JP2927230B2 - Binary refrigeration equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a binary refrigeration system, and more particularly to a countermeasure against a high pressure of a high pressure refrigerant in a low temperature side refrigeration cycle.

[0002]

2. Description of the Related Art Conventionally, as a refrigerating apparatus, there is a binary refrigerating apparatus in which a high-temperature side refrigerating cycle and a low-temperature side refrigerating cycle individually perform a refrigerating operation. This binary refrigeration system
It is used to obtain a low temperature of minus several tens of degrees, and can be used at high efficiency from a high compression ratio to a low compression ratio, which is advantageous in energy saving.

[0003] The high-temperature side refrigeration cycle of the binary refrigeration system is composed of a compressor, a condenser, an expansion valve, and an evaporator of a cascade heat exchanger connected in order. The low-temperature side refrigeration cycle includes a compressor and a compressor. The condenser, expansion valve, and evaporator of the cascade heat exchanger are connected in order. Then, in the cascade heat exchanger, heat of condensation is condensed between the low-temperature side refrigeration cycle and the heat of evaporation of the high-temperature side refrigeration cycle.

[0004]

In the above-described two-stage refrigeration system, frost is formed on the evaporator of the low-temperature side refrigeration cycle, so that the discharge gas refrigerant (hereinafter, referred to as hot gas) of the compressor is evaporated at predetermined time intervals. To perform defrost operation.

However, when the cooling operation is restarted after the end of the defrosting operation, the high-pressure refrigerant pressure of the low-temperature side refrigeration cycle may abnormally increase, and the protection high-pressure switch is activated to generate an alarm. There was a problem.

That is, when both the outside air temperature and the inside temperature are low, the defrost operation takes time, while the outside air temperature is low, so that the refrigerant accumulates in the high temperature side condenser of the high temperature side refrigeration cycle. Further, in the low-temperature side refrigeration cycle, if the defrost operation is long, the temperature-sensitive cylinder portion of the temperature-sensitive expansion valve is heated, and when the cooling operation is restarted, the expansion valve is fully opened and the refrigerant of the low-temperature side refrigeration cycle is cooled. The amount of circulation increases. In addition, there is a problem that the high-pressure refrigerant pressure in the low-temperature side refrigeration cycle rises abnormally, coupled with the fact that the heat exchange in the cascade heat exchanger is small due to the accumulation of the refrigerant in the high-temperature side condenser described above.

[0007] The present invention has been made in view of such a point, and suppresses an abnormal increase in the high-pressure refrigerant pressure when the cooling operation is restarted after the defrost operation, so that the cooling operation can be smoothly restarted. It is intended to do so.

[0008]

[Means for Solving the Problems]

-Summary of the Invention-The present invention relates to a control pressure detecting means (HPS2) for outputting a high pressure signal when a high pressure value lower than an abnormal high pressure value detected by the protection pressure detecting means (HPS1) is used. At the time of restart of the cooling operation after the defrost operation of the low temperature side refrigeration cycle (30), the control pressure detecting means (HPS
2) When the high voltage signal is output, the cooling operation is temporarily stopped, and after waiting for a predetermined time, the cooling operation is restarted.

-Specific Items of the Invention- Specifically, as shown in FIG. 1, means taken by the invention according to claim 1 includes a compressor (21), a condenser (22), and an expansion mechanism (EV). -1) and cascade heat exchanger (1H) evaporator (2
3) are connected in sequence to form a high-temperature refrigeration cycle (20) in which refrigerant circulates, while the compressor (31), the condenser (32) of the cascade heat exchanger (1H), and the expansion mechanism (EV- It is premised on a binary refrigeration system in which a low-temperature refrigeration cycle (30) in which a refrigerant is circulated by sequentially connecting the evaporator (33) and the evaporator (33) is configured.

The low-temperature side refrigeration cycle (30) has a control pressure detecting means (HP) for outputting a high-pressure signal when the high-pressure refrigerant pressure on the discharge side of the compressor (31) reaches a predetermined high pressure value.
S2) is provided.

In addition, when the control pressure detecting means (HPS2) outputs a high-pressure signal when the cooling operation is restarted after the defrost operation of the low-temperature side refrigeration cycle (30), the cooling operation is temporarily stopped and waits for a predetermined time. After that, a standby control means (40) for restarting the cooling operation is provided.

[0012] Further, according to a second aspect of the present invention, in the first aspect of the present invention, the high-pressure refrigerant pressure at the discharge side of the compressor (31) is set to a predetermined value in the low-temperature refrigeration cycle (30). The protection pressure detection means (HPS2), which outputs an abnormal signal when the abnormal high pressure value is reached, is provided, while the control pressure detection means (HPS2) is lower than the abnormal high pressure value detected by the protection pressure detection means (HPS1). It is configured to output a high voltage signal when a high voltage value is reached.

-Operation- According to the above-mentioned invention specifying matter, in the invention according to claim 1,
First, during the cooling operation, the high temperature side refrigeration cycle (20)
The refrigerant discharged from the compressor (21) is condensed in the condenser (22) to become a liquid refrigerant, and after being depressurized by the expansion mechanism (EV-1),
The evaporator (23) of the cascade heat exchanger (1H) evaporates to gas refrigerant and returns to the compressor (21).

On the other hand, the refrigerant discharged from the compressor (31) of the low-temperature side refrigeration cycle (30) is supplied to the cascade heat exchanger (1H).
The condenser (32) condenses into a liquid refrigerant, and the expansion mechanism (EV
After the pressure is reduced in -2), the refrigerant is evaporated in the evaporator (33) to become a gas refrigerant and returns to the compressor (31).

Further, the defrost operation is performed every predetermined time to stop the operation of the high-temperature side refrigeration cycle (20).
The hot gas (gas refrigerant) discharged from the compressor (31) of the low temperature side refrigeration cycle (30) is supplied to the low temperature side evaporator (33) for defrosting.

When the high-pressure refrigerant pressure of the low-temperature side refrigeration cycle (20) rises above a predetermined pressure when the cooling operation is restarted from the defrost operation, for example, 23.5 kg / cm.
^When the temperature rises from ² , the high-temperature side compressor (21) and the low-temperature side compressor (31) are stopped, and then wait for a predetermined time. Thereafter, the cooling operation is restarted.

That is, when the outside air temperature is low and the inside temperature is low, the refrigerant accumulates in the high-temperature side condenser (22) and the defrost operation takes a long time. ) Is heated, the opening of the low-temperature side expansion valve (EV-2) at the time of restarting the cooling operation increases, and the high-pressure refrigerant pressure increases.

At this time, by waiting for the predetermined time, the refrigerant accumulated in the high-temperature side condenser (22) is circulated, and the low-temperature side evaporator (33) is cooled. The abnormal rise of the high-pressure refrigerant pressure of (30) is suppressed.

[0019]

Therefore, according to the first aspect of the present invention, when the cooling operation is restarted after the defrost operation of the low-temperature refrigeration cycle (30), the control pressure detecting means (HPS2)
When the high-pressure signal is output, the cooling operation is temporarily stopped to wait for a predetermined time.
It is possible to circulate the refrigerant accumulated in the evaporator and to cool the low-temperature side evaporator (33).

As a result, when the cooling operation is restarted, the opening of the low temperature side expansion valve (EV-2) can be suppressed from increasing, and the cascade heat exchanger (1H) can perform heat exchange. Therefore, an abnormal increase in the high-pressure refrigerant pressure in the low-temperature side refrigeration cycle (30) can be suppressed.

According to the second aspect of the present invention, the control pressure detecting means (HPS2) is replaced by the protective pressure detecting means (HPS1).
Since the pressure is set lower than the operating pressure of (1), an alarm operation due to the operation of the protection pressure detecting means (HPS1) can be prevented.

[0022]

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

As shown in FIG. 1, a binary refrigeration system (10)
Is for cooling a refrigerator or a freezer, and includes a high-temperature unit (1A) and a low-temperature unit (1B), and a high-temperature unit (1A) and a part of the low-temperature unit (1B) While the low-side refrigeration cycle (20) is configured, the low-temperature side refrigeration cycle (3
0) is configured.

The high-temperature side refrigeration cycle (20) includes a compressor (21) and a high-pressure gas pipe (2) on the discharge side of the compressor (21).
a) and a condenser (22) connected via
2) and a cascade heat exchanger (1H) evaporator (23) connected via a liquid pipe (2b), and the evaporator (23) is connected to a compressor () via a low-pressure gas pipe (2c). 21) It is connected to the suction side.

The condenser fan (22) has a condenser fan (22-
F) is provided, while an expansion valve (EV-1) is provided in the middle of the liquid pipe (2b). The compressor (21) side (base end side) of the liquid pipe (2b) and the low-pressure gas pipe (2c) in the high temperature side refrigeration cycle (20) is configured as a high temperature side unit (1A). . Specifically, the high-temperature side unit (1A) consists of a compressor (21) and a high-pressure gas pipe (2a).
And condenser (22) and condenser fan (22-F) and liquid piping (2
b) and a part of the low-pressure gas pipe (2c).

As shown in FIG. 2, the expansion valve (EV-1) is composed of an external pressure equalizing type temperature-sensitive expansion valve.
1) Evaporator (33) in cascade heat exchanger (1H)
, That is, attached to the low-pressure gas pipe (2c). Further, an external pressure equalizing pipe (E1) is connected to the high temperature side expansion valve (EV-1). The external pressure equalizing pipe (E1) includes a three-way switching valve (SV-1) and a low pressure gas pipe (2c). Is connected to the mounting part of the temperature-sensitive tube (T1).

One port of the three-way switching valve (SV-1) is connected to a low-pressure gas pipe (2c), and the three-way switching valve (SV-1)
The liquid refrigerant pressure acts on the expansion valve (EV-1) when the valve is turned on, and the expansion valve (EV-1) is closed, while the three-way switching valve (SV-1)
When the gas is turned off, the gas refrigerant pressure acts on the expansion valve (EV-1) so that the gas refrigerant reaches a predetermined degree of superheat.
1) opens to a predetermined opening.

On the other hand, the low-temperature side refrigeration cycle (30)
As shown in FIG. 2, the compressor (31), the condenser (32) of the cascade heat exchanger (1H), and the expansion valve (EV-2) as an expansion mechanism
And an evaporator (33) are connected in order, and the evaporator (33) is provided with an evaporator fan (33-F). Then, from the middle of the liquid pipe (2b) and the low-pressure gas pipe (2c) in the high-temperature side refrigeration cycle (20), the cascade heat exchanger (1H) side (tip side) and the low-temperature side refrigeration cycle (3
0) and the low-temperature side unit (1B). Specifically, the low-temperature side unit (1B) is connected to the low-temperature side refrigeration cycle (30), the condenser (32) of the cascade heat exchanger (1H), and a part of the liquid pipe (2b) and the low-pressure gas pipe (2c). It is formed by a high temperature side expansion valve (EV-1) and a temperature sensing cylinder (T1).

The low temperature side expansion valve (EV-2) is constituted by an external pressure equalizing type temperature sensitive expansion valve, and the temperature sensitive cylinder (T2) is connected to the refrigerant outlet side of the low temperature side evaporator (33), Attached to the gas pipe (3b) and connected to an external pressure equalizing pipe (E2). The external pressure equalizing pipe (E2) is connected to a portion of the low-pressure gas pipe (3b) to which the temperature-sensitive cylinder (T2) is attached, and the low-temperature side expansion valve (EV-2) is set so that the gas refrigerant has a predetermined degree of superheat. Opens at a predetermined opening.

A high-pressure gas pipe (3a) on the discharge side of the low-temperature side compressor (31) is provided with a four-way switching valve (34), and the four-way switching valve (34) has an operating differential pressure passage (34). 35) and the hot gas bypass passage (36) are connected. The four-way switching valve (34) is turned off during the cooling operation, and supplies the refrigerant discharged from the low-temperature side compressor (31) to the condenser (32), as shown by the solid line in FIG. It is configured to be turned on during the defrost operation, and to supply the refrigerant discharged from the low temperature side compressor (31) to the hot gas bypass passage (36) as shown by the broken line in FIG.

The differential pressure passage (35) is connected to the low-pressure gas pipe (3b) on the suction side of the compressor (31) and from the four-way switching valve (34) to the suction side of the compressor (31). A check valve (CV-1) and a capillary tube (CP-1) for adjusting the flow rate of the refrigerant are provided so as to allow only the refrigerant flow.

The hot gas bypass passage (36) is connected to the suction side of the low-temperature side evaporator (33), that is, to the liquid pipe (3c) between the expansion valve (EV-2) and the evaporator (33). The hot gas is supplied to the low-temperature side evaporator (33) every predetermined time, for example, every four hours to remove frost from the evaporator (33). Further, in the middle of the hot gas bypass passage (36), a drain pan heater (H1), a drain receiving heater (H2), and a fan guard heater (H3) are connected in parallel with each other, and the compressor (31) A check valve (CV-2) is provided so as to allow only the refrigerant flow from the discharge side to the low-temperature side evaporator (33).

The drain pan heater (H1) removes frost from the drain pan provided below the low-temperature side evaporator (33), and the drain receiving heater (H2) is a drain pan heater formed in the drain pan. The frost is removed, and the fan guard heater (H3) removes frost around the evaporator fan (33-F).

Each of the low-temperature refrigeration cycles (30) is provided with a capacity control bypass passage (37).
One end of the capacity control bypass passage (37) is connected to the compressor (3
The high pressure gas pipe (3a) between 1) and the four-way switching valve (34) is connected, and the other end is connected to the liquid pipe (3c) between the expansion valve (EV-2) and the evaporator (33). It is connected. The capacity control bypass passage (37) is provided with an electromagnetic valve (SV-3) and a capillary tube (CP-3), and serves to evaporate hot gas discharged from the compressor (31) to an evaporator (33). To adjust the cooling capacity.

The high-pressure gas pipe (3a) of the low-temperature refrigeration cycle (30) has a high-pressure switch (HPS1) that outputs an abnormal signal when the high-pressure refrigerant pressure rises abnormally, And a high-pressure pressure sensor (HPS2) for outputting a high-pressure signal when the high-pressure refrigerant pressure, which is the hot gas pressure, reaches a predetermined high pressure value in the hot gas bypass passage (36). A defrost pressure sensor (HPS3) is provided.

The high-pressure pressure sensor (HPS2) is one of the features of the present invention. The high-pressure pressure sensor (HPS2) is a high-pressure pressure sensor (HPS1) which is a protection pressure detecting means. It constitutes control pressure detecting means for outputting a signal.

In the low-pressure gas pipe (3b) of the low-temperature refrigeration cycle (30), a low-pressure switch (LPS1) that outputs an abnormal signal when the low-pressure refrigerant pressure abnormally decreases, and a low-temperature evaporator (33). A) a defrost temperature sensor (Th-1) for outputting a defrost end signal when the refrigerant temperature on the refrigerant outflow side reaches a predetermined high temperature.

As a feature of the present invention, a binary refrigeration system (10)
Is provided with a controller (40) for controlling the refrigeration operation. The controller (40) has a high-temperature compressor (2
1) and start / stop of the low-temperature side compressor (31), and when the cooling operation is restarted after the defrost operation of the low-temperature side refrigeration cycle (30), the high-pressure pressure sensor (HPS
When 2) outputs a high-voltage signal, the cooling operation is temporarily stopped, and after waiting for a predetermined time, a standby control means is configured to restart the cooling operation.

-Operation and Effect of Binary Refrigeration Unit (10)-Next, the operation of the binary refrigeration unit (10) will be described with reference to Table 1.

[0040]

[Table 1]

First, when performing a cooling operation (thermo-on), both the high-temperature side compressor (21) and the low-temperature side compressor (31) are driven, and the high-temperature side condenser fan (22-F) and the low-temperature side evaporator are operated. The fan (33-F) drives together. Then, the three-way switching valve (SV-1) is turned off and the high temperature side expansion valve (EV
-1) The external pressure equalizing pipe (E1) is in communication.

In this state, in the high-temperature side refrigeration cycle (20), the refrigerant discharged from the compressor (21) is condensed in the condenser (22) to become a liquid refrigerant, and the low-temperature side unit (1)
B). And the liquid refrigerant is an expansion valve (EV-1)
After depressurizing in the evaporator of the cascade heat exchanger (1H) (2
In 3), the refrigerant evaporates to become a gas refrigerant and returns to the compressor (21), and this circulation is repeated.

On the other hand, in the low temperature side refrigeration cycle (30), the four-way switching valve (34) is switched to the solid line in FIG.
Refrigerant discharged from is passed through the high-pressure gas pipe (3a) and condensed in the condenser (32) of the cascade heat exchanger (1H) to become a liquid refrigerant, and this liquid refrigerant is depressurized by the expansion valve (EV-2). After doing
Evaporated by the evaporator (33) to become a gas refrigerant and the compressor (31)
And this cycle will be repeated. Then, cooling air is generated by the low-temperature side evaporator (33) to cool the inside of the refrigerator.

When the internal temperature reaches a predetermined temperature, the thermostat is turned on to suspend the cooling operation, the high temperature side compressor (21) and the low temperature side compressor (31) are stopped, and the low temperature side evaporator fan (33- F) Only drive.

A defrosting operation (defrosting operation) is performed every predetermined time such as four hours. In this case, the operation of the high-temperature side refrigeration cycle (20) is stopped.
1) and the high-temperature condenser fan (22-F) is stopped, and the three-way switching valve (SV-1) is turned on to fully close the high-temperature expansion valve (EV-1). Then, in the low-temperature side refrigeration cycle (30), the four-way switching valve (34) is switched to the broken line in FIG. 2 to drive the compressor (31) and the low-temperature side evaporator fan (33-F). In this state, the hot gas (gas refrigerant) discharged from the low temperature side compressor (31) flows through the hot gas bypass passage (36) from the four way switching valve (34) and is supplied to the low temperature side evaporator (33). To return to the compressor (31), whereby defrosting is performed.

Next, the operation at the time of restarting the cooling operation after the end of the defrost operation, which is a feature of the present invention, will be described based on the control flow of FIG.

First, in step ST1, it is determined whether or not the above-described defrost operation is being performed, and the process waits in step ST1 until the defrost operation is completed. Thereafter, the refrigerant temperature on the refrigerant outflow side of the low-temperature side evaporator (33) becomes a predetermined high temperature, and the defrost temperature sensor (Th-1) outputs an end signal or the discharge of the compressor (31). The high-pressure refrigerant pressure on the side reaches a predetermined pressure, and the pressure sensor for defrost (HPS3)
Outputs the end signal, or when the end signal is output after the elapse of a predetermined time, the defrost operation is ended.

Then, the determination in step ST1 is NO, and the process proceeds to step ST2, where the low-temperature side evaporator fan (33-
The delay control of F) is performed, and it is determined whether or not the delay control is being performed. In other words, after the end of the defrost operation, the low-temperature side evaporator (33) is warmed by the hot gas, so that both the high-temperature side compressor (21) and the low-temperature side compressor (31) are driven,
Rotate the high-temperature condenser fan (22-F) while stopping the low-temperature evaporator fan (33-F). Then, the four-way switching valve (34) is switched to the solid line in FIG. 2, and the three-way switching valve (SV-1) is turned off to open the high temperature side expansion valve (EV-1).

If the above delay control is being performed, step ST2
The process then proceeds to step ST4 to determine whether or not the high-pressure refrigerant pressure HP of the low-temperature side refrigeration cycle (20) has risen above a predetermined pressure P1, for example, whether or not it has risen above 23.5 kg / cm ² . When the high-pressure refrigerant pressure HP is lower than the predetermined pressure P1, the process returns to step ST2. When the delay control is completed while the high-pressure refrigerant pressure HP is lower than the predetermined pressure P1, for example, when the one-minute delay control is completed, the process proceeds from step ST2 to step ST4 to restart the cooling operation (thermo-on) described above. become.

On the other hand, if the high-pressure refrigerant pressure HP rises above the predetermined pressure P1 of 23.5 kg / cm ^{2 in} step ST3, the high-pressure pressure sensor (HPS2) outputs a high-pressure signal. The process moves to step ST5. Then, after stopping the high-temperature side compressor (21) and the low-temperature side compressor (31) driven in step ST2,
Moving to step ST6, standby control is executed.

That is, the low-temperature side evaporator fan (33-F)
Similarly, stop the high-temperature condenser fan (22-F), turn on the three-way switching valve (SV-1), close the high-temperature expansion valve (EV-1), and wait for 1 minute. When this standby control ends, the determination in step ST6 becomes NO, and the process proceeds to step ST4, where the above-described cooling operation is restarted.

Specifically, as shown by the hatched portion in FIG.
When the outside air temperature is low and the internal temperature is low, the refrigerant accumulates in the high-temperature condenser (22) while the defrost operation takes a long time, so that the low-temperature evaporator (33) is heated. Accordingly, the opening of the low-temperature side expansion valve (EV-2) during the delay control increases, and the high-pressure refrigerant pressure HP increases.

At this time, in step ST2, since the high temperature side compressor (21) and the low temperature side compressor (31) are driven once, the refrigerant of the high temperature side refrigeration cycle (20) and the low temperature side refrigeration cycle (30) is discharged. Even a small amount will circulate,
The refrigerant accumulated in the high-temperature side condenser (22) circulates, and the low-temperature side evaporator (33) is cooled. As a result, when the cooling operation is restarted after the standby control, the opening of the low-temperature side expansion valve (EV-2) does not increase, and the heat exchange of the cascade heat exchanger (1H) is performed. The abnormal increase in the high-pressure refrigerant pressure of the side refrigeration cycle (30) is suppressed.

Therefore, according to the present embodiment, when the high-pressure pressure sensor (HPS2) outputs a high-pressure signal when restarting the cooling operation after the defrost operation of the low-temperature side refrigeration cycle (30), the cooling operation is temporarily stopped. Since it is made to stand by for a predetermined time, the refrigerant accumulated in the high-temperature side condenser (22) can be circulated, and the low-temperature side evaporator (3) can be circulated.
3) can be cooled.

As a result, when the cooling operation is resumed, the opening of the low temperature side expansion valve (EV-2) can be prevented from increasing, and the cascade heat exchanger (1H) can perform heat exchange. Therefore, an abnormal increase in the high-pressure refrigerant pressure in the low-temperature side refrigeration cycle (30) can be suppressed.

In particular, since the high-pressure pressure sensor (HPS2) sets the high-pressure signal to be lower than the operating pressure of the high-pressure pressure switch (HPS1), it is possible to prevent an alarm operation due to the operation of the high-pressure pressure switch (HPS1). Can be.

[0057]

In this embodiment, the high-temperature side expansion valve (EV-1) is fully closed during the standby control in step ST6, but the high-temperature side expansion valve (EV-1) is opened. In short, the high temperature side compressor (21) and the low temperature side compressor (31) may be stopped and wait for a predetermined time.

The refrigerant circuit and arrangement of the high-temperature side unit (1A) and the low-temperature side unit (1B) are not limited to the embodiment. For example, only the low-temperature side evaporator (33) is provided in the refrigerator. It may be arranged.

[Brief description of the drawings]

FIG. 1 is a refrigerant circuit diagram showing a binary refrigeration apparatus of the present invention.

FIG. 2 is a refrigerant circuit diagram showing a low-temperature side unit.

FIG. 3 is a control flowchart showing a transition operation from a defrost operation to a cooling operation.

FIG. 4 is a characteristic diagram showing a control range in a relationship between the outside air temperature and the inside temperature.

[Explanation of symbols]

 10 Binary refrigeration unit 1A High temperature side unit 1B Low temperature side unit 1H Cascade heat exchanger 20 High temperature side refrigeration cycle 21 Compressor 22 Condenser 23 Evaporator EV-1 Expansion valve (expansion mechanism) T1 Temperature sensitive cylinder 30 Low temperature side refrigeration cycle 31 Compressor 32 Condenser 33 Evaporator 36 Hot gas bypass passage EV-2 Expansion valve (Expansion mechanism) 40 Controller (Standby control means) HPS1 High pressure switch (Protective pressure detecting means) HPS2 High pressure sensor (Control pressure) Detection means)

Continuation of front page (58) Field surveyed (Int.Cl. ⁶ , DB name) F25B 7/00

Claims (2)

(57) [Claims] A high temperature side in which a compressor (21), a condenser (22), an expansion mechanism (EV-1), and an evaporator (23) of a cascade heat exchanger (1H) are connected in order and a refrigerant circulates. While the refrigeration cycle (20) is configured, the compressor (31) and the condenser (3H) of the cascade heat exchanger (1H)
2), the expansion mechanism (EV-2) and the evaporator (33) are connected in order to constitute a low-temperature refrigeration cycle (30) in which the refrigerant circulates. 30) is provided with a control pressure detecting means (HPS2) for outputting a high pressure signal when the high pressure refrigerant pressure on the discharge side of the compressor (31) reaches a predetermined high pressure value, while the low temperature side refrigeration cycle (30) is provided. Control pressure detection means (HPS2) when cooling operation restarts after defrost operation
And a standby control means (40) for temporarily stopping the cooling operation, waiting for a predetermined time, and then restarting the cooling operation when a high voltage signal is output. 2. The two-way refrigeration system according to claim 1, wherein the low-temperature refrigeration cycle (30) outputs an abnormal signal when the high-pressure refrigerant pressure on the discharge side of the compressor (31) reaches a predetermined abnormal high pressure value. While the protection pressure detection means (HPS1) is provided, the control pressure detection means (HPS2) outputs a high pressure signal when the protection pressure detection means (HPS1) detects a high pressure value lower than the abnormal high pressure value. A binary refrigeration apparatus characterized in that: