way switching valve (switching mechanism) (25a ), (25b) …… Outdoor electric expansion valve (heat source side pressure reducing mechanism) (42) …… Bypass path (42a) …… Opening / closing valve (opening / closing means) (51) …… Indoor electric expansion valve (use side pressure reducing mechanism) (T ₁ ) …… First set time (T ₂ ) …… Second set time

Claims (2)

[Claims] 1. A compressor (1), an outdoor heat exchanger (2a),
Refrigerant circuit (3) formed by connecting (2b), pressure reducing mechanism (25a), (25b), (51) and indoor heat exchanger (5) in a closed circuit.
An air conditioner including: a bypass path (42) connecting a discharge side of the compressor (1) to a suction side; an opening / closing means (42a) opening and closing the bypass path (42); ), The start of the compressor (1) is restricted until the first set time (T ₁ ) elapses, and the second set time (T ₂ ) longer than the first set time (T ₁ ) elapses. The opening / closing means (42a) is opened until the second setting time (T ₂ ) elapses, the opening / closing means (42a) is closed, and after the closing operation of the opening / closing means (42a), the compressor (1) is closed. Control unit (6) for controlling the compressor (1) to start after the opening / closing means (42a) is opened for a predetermined time when the start request signal of (1) is input. Pressure equalizer of machine. 2. An air conditioner is connected to a compressor (1) and one end thereof is switchably connected to a discharge side and a suction side of the compressor (1).
Heat source side heat exchangers (2a), (2b) installed in parallel
And a plurality of heat source side pressure reducing mechanisms (25a) and (25b) provided corresponding to the heat source side heat exchangers (2a) and (2b) and capable of controlling the pressure reduction and flow rate of the refrigerant, and one end of which is Compressor (1)
Of the use side heat exchanger (5) switchably connected to the discharge side and the suction side, and the use side heat exchanger (5) provided corresponding to each of the use side heat exchangers (5) with adjustable pressure reduction and flow rate of the refrigerant. A refrigerant circuit (where a side pressure reducing mechanism (51) and a switching mechanism (21a), (21b) for switching the refrigerant flow direction so that the utilization side heat exchanger (5) becomes an evaporator or a condenser ( 3. The pressure equalizing device for an air conditioner according to claim 1, which is an air conditioner provided with 3).