JP2002243240A - Refrigerating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the cost of a refrigerating device by reducing the number of parts used in the device. SOLUTION: The refrigerating device is provided with a heat source-side circuit (14) equipped with an outdoor heat exchanger (23), a user-side circuit (15) equipped with an indoor heat exchanger (31) and connected to the circuit (14), and a refrigerant circuit (11) which performs refrigerating cycle operations by compressing a refrigerant by means of a compressor (21). The device is also provided with stop valves (26 and 27) between the circuits (14) and (15). A discriminating and control section (63) discriminates the opened and closed states of the stop valves (26 and 27) based on the air temperatures respectively detected by means of an indoor temperature sensor (55) before and after the compressor (21) is started, and the temperature detected by means of an indoor heat exchanger temperature sensor (56) after the compressor (21) is started.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a refrigeration apparatus,
In particular, the present invention relates to a countermeasure for opening and closing detection of an on-off valve provided between a heat source side circuit and a use side circuit.

[0002]

2. Description of the Related Art Conventionally, a so-called separate type refrigerating apparatus in which a heat source side unit and a use side unit are connected by a liquid side and a gas side connecting pipes has been known. In this type of refrigeration apparatus, a closing valve is provided at a connection end of a liquid side and a gas side connecting pipes in a heat source side unit, and pressure detecting means for detecting closing of the closing valve is provided at a suction side of a compressor. Have been. In this type of refrigerating apparatus, in order to maintain a clean state in the pipe, the closing valve is closed during installation, and the closing valve is opened after installation is completed. When the refrigerating apparatus is operated, if the shut-off valve is closed, the refrigerant is not sucked into the compressor, and the pressure on the suction side drops abnormally. By detecting, the closing of the closing valve can be detected.

[0003]

However, it is only necessary to detect the closing of the shut-off valve during the first operation after installation. Therefore, the provision of the pressure detecting means to be used only at the time of the first operation causes an increase in the number of parts and causes an increase in cost.

The present invention has been made in view of the above points, and has as its object to reduce costs by reducing the number of parts.

[0005]

According to the present invention, an on-off valve (55, 56) provided for detecting the air temperature and the refrigerant temperature around the use side heat exchanger (31) is used. 26,
The open / closed state of 27) is detected.

Specifically, a first solution is to provide a heat source side circuit (14) having a heat source side heat exchanger (23) and a use side circuit (15) having a use side heat exchanger (31). Is connected, and is provided with a refrigerant circuit (11) that performs a refrigeration cycle operation by compressing the refrigerant with a compressor (21), and the refrigerant circuit (11) includes a heat source circuit (1).
Assuming that a refrigerating system is provided with on-off valves (26, 27) between 4) and the use side circuit (15), the use side heat exchanger (31) after the start of the compressor (21) The on / off state of the on / off valves (26, 27) is detected based on the temperature.

A second solution is to provide a heat source side circuit (14) having a heat source side heat exchanger (23) and a use side heat exchanger (3).
The user side circuit (15) equipped with 1) is connected, and the compressor (2
A refrigerant circuit (11) for performing a refrigeration cycle operation by compressing the refrigerant in 1), wherein the refrigerant circuit (11) includes a heat source circuit (14)
Air temperature detecting means for detecting an air temperature around the use side heat exchanger (31) on the premise of a refrigeration system provided with an on-off valve (26, 27) between the use side circuit (15) and the use side circuit (15) (55), a refrigerant temperature detecting means (56) for detecting a refrigerant temperature of the use side heat exchanger (31), a detected air temperature detected by the air temperature detecting means (55), and a refrigerant temperature detecting means. (56) compares the detected temperature detected after the compressor (21) is started, and determines the open / close state of the on-off valves (26, 27) based on the difference between the detected air temperature and the detected temperature. A determination means (63) is provided.

In a third aspect of the present invention, in the second aspect, the judging means (63) comprises means for detecting the detected air temperature and the detected air temperature detected by the air temperature detecting means (55) before starting the compressor (21). The detected air temperature detected after the compressor (21) is started,
The open / close state of the on-off valves (26, 27) is determined based on the detected temperature detected by the refrigerant temperature detecting means (56) after the compressor (21) is started.

A fourth solution is to provide a heat source side circuit (14) having a heat source side heat exchanger (23) and a use side heat exchanger (3).
The user side circuit (15) equipped with 1) is connected, and the compressor (2
A refrigerant circuit (11) for performing a refrigeration cycle operation by compressing the refrigerant in 1), wherein the refrigerant circuit (11) includes a heat source circuit (14)
Refrigerant temperature detecting means (56) for detecting the refrigerant temperature of the use side heat exchanger (31) on the premise of a refrigerating device provided with on-off valves (26, 27) between the use side circuit (15) and )
And a detected temperature detected by the refrigerant temperature detecting means (56) before the compressor (21) is started and a detected temperature after the compressor (21) is started, and a difference between the two detected temperatures is calculated. Determining means (6) for determining the open / closed state of the on-off valves (26, 27) based on the
3).

According to a fifth aspect of the present invention, in any one of the first to fourth aspects of the present invention, a liquid receiver (28) provided in the refrigerant circuit (11) for storing refrigerant is provided. A degassing pipe (45) connecting the liquid container (28) and the suction side of the compressor (21), an opening / closing mechanism (46) installed on the degassing pipe (45), and the compressor (21) And an initial control means (62) for repeating the opening and closing of the opening and closing mechanism (46) at the initial stage of the drive.

That is, in the first solution, when the compressor (21) is started, the refrigerant circulates in the refrigerant circuit (11), but the refrigerant flows between the heat source side circuit (14) and the utilization side circuit (15). When the open / close valves (26, 27) provided in the first side are closed, the refrigerant does not flow through the use side heat exchanger (31). Therefore, at this time, since the temperature of the use side heat exchanger (31) does not change, the use side heat exchanger (3
The open / close state of the on-off valves (26, 27) can be detected based on the temperature of 1).

In the second solution, the air temperature detecting means (55) detects the air temperature around the use side heat exchanger (31), and the refrigerant temperature detecting means (56) detects the use side heat exchange. The refrigerant temperature of the vessel (31) is detected. And the judgment means (63)
Compares the detected air temperature detected by the air temperature detecting means (55) with the detected temperature detected by the refrigerant temperature detecting means (56) after the compressor (21) is started, and compares the detected air temperature with the detected temperature. The open / close state of the on-off valves (26, 27) is determined based on the temperature difference. That is, before the compressor (21) is started, the detected air temperature and the detected temperature are the same, and the on-off valves (26, 27)
Is open, the differential temperature between the two temperatures increases after the compressor (21) is started. On the other hand, when the compressor is closed, the differential temperature does not increase. 27) The open / closed state can be determined.

[0013] In the third solution means, the second solution
The determination means (63) comprises: a detection air temperature detected by the air temperature detection means (55) before the compressor (21) is started; and a detected air temperature detected after the compressor (21) is started, The open / close state of the on-off valves (26, 27) is determined based on the detected temperature detected by the refrigerant temperature detecting means (56) after the compressor (21) is started. That is, when the on-off valves (26, 27) are open, the detected air temperature changes and the detected temperature changes before and after the compressor (21) starts, and the on-off valves (26, 27) are closed. Since the detected air temperature changes while the detected temperature does not change, the open / close state of the on-off valves (26, 27) can be determined based on the detected air temperature and the detected temperature.

In the fourth solution, the air temperature detecting means (55) detects the air temperature around the use side heat exchanger (31), and the refrigerant temperature detecting means (56) detects the use side heat exchange. The refrigerant temperature of the vessel (31) is detected. And the judgment means (63)
Compares the detected temperature detected before the compressor (21) is started by the refrigerant temperature detecting means (56) with the detected temperature detected after the compressor (21) is started, and based on the difference between the two detected temperatures. The open / close state of the on-off valves (26, 27) is determined. That is, when the on-off valves (26, 27) are closed, the temperature detected by the use side heat exchanger (31) does not change before and after the start of the compressor (21). The open / close state of the on-off valves (26, 27) can be determined.

[0015] In the fifth solution means, the first solution
To the fourth solution, the compressor (2
The opening / closing mechanism (46) repeatedly opens and closes at the beginning of the driving of (1), and the refrigerant in the liquid receiver (28) is intermittently drawn into the suction side of the compressor (21).

[0016]

Therefore, according to the above solution, the temperature of the use side heat exchanger (31) necessary for controlling the operation is utilized,
Since the on-off state of the on-off valves (26, 27) is detected, it is necessary to provide a pressure detecting means for detecting the on-off state of the on-off valves (26, 27) on the suction side of the compressor (21). Disappears. Therefore, the number of parts can be reduced, and the cost can be reduced.

Further, according to the third solution, the air temperature detecting means (55) detects the detected air temperature before and after the compressor (21) is started, and the refrigerant temperature detecting means (56) performs the compression. Since the open / close state of the on-off valves (26, 27) is determined based on the temperature detected after the start of the machine (21), the open / close state of the on-off valves (26, 27) can be accurately determined. it can.

Further, according to the fourth solution, the refrigerant temperature detecting means (56) detects a difference between the detected temperature before the compressor (21) is started and the detected temperature after the compressor is started. Since the open / close state of the on-off valves (26, 27) is determined, the open / close state of the on-off valves (26, 27) can be accurately determined.

Further, according to the fifth solution, since the refrigerant in the liquid receiver (28) is caused to flow to the suction side of the compressor (21), the on-off valves (26, 27) are closed. Even if it is, the pressure on the suction side of the compressor (21) can be prevented from abnormally lowering. Further, since the opening and closing mechanism (46) is repeatedly opened and closed, it is possible to prevent the refrigerant from flowing too much to the compressor (21) and causing liquid back.

[0020]

Embodiments of the present invention will be described below in detail with reference to the drawings.

As shown in FIG. 1, the refrigerating apparatus of this embodiment is a so-called separate type air conditioner in which an outdoor unit (20) as a heat source unit and an indoor unit (30) as a use side unit are connected. The device (10). The outdoor unit (20) and the indoor unit (30) are connected by a liquid side communication pipe (12) and a gas side communication pipe (13).

The outdoor unit (20) is connected to the heat source side circuit (1).
4) equipped. The heat source side circuit (14) is a compressor (21)
And a four-way switching valve (22), an outdoor heat exchanger (23), and an expansion circuit (25). The outdoor unit (20)
It has an outdoor fan (24).

The indoor unit (30) includes a use side circuit (15). The use side circuit (15) includes an indoor heat exchanger (31). The indoor unit (30) includes an indoor fan (32).

The heat source side circuit (14) and the use side circuit (15)
Between the liquid and gas side shut-off valves (2
6,27). Then, the heat source side circuit (1
The refrigerant circuit (11) of the vapor compression refrigeration cycle is formed by connecting 4), the closing valves (26, 27), and the use side circuit (15). That is, the compressor (21) and the four-way switching valve (2
2), outdoor heat exchanger (23), expansion circuit (25), liquid-side shut-off valve (26), indoor heat exchanger (31), and gas-side shut-off valve (2
7) constitute a refrigerant circuit (11).

On the discharge side of the compressor (21), a discharge pipe (4
1), but a suction pipe (42) is provided on the suction side. One end of the discharge pipe (41) is connected to the discharge side of the compressor (21), and the other end is connected to a first port of the four-way switching valve (22). One end of the suction pipe (42) is connected to the suction side of the compressor (21), and the other end is connected to the second port of the four-way switching valve (22). One end of the outdoor heat exchanger (23) is connected to the third port of the four-way switching valve (22) by piping, while the other end is connected to the expansion circuit (25) by piping. The gas side closing valve (27) is connected to the fourth port of the four-way switching valve (22), which is one end of the heat source side circuit (14), by piping, while the gas side communication pipe (13) is connected. Through the use side circuit (1
5) is connected to one end of the indoor heat exchanger (31) which is one end.

The expansion circuit (25) is composed of a direction control circuit (43) composed of a bridge circuit and a one-way passage (44). One end of the direction control circuit (43), which is one end of the heat source side circuit (14), is connected to the liquid-side stop valve (26) by a pipe. The liquid side shut-off valve (26)
It is connected to one end of the indoor heat exchanger (31), which is one end of the use side circuit (15), via the liquid side communication pipe (12). In the one-way passage (44), a liquid receiver (28) that stores the refrigerant and allows the refrigerant to flow out, and a motor-operated valve (29), which is an expansion mechanism whose opening is adjustable downstream, is arranged in series. Are located.

A gas vent pipe (45) is provided above the liquid receiver (28). One end of the degassing pipe (45) is connected to the upper part of the liquid receiver (28), and the other end is connected to the suction pipe (42). The gas vent pipe (45) is provided with an electromagnetic valve (46) as an opening / closing mechanism. An equalizing pipe (47) is connected to the degassing pipe (45). The equalizing tube (47)
One end is connected between the liquid receiver (28) and the solenoid valve (46) in the gas vent pipe (45), and the other end is connected to the discharge pipe (41). The equalizing pipe (47) is provided with a check valve (48) that allows only the flow of the refrigerant from the liquid receiver (28) to the discharge side of the compressor (21).

The compressor (21) is configured as a scroll type compressor (21), and is connected to an inverter circuit. The compressor (21) is configured to adjust the compressor capacity by changing the output frequency of the inverter circuit.

The four-way switching valve (22) has a state in which the first port and the third port communicate with each other, and a state in which the second port and the fourth port communicate with each other (a state shown by a solid line in FIG. 1). The first port and the fourth port communicate with each other, and the second port and the third port communicate with each other (the state shown by the broken line in FIG. 1). The four-way switching valve (22)
The switching reverses the direction of circulation of the refrigerant in the refrigerant circuit (11), and switches between the refrigeration cycle operation and the heat pump cycle operation.

The outdoor heat exchanger (23) is configured as a so-called cross-fin type heat exchanger, and is configured to exchange heat between outdoor air and a refrigerant.

The direction control circuit (43) is configured by connecting two inflow paths (49) and two outflow paths (50) in a bridge shape. Each inflow channel (49) and each outflow channel (5
0) is provided with a check valve (CV). The direction control circuit (43) is connected to the outdoor heat exchanger (2
3) and the indoor heat exchanger (3
It is configured to guide the refrigerant from 1) to the one-way passage (44). The direction control circuit (43) guides the refrigerant flowing out of the liquid receiver (28) to the indoor heat exchanger (31) during the cooling operation, and guides the refrigerant to the outdoor heat exchanger (23) during the heating operation. It is configured to be.

Each of the shut-off valves (26, 27) is maintained until the outdoor unit (20) and the indoor unit (30) are installed.
It is closed for reasons such as maintaining a clean state. The closing valves (26, 27) are normally opened by the installer when performing a trial operation after the installation is completed, and thereafter remain open.

The indoor heat exchanger (31) is configured as a so-called cross-fin type heat exchanger, and is configured to exchange heat between indoor air and a refrigerant.

The discharge pipe (41) of the compressor (21) has a discharge pipe temperature sensor (51) for detecting a discharge pipe temperature which is a refrigerant temperature on the discharge side of the compressor (21), and a high-pressure refrigerant pressure. And a high-pressure protection pressure switch (52) that is turned on when the high-pressure refrigerant pressure becomes higher than a predetermined pressure and outputs a high-pressure protection signal.

An outdoor temperature sensor (53) for detecting an outdoor temperature is disposed at an air inlet of the outdoor unit (20), and a heat transfer tube of the outdoor heat exchanger (23) has a condensing temperature during a cooling operation. In addition, an outdoor heat exchange temperature sensor (54) for detecting the refrigerant temperature of the outdoor heat exchanger (23) that becomes the evaporating temperature during the heating operation is disposed. An indoor temperature sensor (55) for detecting an indoor temperature, which is an air temperature around the indoor heat exchanger (31), is disposed at an air inlet of the indoor unit (30). An indoor heat exchange temperature sensor (56) that detects the refrigerant temperature of the indoor heat exchanger (31), which becomes the evaporating temperature during the cooling operation and becomes the condensing temperature during the heating operation, is disposed in the heat transfer tube. In other words, the indoor temperature sensor (55) constitutes an air temperature detecting means, and the indoor heat exchange temperature sensor (56) constitutes a refrigerant temperature detecting means. The indoor unit (30) has a remote control (33) with an operation switch
Is provided.

The output signals of the various sensors are input to the controller (60). The controller (60) includes an operation control unit (61), an initial operation control unit (62), a determination control unit (63), and an execution control unit (64).

The operation control section (61) is configured to adjust the compressor capacity by changing the output frequency of the inverter circuit based on the air conditioning load. Further, the operation control unit (61) includes an outdoor heat exchange temperature sensor (5).
4) The optimum value of the discharge pipe temperature that gives the optimum refrigeration effect is derived from the condensation temperature and the evaporation temperature detected by the indoor heat exchange temperature sensor (56), and the electric valve is controlled so that the discharge pipe temperature becomes the optimum value. It is configured to adjust the opening degree of (29).

The initial operation control section (62) constitutes initial control means. The initial operation control unit (62) is configured to drive the compressor (21) for a predetermined time and then stop the compressor (21) from the first operation after installation to the fourth operation at maximum. The mode is configured to be executed. In the initial operation mode, the operation is performed by switching to the cooling operation. In the initial operation mode, as shown in FIG. 2, when the operation switch of the remote controller (33) is turned on, the outdoor fan (24) is driven, and for example, five seconds later, the solenoid valve (46) and the electric valve ( 29) opens. In the initial operation mode, after the solenoid valve (46) is opened and, for example, 15 seconds have elapsed, the compressor (21) is started, and the solenoid valve (46) is turned on while the compressor (21) is running. Repeat opening and closing. Solenoid valve (4
6) is repeated, for example, with an opening time of 2 seconds and a closing time of 2 seconds. In the initial operation mode, the compressor (21)
It stops after driving for a predetermined time. This predetermined time is
For example, it is set to 120 seconds. That is, in the initial operation mode, the solenoid valve (46) repeatedly opens and closes at the initial stage of driving the compressor (21).

The judgment control section (63) constitutes judgment means. That is, in the initial operation mode, the determination control unit (63) detects the detected air temperature Tr2 detected by the indoor temperature sensor (55) after the start of the compressor (21) and the indoor heat exchange temperature sensor (56) 21) Detected temperature Tn detected after startup
2 and the difference between the detected air temperature Tr2 and the detected temperature Tn2 (T
r2−Tn2) based on the first differential temperature dTn1,
6, 27). Further, in the initial operation mode, the determination control unit (63) detects the detected air temperature Tr1 detected by the indoor temperature sensor (55) before starting the compressor (21) and the indoor heat exchange temperature sensor (56) Compare the detected temperature Tn2 detected after the start of (21),
The open / close state of the close valves (26, 27) is determined based on a second difference temperature dTn2 that is a difference (Tr1-Tn2) between the detected air temperature Tr1 and the detected temperature Tn2.

That is, before the compressor (21) is started, there is no difference in temperature between the detected air temperature Tr1 and the detected temperature Tn1, but when the closing valves (26, 27) are in the open state, the compressor (21) ), The temperature difference between the detected air temperature Tr2 and the detected temperature Tn2 increases, but when the closing valves (26, 27) are in the closed state, the temperature difference does not increase even after the compressor (21) starts. And the two temperature differences between the detected air temperature Tr and the detected temperature Tr
The open / close state of the closing valve (26, 27) is determined based on dTn1 and dTn2. That is, based on the temperature of the indoor heat exchanger (31) after the start of the compressor (21),
The open / closed state of the closing valve (26, 27) is detected.

As shown in FIG. 3, the judgment control unit (63)
Different judgment conditions are set for each operation in the initial operation mode up to the fourth time.

The initial operation mode is executed from the first operation after the installation to the fourth operation to determine the open / close state. Usually, when the first operation is stopped, the closing valve (26) is used. , 27), the closing of the closing valves (26, 27) is canceled, but the operator does not notice immediately.

Specifically, the determination conditions at the time of the first operation in the initial operation mode include the detected air temperature Tr2 detected by the indoor temperature sensor (55) after startup and the detected air temperature Tr2 detected by the indoor heat exchange temperature sensor (56) after startup. The first differential temperature dTn1, which is the differential temperature from the detected temperature Tn2, exceeds 3 ° C., and the detected air temperature Tr1 detected by the indoor temperature sensor (55) before startup and the indoor heat exchange temperature sensor (56) The setting is made so as to determine whether or not a second temperature difference dTn2 which is a temperature difference from the detected temperature Tn2 detected after the start-up exceeds 3 ° C. The determination control unit (63) is configured to determine that the closing valves (26, 27) are open when this determination condition is satisfied. The reason why the open / close state of the shut-off valves (26, 27) is determined based on both of the two differential temperatures dTn1 and dTn2 is that when the shut-off valves (26, 27) are closed under specific conditions, Regardless, it is to prevent the case where it is determined that the door is opened from occurring.

For example, when the indoor unit (30) stored at a relatively low temperature before installation is installed at a relatively high temperature, the detected air temperature Tr detected by the indoor temperature sensor (55) is reduced. While the temperature rises immediately after the compressor (21) is started, the detected temperature Tn detected by the indoor heat exchange temperature sensor (56) changes slowly, so that the first differential temperature dTn1 increases. In such a case, if the determination is made based only on the first differential temperature dTn1, it is erroneously determined that the closing valve (26, 27) is open even if it is closed. Therefore, the second temperature difference dTn2 is also considered.

The determination conditions at the time of operation in the second initial operation mode are set so as to determine whether the first differential temperature dTn1 exceeds 2 ° C. and the second differential temperature dTn2 exceeds 2 ° C. Have been. The determination control unit (63) is configured to determine that the closing valves (26, 27) are open when this determination condition is satisfied during the second operation. That is,
In the first operation, even if it is not determined that the closing valve (26, 27) is open, the closing valve (26, 27) is opened if the second determination condition is satisfied. Is determined. Compared with the first operation, the judgment conditions are relaxed because the refrigerant does not circulate sufficiently due to the influence of the pipe length and the closing valves (26, 27) are open. This takes into account that the conditions may not be satisfied during the first operation.

The conditions for determination during the third initial operation mode are determined based on whether the first differential temperature dTn1 exceeds 4 ° C. or the second differential temperature dTn2 exceeds 6 ° C. Is set. When this determination condition is satisfied during the third operation, the determination control unit (63) closes the closing valve (26, 27).
Is determined to be open. That is, at the time of the first and second operations, the closing valve (26, 2
Even if 7) is not determined to be open, 3
When the second determination condition is satisfied, the closing valves (26, 27)
It is determined that it is open.

In the determination condition at the time of the third operation, when one of the two conditions is satisfied, for example, when the closing valves (26, 27) are open,
This takes into account that the refrigerant temperature of the indoor heat exchanger (31) has been sufficiently lowered by the operation up to the previous time, and the refrigerant temperature may not be significantly lowered even after the compressor (21) is started. In such cases, shut-off valves (26,27)
Is opened, the second differential temperature dTn2 does not increase,
Since it may be determined that the vehicle is not released, any one of the conditions is satisfied.

The determination conditions at the time of the operation in the fourth initial operation mode are determined based on whether the first temperature difference dTn1 exceeds 2 ° C. or the second temperature difference dTn2 exceeds 4 ° C. Is set. At the time of the fourth operation, when the determination condition is satisfied, the determination control unit (63) closes the closing valve (26, 27).
Is determined to be open. That is, even if it is not determined that the closing valves (26, 27) are open during the third operation, the closing valves (26, 27) are opened when the fourth determination condition is satisfied. Is determined to have been performed.

The execution control unit (64) includes a judgment control unit (6
When 3) determines that the closing valves (26, 27) are open, the initial operation mode is terminated, and in the subsequent operation, execution of the initial operation mode is prohibited. Further, when the operation in which the initial operation mode is executed is performed four times, the execution control unit (64) prohibits the execution of the initial operation mode during the subsequent operation and performs the normal air-conditioning operation. It is configured. In other words, if the operation stops immediately after the operation immediately after installation, the operator immediately determines that there is an abnormality and checks the closing valves (26, 27) etc. By four times, the closing valves (26, 27) have been opened. Therefore, after the fifth operation, normal air-conditioning operation is performed.

-Operating operation- The operating operation of the air conditioner (10) will be described.

After the installation of the air conditioner (10) is completed, when the operator turns on the operation switch of the remote controller (33), the first operation in the initial operation mode is started. In the initial operation mode, as shown in FIG. 4, first, in step ST11, the four-way switching valve (22) is switched to the solid line side in FIG. 1 to perform the cooling operation, and in step ST12 the outdoor fan (24) Drives. Five seconds later, step ST13
At, the solenoid valve (46) and the electric valve (29) are opened. When 15 seconds elapse after the solenoid valve (46) and the motor-operated valve (29) are opened, in step ST14, the compressor (29) starts and the solenoid valve (46) repeatedly opens and closes.
The solenoid valve (46) is repeatedly opened and closed with an opening time of 2 seconds and a closing time of 2 seconds. The opening and closing of the solenoid valve (46) causes the refrigerant in the liquid receiver (28) to intermittently flow to the suction side of the compressor (21). Therefore, even when the shut-off valves (26, 27) are closed, the refrigerant flows to the suction side of the compressor (21). Machine (21) can be protected. Also, when the refrigerant flows intermittently and the liquid refrigerant is stored up to the upper part of the liquid receiver (28), the excess liquid refrigerant is discharged from the compressor (2).
The liquid is not sucked into 1), the liquid back can be prevented, and the compressor (21) can be protected.

Then, the process proceeds to step ST15, in which the determination control section (63) performs the following based on the detected air temperature Tr and the detected temperature Tn.
It is determined whether the determination condition is satisfied. That is, the determination control unit (63) determines the temperature difference between the detected air temperature Tr2 detected by the indoor temperature sensor (55) after the start and the detected temperature Tn2 detected by the indoor heat exchange temperature sensor (56) after the start. Differential temperature of 1 d
Tn1 exceeds 3 ° C., and the detected air temperature Tr1 detected by the indoor temperature sensor (55) before the start-up and the indoor heat exchange temperature sensor (5
6) is the second temperature difference from the detected temperature Tn2 detected after startup.
It is determined whether or not the temperature difference dTn2 exceeds 3 ° C. If this condition is not satisfied, the process proceeds to step ST16, in which it is determined whether or not 120 seconds have elapsed since the compressor (21) was started.
Return to 15. Then, when the above-described determination conditions are satisfied, it is determined that the closing valves (26, 27) are open, and the process proceeds to step ST1.
The determination at 5 is YES, and the routine goes to Step ST17. In step ST17, the execution of the initial operation mode in the next and subsequent operations is prohibited, and the initial operation mode is ended. In this case, the normal air-conditioning operation is continued until the operation switch of the remote control (33) is turned off.

On the other hand, in step ST15, when 120 seconds have elapsed since the start of the compressor (21) without satisfying the above-mentioned determination conditions, the process proceeds from step ST16 to step ST18, where the compressor (21) is stopped. In step ST19, the solenoid valve (4
6) And the motor-operated valve (29) closes and operation stops automatically. Usually, at this time, the operator notices that the shut-off valves (26, 27) have been closed in order to check for abnormalities.
7) is released. After that, the operator again operates the remote control (3
When the operation switch of 3) is turned on, operation in the second initial operation mode is performed. In the second operation, steps ST11 to ST14 are executed in the same manner as described above.
In step ST15, the determination condition is different from that in the first operation. That is, in step ST15, it is determined whether the first differential temperature dTn1 exceeds 2 ° C. and the second differential temperature dTn2 exceeds 2 ° C., which is the determination condition for the second operation. When the closing valves (26, 27) are open, this determination condition is satisfied by 120 seconds after the start of the compressor (21). Then, the process proceeds to step ST17, where the execution of the initial operation mode in the next and subsequent operations is prohibited, and the initial operation mode is ended. Then, a normal air-conditioning operation is performed thereafter.

If the second operation is started without noticing that the closing valves (26, 27) have not been opened, the compressor (21)
After 120 seconds have passed, the determination condition is not satisfied by 120 seconds, the process proceeds from step ST16 to step ST18, and the compressor (21) is stopped. In step ST19, the solenoid valve (46) and the electric valve (29) are stopped. Is closed and driving stops automatically. At this time, the operator notices the closing of the closing valves (26, 27) and opens the closing valves (26, 27) in order to check for abnormalities. Then, when the operator turns on the operation switch again,
The third operation in the initial operation mode is performed, and steps ST11 to ST14 are performed again in the same manner as in the first operation. Then, in step ST15, the open / close state of the closing valves (26, 27) is determined based on the determination condition of the third operation number. That is, whether the first temperature difference dTn1 exceeds 4 ° C.
Alternatively, it is determined whether the second temperature difference dTn2 exceeds 6 ° C. Then, when the closing valves (26, 27) are open, by the time 120 seconds after the start of the compressor (21) elapses,
Since this determination condition is satisfied, as in the first operation, the process proceeds to step ST17, where the execution of the initial operation mode in the next and subsequent operations is prohibited, and the initial operation mode is ended. Then, a normal air-conditioning operation is performed thereafter.

If the third operation is started without noticing that the closing valves (26, 27) have not been opened, the compressor (21)
After 120 seconds have passed, the determination condition is not satisfied by 120 seconds, the process proceeds from step ST16 to step ST18, and the compressor (21) is stopped. In step ST19, the solenoid valve (46) and the electric valve (29) are stopped. Is closed and driving stops automatically. At this time, the operator notices that the shut-off valves (26, 27) are closed, and opens the shut-off valves (26, 27) in order to check for abnormalities. Then, when the operator turns on the operation switch again,
The initial operation mode is executed, the operation in the fourth initial operation mode is performed, and steps ST11 to ST14 are executed again as in the first operation. Then, in step ST15, the open / close state of the closing valves (26, 27) is determined based on the determination condition for the fourth operation. That is, the first differential temperature dTn1 exceeds 2 ° C., or the second differential temperature dTn2 is 4
Judge whether the temperature exceeds ℃. And shut off valve (2
When the compressor (21) is open, the determination condition is satisfied by 120 seconds after the start of the compressor (21), so that the process proceeds to step ST17 as in the first operation. The execution of the initial operation mode in the next and subsequent operations is prohibited, and the initial operation mode is ended. Then, a normal air-conditioning operation is performed thereafter.

If the fourth operation is started without noticing that the closing valves (26, 27) have not been opened, the compressor (21)
After 120 seconds have passed, the determination condition is not satisfied by 120 seconds, the process proceeds from step ST16 to step ST18, and the compressor (21) is stopped. In step ST19, the solenoid valve (46) and the electric valve (29) are stopped. Is closed and driving stops automatically. At this time, since the operation in the initial operation mode has been performed four times, the execution of the initial operation mode is prohibited in the subsequent operation.

According to the present embodiment, the open / close state of the shut-off valves (26, 27) is detected using the temperature of the indoor heat exchanger (31) necessary for controlling the operation. Therefore, it is not necessary to provide pressure detecting means for detecting the open / closed state of the closing valves (26, 27) on the suction side of the compressor (21). Therefore, the number of parts can be reduced, and the cost can be reduced.

The indoor temperature sensor (55) is connected to the compressor (2
The open / close state of the closing valves (26, 27) based on the detected air temperature detected before and after the start of 1) and the detected temperature after the start of the compressor (21) by the indoor heat exchange temperature sensor (56). Is determined, the open / closed state of the closing valve (26, 27) can be accurately determined.

The refrigerant in the receiver (28) is supplied to the compressor (21)
As a result, the pressure on the suction side of the compressor (21) can be prevented from abnormally lowering even when the closing valves (26, 27) are closed. Furthermore, because the solenoid valve (46) was repeatedly opened and closed,
It is possible to prevent the refrigerant from flowing too much into the compressor (21) and causing liquid back.

<Other Embodiments of the Invention> In the above embodiment, the gas vent pipe (45) and the solenoid valve (46) are omitted, and the pressure equalizing pipe (47) is provided with the liquid receiver (28) and the discharge pipe ( 41) may be connected.

In the above embodiment, the initial operation mode is executed by performing the cooling operation. However, the initial operation mode is not necessarily required to be performed by the cooling operation. In this case, the determination control unit (63) may be configured to determine based on the absolute value of the first differential temperature dTn2 and determine based on the absolute value of the second differential temperature dTn2.

In the above-described embodiment, the initial operation control section (62) is configured to execute the initial operation mode up to the fourth operation at the maximum. However, the present invention is not limited to this, and the number of executions may be any number. .

Further, different from the above-described embodiment, the judgment control section (63) includes a detection temperature detected by the indoor heat exchange temperature sensor (56) before the start and a detection temperature detected by the indoor heat exchange temperature sensor (56) after the start. The open / closed state of the closing valve (26, 27) may be determined based on the temperature difference from the temperature.

[Brief description of the drawings]

FIG. 1 is a refrigerant system diagram illustrating an overall configuration of an air-conditioning apparatus according to an embodiment.

FIG. 2 is a characteristic diagram illustrating an operation in an initial operation mode of the air-conditioning apparatus according to the embodiment.

FIG. 3 is a diagram illustrating a table of determination conditions of the air-conditioning apparatus according to the embodiment.

FIG. 4 is a flowchart illustrating a flow of an initial operation mode of the air-conditioning apparatus according to the embodiment.

[Explanation of symbols]

 (11) Refrigerant circuit (14) Heat source side circuit (15) User side circuit (21) Compressor (23) Outdoor heat exchanger (26) Shutoff valve (27) Shutoff valve (28) Receiver (31) Indoor heat Exchanger (45) Gas vent pipe (46) Solenoid valve (55) Indoor temperature sensor (56) Indoor heat exchange temperature sensor (62) Initial operation control unit (63) Judgment control unit

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Kondo Higashi 1304 Kanaokacho, Sakai-shi, Osaka Daikin Industries, Ltd. Sakai Seisakusho Kanaoka Plant F-term (reference) 3L060 CC02 CC04 DD08 EE01

Claims (5)

[Claims] 1. A heat source side circuit (14) having a heat source side heat exchanger (23) and a use side circuit (15) having a use side heat exchanger (31) are connected, and a compressor (21) is provided. A refrigerant circuit (11) for compressing the refrigerant with the refrigerant circuit and performing a refrigeration cycle operation. The refrigerant circuit (11) includes an on-off valve (26, 27) between the heat source circuit (14) and the utilization side circuit (15). ), The use-side heat exchanger (3) after the start of the compressor (21).
A refrigeration system that detects the open / close state of the on-off valves (26, 27) based on the temperature of 1). 2. A heat source side circuit (14) provided with a heat source side heat exchanger (23) and a use side circuit (15) provided with a use side heat exchanger (31) are connected to a compressor (21). A refrigerant circuit (11) for compressing the refrigerant with the refrigerant circuit and performing a refrigeration cycle operation. The refrigerant circuit (11) includes an on-off valve (26, 27) between the heat source circuit (14) and the utilization side circuit (15). ), An air temperature detecting means (55) for detecting an air temperature around the use side heat exchanger (31), and a refrigerant temperature of the use side heat exchanger (31). Comparing the detected air temperature detected by the refrigerant temperature detecting means (56), the detected air temperature detected by the air temperature detecting means (55), and the detected temperature detected by the refrigerant temperature detecting means (56) after starting the compressor (21). And determining means (63) for determining whether the on-off valves (26, 27) are open or closed based on the temperature difference between the detected air temperature and the detected temperature. Refrigeration system, characterized by that. 3. The compressor (2) according to claim 2, wherein the judging means (63) detects the detected air temperature detected by the air temperature detecting means (55) before the compressor (21) is started.
The open / close state of the on-off valves (26, 27) is determined based on the detected air temperature detected after the start-up of 1) and the detected temperature detected after the start-up of the compressor (21) by the refrigerant temperature detecting means (56). A refrigeration apparatus characterized by being configured as described above. 4. A heat source side circuit (14) having a heat source side heat exchanger (23) and a use side circuit (15) having a use side heat exchanger (31) are connected, and a compressor (21) is provided. A refrigerant circuit (11) for compressing the refrigerant with the refrigerant circuit and performing a refrigeration cycle operation. The refrigerant circuit (11) includes an on-off valve (26, 27) between the heat source circuit (14) and the utilization side circuit (15). ), A refrigerant temperature detecting means (56) for detecting a refrigerant temperature of the use side heat exchanger (31), and the refrigerant temperature detecting means (56) starts the compressor (21). Judging means for comparing the detected temperature detected before and the detected temperature detected after the start of the compressor (21) to determine the open / close state of the on-off valves (26, 27) based on the difference between the two detected temperatures; (63)
A refrigeration apparatus comprising: 5. A liquid receiver (2) provided in the refrigerant circuit (11) for storing refrigerant.
8), a gas vent pipe (45) connecting the liquid receiver (28) and the suction side of the compressor (21), an opening / closing mechanism (46) installed in the gas vent pipe (45), A refrigerating apparatus comprising: an initial control unit (62) for repeating opening and closing of the opening and closing mechanism (46) at an early stage of driving the compressor (21).