JPH11142017A - Air conditioner - Google Patents

Abstract

(57) [Summary] [Problem] To prevent frequent switching of a four-way valve, reduce room temperature change at the time of operation switching, and continue long-term stable dehumidification operation even at low outside temperature, and at low outside temperature. To provide an air conditioner that can secure the amount of heat to be heated even in the dehumidifying operation at the time. SOLUTION: In this air conditioner, in particular, a first bypass pipe connected from a discharge side of a compressor 1 to an inlet side of a first condenser 4 by bypassing a four-way valve 2b and having a first electric valve 11 is provided. And a second motor-operated valve 12 which is connected from the discharge side of the compressor 1 to the inlet side of the second condenser 8 by bypassing the four-way valve 2b.
A second bypass pipe 20 having a pressure sensor, a temperature detector 34 installed on the air conditioning load side to detect a load temperature, and an evaporator 7.
And a temperature controller 35 that controls the state of the refrigerant flowing through the second condenser 8 to adjust the load temperature on the air-conditioning load side and switches the refrigerant flow path of the four-way valve 2b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner that mainly performs, for example, a dehumidifying operation and a drying operation, and more particularly to a refrigerant control of an air conditioner.

[0002]

2. Description of the Related Art A conventional air conditioner of this type is shown in FIG. In the conventional machine shown in FIG.
The compressed refrigerant discharged from the valve is connected to the four-way valve 2
b, and is sent to the first condenser 4. In the first condenser 4, the refrigerant is cooled and condensed by the air sent by the first blower 3 to become a liquid refrigerant. Thereafter, the liquid refrigerant is depressurized by the expansion device 5 and sent to the evaporator 7, and after being superheated and evaporated by the air sent by the second blower 6,
Return to the compressor 1. At this time, the air sent by the second blower 6 is cooled by the evaporator 7 and then sent indoors to perform a cooling operation. Note that the first blower 3 and the first condenser 4 are usually installed outside the room. Also,
The switching pressure transmission pipe 16a is connected between the four-way valve 2b and the suction side of the compressor 1. This switching pressure transmission pipe 1
Reference numeral 6a denotes a capillary-like pipe through which the pressure is conducted but the flow rate of the refrigerant is very small.

In the dehumidifying operation of the conventional apparatus shown in FIG. 7, the refrigerant flow path of the four-way valve 2b is switched to the second condenser 8 in advance. Then, the compressed refrigerant discharged from the compressor 1 is sent to the second condenser 8 through the four-way valve 2b as shown by a broken line in the figure. Here, the refrigerant is cooled and condensed by the air sent from the second blower 6 to become a liquid refrigerant. Thereafter, the liquid refrigerant is sent to the evaporator 7 after being decompressed by the expansion device 5. In the evaporator 7, the refrigerant is superheated and evaporated by the air sent from the second blower 6, and then evaporated.
Return to the compressor 1. At this time, the air sent by the second blower 6 is cooled by the evaporator 7, and the cooled air is further heated by the second condenser 8, thereby performing a dehumidifying operation.

[0004] FIG. 8 shows another conventional machine described in Japanese Patent Publication No. 7-35917. During the cooling operation by the conventional machine of FIG. 8, the compressed refrigerant discharged from the compressor 1 is sent to the first condenser 4 as shown by a solid line in the figure. Here, the refrigerant is cooled and condensed by the air sent from the first blower 3 to become a liquid refrigerant. Thereafter, the liquid refrigerant passes through the motor-operated valve 9 via the check valve 17, and is sent to the evaporator 7 after being depressurized by the expansion device 5. In the evaporator 7, the refrigerant is superheated and evaporated by the air sent from the second blower 6, and then returns to the compressor 1. At this time, the air sent by the second blower 6 is cooled by the evaporator 7 to perform a cooling operation. Note that the motor-operated valve 10 is closed in advance.

[0005] In addition, during the dehumidifying operation of the conventional machine shown in Fig. 8, the compressed refrigerant discharged from the compressor 1 is sent to the first condenser 4 as in the cooling operation. In addition, the first blower 3
Are stopped, and the electric valve 9 is closed in advance. Therefore, the compressed refrigerant is supplied to the electric valve 10 as indicated by the broken line in the figure.
To the second condenser 8. Here, the refrigerant is cooled by the air sent by the second blower 6 and condensed to become a liquid refrigerant. The liquid refrigerant from the second condenser 8 is sent to the evaporator 7 after being depressurized by the expansion device 5 via the check valve 18. In the evaporator 7, the refrigerant is superheated and evaporated by the air sent from the second blower 6, and then returns to the compressor 1. At this time, the air sent by the second blower 6 is cooled, and the cooled air is further heated by the second condenser 8, thereby performing a dehumidifying operation.

[0006]

The conventional air conditioner having a cooling function and a dehumidifying function has the following problems because it is configured as described above. That is, in the conventional machine shown in FIG. 7, when the dehumidifying operation is performed at a low outside air temperature in winter or the like, the refrigerant flow path by the four-way valve 2b is switched to the second condenser 8 side as shown by a broken line in the figure. However, the refrigerant may leak from the four-way valve 2b to the first condenser 4 which should be closed. In that case, the leaked refrigerant accumulates as a liquid refrigerant in the first condenser 4 exposed to the low-temperature outside air. For this reason, since the refrigerant is unevenly distributed in the refrigerant circuit and the amount of the refrigerant that can be used for the dehumidifying operation gradually decreases, the normal operation may not be performed.

[0007] Further, the refrigerant that has flowed back little by little through the switching pressure transmission pipe 16a may accumulate as liquid refrigerant in the first condenser 4 exposed to low-temperature outside air.
Also in this case, the amount of refrigerant that can be used for the dehumidifying operation gradually decreases in the refrigerant circuit, and normal operation cannot be performed.

When the refrigerant flow path of the four-way valve 2b is switched, the liquid refrigerant flows from the unused condenser of the first condenser 4 and the second condenser 8 through the switching pressure transmission pipe 16a. 1 may return to the suction side, which may cause a failure of the compressor 1 and may temporarily reduce the amount of refrigerant passing through the evaporator 7, thereby lowering the heat exchange capacity.

The temperature of the air blown into the room during the dehumidifying operation is determined by the rise of the enthalpy of the blown air corresponding to the input of the motor (not shown) of the compressor 1 and the latent heat of condensation of water condensed in the evaporator 7. As a result, the temperature of the air greatly increases as compared with the suction air temperature, so that the room temperature fluctuation during the cooling operation and the dehumidifying operation increases. Therefore, when trying to control the room temperature to a predetermined target temperature, the four-way valve 2b must be frequently switched, which causes a failure of the four-way valve 2b.

When the temperature of the air supplied to the first condenser 4 or the second condenser 8 rises or the amount of air decreases, the pressure of the compressed refrigerant rises, and the refrigeration cycle equipment becomes inoperable. There is a risk of failure. Therefore, in order not to cause a failure, it is necessary to stop the operation of the compressor 1 when the refrigerant pressure on the compressor discharge side is high, and the reliability of the device is reduced.

On the other hand, in the conventional machine shown in FIG. 8, even when the dehumidifying operation is performed at a low outside air temperature in winter or the like, the amount of the natural heat radiation due to the low outside air temperature is small because the refrigerant always flows through the first condenser 4. In some cases, the amount of heat to be heated by the second condenser 8 when performing the dehumidifying operation was insufficient.

The present invention has been made in order to solve the above-mentioned problems, and it is possible to prevent frequent switching of a four-way valve, reduce a change in room temperature at the time of operation switching, and furthermore, even at a low outside air temperature. It is an object of the present invention to provide an air conditioner that can maintain a stable dehumidifying operation for a long time and can secure a sufficient amount of heat to be heated even in a dehumidifying operation at a low outside air temperature.

[0013]

According to a first aspect of the present invention, there is provided an air conditioner comprising: a compressor for compressing a refrigerant gas; and a refrigerant flow path from the compressor. A four-way valve, a first condenser blown by a first blower, a throttling device, and an evaporator blown by a second blower are sequentially connected in an annular pipe to form a refrigeration cycle, And a second condenser blown by a second blower at a position downstream of the air path of the evaporator and connected to the first condenser in parallel between the first condenser outlet side and
An air conditioner including a suction-side pipe that communicates a four-way valve with a compressor suction side, wherein air from a second blower is air-conditioned by an evaporator and a second condenser and then sent to an air-conditioning load side. In the first bypass pipe having a first motor-operated valve connected by bypassing the four-way valve from the compressor discharge side to the first condenser inlet side, and from the compressor discharge side to the second condenser inlet side A second bypass pipe having a second motor-operated valve connected by bypassing the four-way valve, a temperature detector installed on the air-conditioning load side to detect a load temperature, and an evaporator and a second condenser. A temperature controller for controlling the state of the refrigerant to adjust the load temperature on the air conditioning load side is provided,
The temperature controller sets the refrigerant flow path of the four-way valve to a first position when the load temperature detected by the temperature detector exceeds the upper limit or falls below the lower limit of the target temperature zone preset in the temperature controller. Switch to either the condenser side or the second condenser side, and when the load temperature falls within the target temperature zone beyond its upper or lower limit, both the first motor-operated valve and the second motor-operated valve are turned on. It is configured to be opened to send the refrigerant from the compressor in parallel with both the first condenser and the second condenser.

The second aspect of the present invention provides the first aspect.
In the configuration described in the paragraph, the temperature controller, when the load temperature detected by the temperature detector exceeds the upper limit of the target temperature zone preset in this temperature controller, the refrigerant flow path of the four-way valve. Switch to the first condenser side and close the first motor-operated valve and the second motor-operated valve, and when the load temperature is below the upper limit of the target temperature zone, change the refrigerant flow path of the four-way valve to the first condenser side. When the load temperature falls below the lower limit of the target temperature zone, the refrigerant passage of the four-way valve is switched to the second condenser side, and the first motorized valve and the second motorized valve are opened. When the load temperature exceeds the lower limit of the target temperature zone, the control valve is configured to open the first motor-operated valve while maintaining the refrigerant flow path of the four-way valve on the second condenser side. Things.

According to a third aspect of the present invention, in the configuration according to the first or second aspect, the pressure is conducted between the four-way valve and the compressor suction side instead of the suction side pipe. However, the refrigerant is connected by a capillary-shaped switching pressure transmission pipe having a very small flow rate of the refrigerant.

Further, the invention according to claim 4 is based on claim 1.
Item 3. In the configuration according to any one of Items 3 to 3, a third bypass communicating from the second condenser inlet to the first condenser inlet instead of the first bypass pipe and the second bypass pipe. A pipe and a fourth bypass pipe communicating from the first condenser inlet to the second condenser inlet are provided, and a third motor-operated valve is provided in the third bypass pipe, and a fourth bypass is provided. The pipe is provided with a second electric valve.

The invention of claim 5 is the first invention of claim 1.
In the configuration according to any one of Items 3 to 3, the first motor-operated valve, the first bypass pipe, the second motor-operated valve, and the second bypass pipe are replaced with a first condenser inlet side and a second condenser pipe. A fifth bypass pipe communicating with the second condenser inlet side is provided,
A third motor-operated valve capable of bidirectional refrigerant flow is provided in a fifth bypass pipe.

According to a sixth aspect of the present invention, in the configuration according to any one of the first to fifth aspects, a pressure detector for detecting a refrigerant pressure is provided on a discharge side of the compressor. When the refrigerant pressure detected by the device is equal to or higher than a preset pressure, both the first motor-operated valve and the second motor-operated valve, or the third motor-operated valve is opened to open the first condenser and the second motor-operated valve. The control system is configured to send the refrigerant from the compressor in parallel with both of the two condensers.

Further, the invention of claim 7 is the first invention.
7. In the configuration according to any one of Items 6 to 6, when the refrigerant is selectively flowing to either the first condenser or the second condenser, the first Controlled to open the third motor-operated valve and / or open the third motor-operated valve to periodically send refrigerant from the compressor in parallel with both the first condenser and the second condenser. It was done.

[0020] The invention of claim 8 provides the invention of claim 1.
Item 7. In the configuration according to any one of Items 7 to 7, a first check valve for circulating the refrigerant only toward the first condenser is provided between the four-way valve and the first condenser, And a second check valve for circulating the refrigerant only toward the second condenser between the first condenser and the second condenser.

According to a ninth aspect of the present invention, in the configuration according to any one of the first, second, fourth, and eighth aspects, the suction side pipe is provided only on the compressor suction side. A third check valve for circulating a refrigerant is provided.

In a tenth aspect of the present invention, in the configuration according to the third aspect, a third check valve for circulating the refrigerant only to the compressor suction side is provided in the switching pressure transmission pipe. It is.

[0023]

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

Embodiment 1 of the Invention FIG. 1 is a refrigerant system diagram of an air conditioner according to Embodiment 1 of the present invention, FIG. 2 is an electric circuit diagram of the air conditioner according to Embodiment 1, and FIG. 3 is an operation of the air conditioner according to Embodiment 1. Flow chart, FIG.
FIG. 3 is an explanatory diagram illustrating an operation state of the four-way valve according to the first embodiment.

In the air conditioner according to this embodiment shown in FIG. 1, a compressor 1 for compressing a refrigerant gas, a four-way valve 2b for selectively switching a refrigerant flow path from the compressor 1, a first blower A first condenser 4 blown by 3, a throttling device 5 for reducing the pressure of the refrigerant, and an evaporator 7 blown by a second blower 6 are sequentially connected in a pipe-like manner to form a refrigerant circuit of a refrigeration cycle. It is configured. Then, between the four-way valve 2b and the outlet side of the first condenser 4, a second condenser 8 blown by the second blower 6 at a position downstream of the evaporator 7 in the air path is provided.
The piping is connected in parallel with the first condenser 4. In addition, the four-way valve 2b and the suction side of the compressor 1 are communicated with each other through a suction-side pipe 16b having a pipe inner diameter through which a refrigerant can flow normally.

In this air conditioner, the air blown from the second blower 6 is air-conditioned by the evaporator 7 and the second condenser 8, and then sent to the air conditioning load (for example, room air; the same applies hereinafter). It has become. Further, for example, during operation, the second blower 6 blows a series of air from the evaporator 7 to the second condenser 8, and the compressed refrigerant is selectively sent to the first condenser 4 from the four-way valve 2b. In this case, the first blower 3 also blows air to the first condenser 4.

In the refrigerant circuit between the four-way valve 2b and the first condenser 4, a first check valve 14 is provided in such a direction that the refrigerant flows only to the first condenser 4. . Also,
In the refrigerant circuit between the four-way valve 2b and the second condenser 8, a second check valve 15 is provided in a direction in which the refrigerant flows only to the second condenser 8. Due to the presence of the first check valve 14 and the second check valve 15, when the compressed refrigerant is sent from the four-way valve 2b to the first condenser 4, the refrigerant is accumulated in the second condenser 8. The liquid refrigerant is prevented from flowing from the four-way valve 2b to the suction side of the compressor 1, and accumulated in the first condenser 4 when the compressed refrigerant is sent from the four-way valve 2b to the second condenser 8. The liquid refrigerant is prevented from flowing from the four-way valve 2b to the suction side of the compressor 1. With these configurations, the four-way valve 2
The liquid back at the time of b switching is prevented, so that the capacity of the evaporator 7 is sufficiently ensured.

A third check valve 13 is provided in the suction side pipe 16b in such a manner that the refrigerant flows only to the suction side of the compressor 1. The presence of the third check valve 13 prevents the refrigerant sucked from the evaporator 7 into the compressor 1 from flowing toward the four-way valve 2b. On the outlet side of the first condenser 4, a fourth check valve 17 is provided so as to allow the refrigerant to flow only to the throttle device 5. A fifth check valve 18 is provided in a direction in which the gas flows.

In this air conditioner, a first bypass pipe having a first motor-operated valve 11 is connected from the discharge side of the compressor 1 to the first condenser 4 by bypassing the four-way valve 2b. 19 and the second condenser 8 from the discharge side of the compressor 1
A second bypass pipe 20 having a second motor-operated valve 12 connected to the inlet side by bypassing the four-way valve 2b and a load temperature (for example, room temperature, etc .; the same applies hereinafter) installed on the air-conditioning load side. A temperature detector 34 for detecting, and a pressure detector 33 provided on a discharge side pipe of the compressor 1 for detecting a refrigerant pressure.
And the first condenser 4, the second condenser 8, and the evaporator 7
And a temperature controller 35 for controlling the state of the refrigerant flowing therethrough to adjust the load temperature.

Next, an electric circuit of the air conditioner will be described mainly with reference to FIG. In FIG. 2, MC is a compressor motor, MF1 and MF2 are a motor for the first blower 3 and a motor for the second blower 6, respectively. 52C is an electromagnetic contactor for the compressor motor MC, and 52C1 is its a contact. 52F1 and 52F2 are electromagnetic contactors for the first blower motor MF1 and electromagnetic contactors for the second blower motor MF2, respectively.
F21 is their a contact. 21R1 is a coil of the first motor-operated valve 11, 21R2 is a coil of the second motor-operated valve 12, and 21R4 is a coil of the four-way valve 2b. X1, X
2, X3 and X4 are relays, respectively. X11, X1
2, X13 are a contact, b contact, and a of the relay X1, respectively.
X21 and X22 are b of relay X2, respectively.
X31 is a contact of the relay X3, X4
1 is an a contact of the relay X4. 23HS is a contact of the humidity controller 36 and forms a parallel circuit with the a contact of the relay X1. This parallel circuit is in series with the electromagnetic contactor 52C for the compressor motor MC. 23RH is an upper limit contact of the target temperature zone of the temperature controller 35, and 23RL is a lower limit contact of the target temperature zone of the temperature controller 35. T is a timed operation timed return timer, and T1 is its contact.
Reference numeral 63H denotes a high-pressure switch that turns on its contact when the refrigerant pressure on the compressor 1 discharge side detected by the pressure detector 33 exceeds a set value, and excites the relay X3. SW is an operation switch.

Next, the operation of the air conditioner will be described mainly with reference to FIG. First, when the operation switch SW is turned on, the electromagnetic contactor 5 for the second blower motor MF2 is turned on.
When 2F2 is excited and its a contact 52F21 is turned on, power is supplied to the second blower motor MF1 to start blowing. At this time, if either the contact 23HS of the humidity controller 36 or the upper limit contact 23RH of the target temperature zone of the temperature controller 35 is ON, the electromagnetic contactor 52C for the compressor motor MC is excited, and a contact 5
When 2C1 is turned on, power is supplied to the compressor motor MC, and the refrigerant compression operation is started.

At this time, if the upper limit contact 23RH of the target temperature zone of the temperature controller 35 is ON, regardless of whether the contact 23HS of the humidity controller 36 is ON or OFF, the relay X1 is excited and its b contact X12 Operation of the first motor-operated valve 1
The first coil 21R1 and the second motor-operated valve 12 coil 2
1R2 is turned off. As a result, the a contact X13 is turned on, so that the coil 21R4 of the four-way valve 2b is turned on. Thereby, the flow path of the compressed refrigerant flowing into the four-way valve 2b to the first condenser 4 side is set. At this time,
Since the relay X4 is excited, the relay X4 is self-held by the a contact X41.

By the above operation, the compressed refrigerant is radiated by the first condenser 4 and condensed to become a liquid refrigerant, decompressed by the expansion device 5 and further evaporated by absorbing heat from the cooling load in the evaporator 7. Return to the compressor 1 again. At this time, the liquid refrigerant in the second condenser 8 does not return to the suction side of the compressor 1 by the second check valve 15 but stays in the second condenser 8. When this is viewed from the load side, the air supplied from the second blower 6 is supplied to the load side after being deprived of heat by the evaporator 7, so that the cooling operation is performed.

Next, the case where the load is sufficiently cooled and the upper limit contact 23RH of the target temperature zone is turned off will be described. The relay X1 is de-energized and the b contact X12 is closed, and the coil 21R1 of the first motor-operated valve 11 and the coil 21R2 of the second motor-operated valve 12 are energized and turned on. Similarly, the a contact X13 is turned off, but the coil 21R4 of the four-way valve 2b is connected to the first condenser 4 because the relay X4 is self-held by the a contact X41.
It is held with the flow path set on the side.

With the above operation, the compressed refrigerant is supplied to the four-way valve 2b.
And from the first motor-operated valve 11 to the first condenser 4, further from the second motor-operated valve 12 to the second condenser 8, and the heat is condensed and released in the respective condensers 4, 8. And becomes a liquid refrigerant. The liquid refrigerant is decompressed by the expansion device 5, evaporates by absorbing heat from the load in the evaporator 7, and then re-compressed by the compressor 1.
Return to

When this is viewed from the load side, the second blower 6
After the air supplied by the evaporator 7 is deprived of heat by the evaporator 7, the air is supplied again by the second condenser 8. At this time, the temperature of the supply air blown to the load side by the second blower 6 is higher than the cooling operation described above, and in addition, the compressed refrigerant is also supplied to the first condenser 4 in parallel. Since the heat is dissipated, it becomes lower than the dehumidifying operation described later. That is, the intermediate operation is an intermediate state between the cooling operation and the dehumidifying operation.

At this time, the contact 23 of the humidity controller 36
When the HS is turned off, the electromagnetic contactor 52C for the compressor motor MC is de-energized, and its a contact 52C1 is turned off.
F. As a result, the compressor motor MC stops, and the air-blowing operation starts. Then, when the humidity rises again and the contact 23HS of the humidity controller 36 is turned on, the electromagnetic contactor 52C for the compressor motor MC is excited, and the intermediate operation is started. Also at this time, since the relay X4 is self-held by the a contact X41 of the coil 21R4, the four-way valve 2
b is maintained in the state where the flow path is set on the first condenser 4 side.

When the upper limit contact 23RH of the target temperature zone of the temperature controller 35 is turned on again, the cooling operation starts again. Here, the relay X1 is excited again, and the coil 21R1 of the first motor-operated valve 11 is actuated by the operation of the b-contact X12.
And, the coil 21R2 of the second motor-operated valve 12 is turned off. Also at this time, since the relay X4 of the coil 21R4 of the four-way valve 2b is self-held by the a contact X41, the four-way valve 2b is held with the flow path set on the first condenser 4 side.

Next, the operation when the lower limit contact 23RL of the target temperature zone of the temperature controller 35 is turned on in the intermediate operation and the dehumidifying operation is performed will be described. At this time, if the contact 23HS of the humidity controller 36 is OFF, the electromagnetic contactor 52C for the compressor motor MC is not excited. Then, the a contact 52C1 is turned off, and the compressor motor MC is stopped to perform the air blowing operation. Then, when the contact 23HS of the humidity controller 36 is turned on again, the compressed refrigerant is supplied from the compressor 1 to start. First, the relay X2 is excited and its b contact X22 is opened, and the relay X4 and its a
The self-holding of the contact X41 is released. Accordingly, the coil 21R4 of the four-way valve 2b is turned off, and the flow path of the compressed refrigerant entering the four-way valve 2b to the second condenser 8 is set.
Then, the relay X2 is excited, and the coil 21R1 of the first motor-operated valve 11 and the coil 21R2 of the second motor-operated valve 12 are turned off by the operation of the b-contact X21. Then, all the compressed refrigerant starts to be supplied to the second condenser 8 side.

By the above operation, the compressed refrigerant radiates heat in the second condenser 8 and is condensed to become a liquid refrigerant. The liquid refrigerant is decompressed by the expansion device 5, evaporates by absorbing heat from the load side in the evaporator 7, and returns to the compressor 1 again. At this time, the liquid refrigerant in the first condenser 4 stays in the first condenser 4 without returning to the suction side of the compressor 1 due to the presence of the first check valve 14. When viewed from the load side, the air from the second blower 6 is deprived of heat by the evaporator 7, subsequently heated by the second condenser 8, and then supplied again to the load side to dehumidify. Driving.

Next, the case where the load is sufficiently heated and the lower limit contact 23RL of the target temperature zone is turned off will be described. First, the relay X2 is de-energized and its b contact X2
1 is closed, the coil 21R1 of the first motor-operated valve 11 and the coil 21R2 of the second motor-operated valve 12 are energized and turned on.
Becomes Similarly, the contact X22 is closed, but the relay X4 remains de-energized, so that the four-way valve 2b is connected to the second condenser 8
It is held with the flow path set on the side.

By the above operation, the compressed refrigerant is supplied in parallel from the first motor-operated valve 11 to the first condenser 4 and further from the four-way valve 2b and the second motor-operated valve 12 to the second condenser 8. The heat is supplied and radiated and condensed by the respective condensers 4 and 8 to become a liquid refrigerant. The liquid refrigerant is decompressed by the expansion device 5, evaporates by absorbing heat from the load side in the evaporator 7, and returns to the compressor 1 again. When this is viewed from the load side, the intermediate operation described above is performed.

At this time, the contact 23HS of the humidity controller 36
Is OFF, the electromagnetic contactor 5 for the compressor motor MC
2C is de-energized and its a contact 52C1 is turned off. As a result, the compressor motor MC stops, and the air-blowing operation starts. Then, the humidity rises again and the humidity controller 36
Is turned on, the electromagnetic contactor 52C for the compressor motor MC is excited, and the intermediate operation is started. Also at this time, the coil 21R4 of the four-way valve 2b has the relay X4 held by its a-contact X41.
b is maintained in the state where the flow path is set on the first condenser 4 side.

When the lower limit contact 23RL of the target temperature zone of the temperature controller 35 is turned ON, the operation is switched from the intermediate operation to the dehumidification operation again. Here, the relay X2 is again excited, and the coil 21R1 of the first motor-operated valve 11 and the coil 21R2 of the second motor-operated valve 12 are turned on by the b contact X21.
FF is performed. Also at this time, the coil 21R4 of the four-way valve 2b
Since the relay X4 is de-energized, the four-way valve 2b is held with the flow path set on the second condenser 8 side.

On the other hand, during the cooling operation, the pressure detector 3
If the refrigerant pressure on the discharge side of the compressor 1 detected by Step 3 is equal to or higher than the pressure set by the high-pressure switch 63H, the relay X3 is excited to close its a-contact X31, whereby the compressed refrigerant is supplied to the four-way valve 2b and the first The pressure is set in parallel with the electric valve 11 to the first condenser 4, and further from the second electric valve 12 to the second condenser 8, in order to radiate heat in the respective condensers 4 and 8. It can be operated under pressure.

On the other hand, even when the detected refrigerant pressure is equal to or higher than the pressure set by the high-pressure switch 63H during the dehumidifying operation, the compressed refrigerant is supplied to the first electric motor by energizing the relay X3 and closing the contact X31. To be supplied in parallel from the valve 11 to the first condenser 4, further from the four-way valve 2 b and the second motor-operated valve 12 to the second condenser 8, and to radiate heat in the respective condensers 4 and 8, The operation can be performed with the pressure reduced below the set pressure.

Further, during the dehumidifying operation, even when the ambient temperature of the first condenser 4 drops extremely and the pressure in the first condenser 4 becomes lower than the suction pressure of the compressor 1, the four-way valve 2
b, since the refrigerant on the suction side of the compressor 1 does not flow to the first condenser 4 due to the presence of the third check valve 13, an amount of refrigerant that can be used for the dehumidifying operation can be secured in the refrigerant circuit. , Normal operation can be continued.

Similarly to the above, during the dehumidifying operation, the ambient temperature of the first condenser 4 is extremely lowered, and the pressure in the first condenser 4 becomes lower than the suction pressure of the compressor 1, Even if the refrigerant gradually leaks from the four-way valve 2b and the third check valve 13 to the first condenser 4, the time limit operation timer T shown in FIG. And the second condenser 8 are supplied with the compressed refrigerant in parallel. As a result, an amount of refrigerant that can be used for the dehumidifying operation can be secured in the refrigerant circuit, and normal operation can be continued.

Here, the functions of the temperature controller 35 will be summarized and summarized below. That is, the temperature controller 3
5 is a four-way valve 2b when the load temperature detected by the temperature detector 34 exceeds the upper limit of the target temperature zone preset in the temperature controller 35 or falls below the lower limit.
Has a control function of switching the refrigerant flow path to either the first condenser 4 side or the second condenser 8 side. On the other hand, when the load temperature falls within the target temperature zone beyond its upper limit or lower limit, the first electric valve 11 and the second electric valve 12
Are opened and the refrigerant from the compressor 1 is sent through the first bypass pipe 19 and the second bypass pipe 20 to both the first condenser 4 and the second condenser 8 in parallel.

The temperature controller 35 includes a temperature detector 34.
If the load temperature detected by the above exceeds the upper limit of the target temperature zone preset in the temperature controller 35,
It has a control function of switching the refrigerant flow path of the four-way valve 2b to the first condenser 4 side and closing both the first electric valve 11 and the second electric valve 12. When the load temperature falls below the upper limit of the target temperature zone, the second motor-operated valve 12 is opened while the refrigerant flow path of the four-way valve 2b is held on the first condenser 4 side. When the load temperature falls below the lower limit of the target temperature zone, the refrigerant passage of the four-way valve 2b is switched to the second condenser 8 and the first electric valve 1
The first and second motor-operated valves 12 are both closed. Further, when the load temperature exceeds the lower limit of the target temperature zone, the first motor-operated valve 11 is opened while the refrigerant flow path of the four-way valve 2b is held on the second condenser 8 side.

The temperature controller 35 includes a pressure detector 33
If the detected refrigerant pressure is equal to or higher than a preset pressure, both the first motor-operated valve 11 and the second motor-operated valve 12 are opened to open the first condenser 4 and the second condenser 8 also has a control function of sending the refrigerant from the compressor 1 in parallel. In addition, instead of the first motor-operated valve 11 and the second motor-operated valve 12, a third motor-operated valve 11a (FIG.
When the refrigerant pressure is equal to or higher than the set pressure, the third motor-operated valve 11a is opened and the control function of sending the refrigerant in parallel to both the first condenser 4 and the second condenser 8 is performed by controlling the temperature. It is possible for the controller 35 to have it.

The temperature controller 35 is connected to the first condenser 4
Alternatively, when the refrigerant is selectively flowing toward any one of the second condensers 8, the first motor-operated valve 11 and the second motor-operated valve 12 are both opened at predetermined time intervals, and the first motor-operated valve 12 is opened. Has a control function of periodically sending the refrigerant from the compressor 1 in parallel with both the condenser 4 and the second condenser 8. When a third motor-operated valve 11a, which will be described later, is provided instead of the first motor-operated valve 11 and the second motor-operated valve 12, the third motor-operated valve 11a is opened at predetermined time intervals to perform the first condensation. The temperature controller 35 may have a function of controlling the refrigerant from the compressor to be periodically sent to both the condenser 4 and the second condenser 8 in parallel.

Embodiment 2 of the Invention FIG. 5 is a refrigerant circuit system diagram of an air conditioner according to Embodiment 2 of the present invention. As shown in FIG. 5, in the air conditioner of this embodiment, the first bypass pipe 19 and the second bypass pipe 20 in the first embodiment described above are omitted. Instead of these, a third bypass pipe 37 communicating from the inlet side of the second condenser 8 to the inlet side of the first condenser 4 and a first condenser 4
A fourth bypass pipe 38 communicating from the inlet side to the second condenser 8 inlet side is provided. The first motor-operated valve 11 is provided in the third bypass pipe 37. The second motor-operated valve 20 is provided in the fourth bypass pipe 38.

Therefore, if the detected load temperature exceeds the upper limit of the target temperature zone of the temperature controller 35, the four-way valve 2b
Is switched to the first condenser 4 side. on the other hand,
If the load temperature falls below the lower limit of the target temperature zone, the four-way valve 2
The refrigerant passage b is switched to the second condenser 8 side. When the detected load temperature falls within the target temperature zone of the temperature controller 35, both the first motor-operated valve 11 and the second motor-operated valve 12 are opened. Thereby, the compressed refrigerant is sent to both the first condenser 4 and the second condenser 8 in parallel. Subsequent operations are the same as those of the first embodiment of the invention described above, and a description thereof will be omitted.

Third Embodiment of the Invention FIG. 6 is a refrigerant circuit system diagram of an air conditioner according to Embodiment 3 of the present invention. As shown in FIG. 6, in the air conditioner of this embodiment, the first electric valve 11, the first bypass pipe 19, the second electric valve 12, and the second bypass pipe in the first embodiment described above. 20 has been omitted. Instead of these, a fifth bypass pipe 39 communicating between the first condenser 4 inlet and the second condenser 8 inlet, and a fifth bypass pipe 39 provided in the fifth bypass pipe 39. A third motor-operated valve 11a is provided so that refrigerant can flow in both directions.

Therefore, if the detected load temperature exceeds the upper limit of the target temperature zone of the temperature controller 35, the four-way valve 2b
Is switched to the first condenser 4 side. on the other hand,
When the temperature falls below the lower limit of the target temperature zone, the refrigerant flow path of the four-way valve 2b is switched to the second condenser 8 side. Further, when the load temperature on the load side falls within the target temperature zone of the temperature controller 35, the electric valve 11a is opened. Thereby, the compressed refrigerant is sent to both the first condenser 4 and the second condenser 8 in parallel. Subsequent operations are the same as those in the first embodiment of the present invention, and a description thereof will not be repeated.

In addition, instead of the suction side pipe 16b in each of the above-described embodiments, a switching pressure transmission pipe employed in the conventional machine (see FIG. 7) is provided between the suction side of the compressor 1 and the four-way valve 2b. 16a. As described above, the switching pressure transmission pipe 16a is configured by a capillary-shaped pipe through which the pressure is conducted but the flow rate of the refrigerant is very small. With the provision of the switching pressure transmission pipe 16a, the four-way valve 2b substantially functions as a three-way valve. In addition, the compressor 1 is connected to the switching pressure transmission pipe 16a.
Third check valve 1 in a direction in which the refrigerant flows only to the suction side of
3 may be deployed.

[0058]

As described above, the first aspect of the present invention relates to the case where the load temperature detected by the temperature detector exceeds the upper limit or the lower limit of the target temperature zone preset in the temperature controller. If the temperature falls below, the refrigerant flow path of the four-way valve is switched to either the first condenser side or the second condenser side, and if the load temperature exceeds the upper or lower limit within the target temperature zone, the second Since both the first motor-operated valve and the second motor-operated valve are opened to control the refrigerant to be sent from the compressor in parallel with both the first condenser and the second condenser, the refrigerant due to the change in load When switching the flow path, from cooling operation to dehumidifying operation,
Also, there is no direct switching from the dehumidifying operation to the cooling operation. Therefore, a sudden change in the room temperature can be prevented.

The invention according to claim 2 is characterized in that when the load temperature detected by the temperature detector exceeds an upper limit of a target temperature zone preset in the temperature controller, the refrigerant flow path of the four-way valve is changed. Is switched to the first condenser side and the first motor-operated valve and the second motor-operated valve are closed, and when the load temperature falls below the upper limit of the target temperature zone, the refrigerant flow path of the four-way valve is switched to the first condenser. The second motor-operated valve is opened while holding the second motor-operated valve, and when the load temperature falls below the lower limit of the target temperature zone, the refrigerant flow path of the four-way valve is switched to the second condenser side and the first motor-operated valve and The second motor-operated valve is closed, and when the load temperature exceeds the lower limit of the target temperature zone, the first motor-operated valve is configured to be opened while the refrigerant flow path of the four-way valve is held on the second condenser side. If the load temperature falls below the upper limit of the target temperature range of the temperature controller or If turned to continue the operation while holding the refrigerant flow path of the four-way valve intact, it is possible to reduce the switching circuit number of the four-way valve, it is possible to lengthen the service life. Further, since the operation is not directly switched from the cooling operation to the dehumidifying operation or from the dehumidifying operation to the cooling operation, it is possible to prevent a sudden change in the load temperature.

According to a third aspect of the present invention, the four-way valve and the compressor suction side are connected by a capillary-shaped switching pressure transmission pipe in which the pressure is conducted but the flow rate of the refrigerant is very small. Therefore, the four-way valve can be used substantially as a three-way valve.

Further, the invention according to claim 4 is characterized in that a third bypass pipe communicating from the second condenser inlet to the first condenser inlet and having a first motor-operated valve; Since a fourth bypass pipe having a second motor-operated valve communicating with the second condenser inlet side from the vessel inlet side is provided, the first condenser and the fourth condenser pipe regardless of the refrigerant flow switching state of the four-way valve. Refrigerant from the compressor can be sent to both of the second condensers in parallel. Therefore, when the operation is switched due to a change in load, the cooling operation is switched to the dehumidifying operation,
Or because it does not switch directly from dehumidifying operation to cooling operation,
A sudden change in the load temperature can be prevented.

According to a fifth aspect of the present invention, a fifth bypass pipe communicating between the first condenser inlet and the second condenser inlet is provided. Since the third electric valve capable of circulating the refrigerant is arranged in the direction, regardless of the refrigerant flow path switching state of the four-way valve, the refrigerant from the compressor is connected in parallel to both the first condenser and the second condenser. Can be sent.
Therefore, when the refrigerant flow path is switched due to a change in the load, the cooling operation is not directly switched from the dehumidifying operation to the dehumidifying operation, or the cooling operation is not directly switched, so that a sudden change in the load temperature can be prevented.

According to a sixth aspect of the present invention, when the refrigerant pressure on the compressor discharge side detected by the pressure detector is equal to or higher than the set pressure, both the first motor-operated valve and the second motor-operated valve are provided.
Or, since the third motor-operated valve is opened to control the refrigerant from the compressor to be sent in parallel to both the first condenser and the second condenser, the first condenser or the second condenser The compressed refrigerant can be sent to both condensers when the temperature of the air supplied to the condenser increases or when the air volume decreases. Therefore, the operation of the compressor can be continued, and the reliability can be improved.

Further, the invention according to claim 7 is characterized in that, when the refrigerant is selectively flowing to either the first condenser or the second condenser, the first condenser is provided at predetermined time intervals. Open the third motorized valve or both the first motorized valve and the second motorized valve to control the refrigerant to be periodically sent from the compressor in parallel with both the first and second condensers. Because
Even if the refrigerant leaked from the four-way valve accumulates as a liquid refrigerant in the first condenser exposed to the low-temperature outside air, it is recovered by the compressed refrigerant periodically sent at predetermined time intervals, and continues stable operation. be able to.

According to the present invention, a first check valve is provided between the four-way valve and the first condenser to allow the refrigerant to flow only toward the first condenser. Since the second check valve that allows the refrigerant to flow only toward the second condenser is disposed between the first condenser and the second condenser, the first condenser and the second condenser Since the liquid refrigerant does not return to the suction side of the compressor from the unused side condenser of the compressor through the suction side pipe or the switching pressure transmission pipe of the four-way valve, it is possible to reduce the capacity. Thereby, a more reliable air conditioner can be obtained.

According to the ninth aspect of the present invention, since the suction-side pipe is provided with the third check valve for allowing the refrigerant to flow only to the compressor suction side, the third check valve is exposed to the low-temperature outside air. Even if the pressure in the condenser decreases, the compressor suction gas does not flow to the first condenser. Therefore, an amount of refrigerant that can be used for the dehumidifying operation in the refrigerant circuit can be secured, and stable operation can be continued.

Further, according to the tenth aspect of the present invention, since the switching check pressure transmission pipe is provided with the third check valve for allowing the refrigerant to flow only to the compressor suction side, the first check valve is exposed to low-temperature outside air. Even if the pressure in the condenser decreases, the compressor suction gas does not flow to the first condenser. As a result, an amount of refrigerant that can be used for the dehumidifying operation in the refrigerant circuit can be secured, and stable operation can be continued.

[Brief description of the drawings]

FIG. 1 is a refrigerant system diagram of an air conditioner according to Embodiment 1 of the present invention.

FIG. 2 is an electric circuit diagram of the air conditioner according to Embodiment 1 of the present invention.

FIG. 3 is an operation flowchart of the air conditioner according to Embodiment 1 of the present invention.

FIG. 4 is an explanatory diagram showing an operation state of the four-way valve according to the first embodiment of the present invention.

FIG. 5 is a refrigerant system diagram of an air conditioner according to Embodiment 2 of the present invention.

FIG. 6 is a refrigerant system diagram of an air conditioner according to Embodiment 3 of the present invention.

FIG. 7 is a refrigerant system diagram of an air conditioner showing a conventional technique.

FIG. 8 is a refrigerant system diagram of an air conditioner showing another related art.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 compressor, 2b four-way valve, 3 first blower, 4 first condenser, 5 throttle device, 6 second blower, 7 evaporator, 8 second condenser, 11 first electric valve, 11a
Third electric valve, 12 Second electric valve, 13 Third check valve, 14 Negative check valve, 15 Second check valve, 16
a Switching pressure transmission pipe, 16b Suction side pipe, 1
9 first bypass pipe, 20 second bypass pipe,
33 pressure detector, 34 temperature detector, 35 temperature controller, 37 third bypass pipe, 38 fourth bypass pipe, 39 fifth bypass pipe.

Claims (10)

[Claims] 1. A compressor for compressing refrigerant gas, a four-way valve for selectively switching a refrigerant flow path from the compressor, a first condenser blown by a first blower, a throttle device, and a second compressor. The evaporator blown by the blower is sequentially connected in a ring shape to form a refrigeration cycle, and is connected in parallel with the first condenser between the four-way valve and the first condenser outlet side. A second condenser blown by the second blower at a position downstream of the air path of the evaporator, and a suction-side pipe that communicates the four-way valve with the compressor suction side. In the air conditioner, the air from the blower is air-conditioned by the evaporator and the second condenser and then sent to the air-conditioning load side, wherein the compressor is discharged from the compressor discharge side to the first condenser inlet side. Connect the first motor-operated valve by bypassing the four-way valve A first bypass pipe, a second bypass pipe having a second motor-operated valve connected by bypassing the four-way valve from the compressor discharge side to the second condenser inlet side, and an air conditioning load side. A temperature detector that is installed and detects a load temperature, and a temperature controller that controls a state of a refrigerant flowing through the evaporator and the second condenser to adjust a load temperature on an air conditioning load side is provided. When the load temperature detected by the temperature detector exceeds an upper limit of a target temperature zone preset in the temperature controller or falls below a lower limit, the refrigerant flow of the four-way valve is controlled. The path is switched to either the first condenser side or the second condenser side, and when the load temperature enters the target temperature zone beyond its upper limit or lower limit, the first motor-operated valve and the Open both second motorized valves An air conditioner characterized in that it is controlled configured to send the refrigerant from the first condenser and the compressor in parallel both the second condenser Te. 2. The air conditioner according to claim 1, wherein the temperature controller has a load temperature detected by the temperature detector that exceeds an upper limit of a target temperature zone preset in the temperature controller. In the case where the refrigerant passage of the four-way valve is switched to the first condenser side and the first motor-operated valve and the second motor-operated valve are closed, and when the load temperature is lower than the upper limit of the target temperature zone, The second motor-operated valve is opened while the refrigerant flow path of the four-way valve is held on the first condenser side, and when the load temperature is lower than the lower limit of the target temperature zone, the refrigerant flow of the four-way valve is The path is switched to the second condenser side, and the first motor-operated valve and the second motor-operated valve are closed. When the load temperature exceeds the lower limit of the target temperature zone, the refrigerant flow of the four-way valve is changed. The first motor-operated valve while maintaining the passage on the second condenser side. An air conditioner, wherein the air conditioner is configured to open. 3. The air conditioner according to claim 1, wherein a pressure is conducted between the four-way valve and the compressor suction side instead of the suction side pipe, but a refrigerant flow rate is very small. An air conditioner characterized by being connected by a capillary-shaped switching pressure transmission pipe. 4. The air conditioner according to any one of claims 1 to 3, wherein the first bypass pipe and the second bypass pipe are replaced with a first condenser pipe from a second condenser inlet side. A third bypass pipe communicating with the condenser inlet side, and a fourth bypass pipe communicating from the first condenser inlet side to the second condenser inlet side are provided, and the third bypass pipe is provided. An air conditioner is provided with a first electric valve and a second electric valve in the fourth bypass pipe. 5. The air conditioner according to claim 1, wherein the first electric valve, the first bypass pipe, the second electric valve, and the second bypass pipe are connected to each other. Alternatively, a fifth bypass pipe communicating between the first condenser inlet and the second condenser inlet is provided, and a third electric valve capable of bidirectionally circulating a refrigerant through the fifth bypass pipe. An air conditioner characterized by being equipped with: 6. The air conditioner according to claim 1, further comprising a pressure detector for detecting a refrigerant pressure on a discharge side of the compressor, wherein the refrigerant detected by the pressure detector is provided. When the pressure is equal to or higher than a preset pressure, both the first motor-operated valve and the second motor-operated valve, or open the third motor-operated valve to open both the first condenser and the second condenser An air conditioner, wherein the air conditioner is controlled so as to send the refrigerant from the compressor in parallel. 7. The air conditioner according to any one of claims 1 to 6, wherein a refrigerant is selectively circulated toward one of the first condenser and the second condenser. State, both the first motor-operated valve and the second motor-operated valve, or the third motor-operated valve is opened at predetermined time intervals, and both the first condenser and the second condenser are periodically arranged in parallel. An air conditioner characterized in that it is controlled to send refrigerant from a compressor. 8. The air conditioner according to claim 1, wherein the refrigerant flows between the four-way valve and the first condenser only toward the first condenser. A first check valve is provided, and a second check valve is provided between the four-way valve and the second condenser to allow the refrigerant to flow only toward the second condenser. Air conditioner. 9. The first, second, fourth to eighth aspects of the present invention.
The air conditioner according to any one of the above items, further comprising a third check valve that allows the refrigerant to flow only to the compressor suction side in the suction-side pipe. 10. The air conditioner according to claim 3, further comprising a third check valve disposed in the switching pressure transmission pipe to allow the refrigerant to flow only to the compressor suction side. .