JP2016161234A - Freezer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To protect a refrigerant circuit in a liquid-sealed state, while suppressing increase in cost and securing actuation of the refrigerant circuit.SOLUTION: A refrigerant circuit (20) has pipeline parts (102a, 103a) held by two valves, and at least one of the two valve is a manual valve (70, 75) that is operated manually and is made into an open state during the refrigerant circuit (20). In the refrigerant circuit (20), provided are bypass passages (90, 95) bypassing the pipeline parts (102a, 103a) to positions beyond the manual valves (70, 75). In the bypass passages (90, 95), a fusible plug (80) is provided.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a refrigeration apparatus.

  An air conditioner that is one of refrigeration apparatuses having a refrigerant circuit is provided on a ship (see, for example, Patent Document 1). Many of such marine air conditioners are relatively large (having a large amount of refrigerant), and it is troublesome to remove the refrigerant from the refrigerant circuit one by one during maintenance and repair. Therefore, in such an air conditioner, a so-called pump-down operation in which a refrigerant is accommodated by a compressor in a device (for example, a condenser) that can serve as a refrigerant container in a refrigerant circuit during maintenance or the like is performed by an operator. May be done manually. In the pump down operation, after the refrigerant is accommodated in the container, the refrigerant is confined in the container by the closing valve.

JP 2012-122670 A

  By the way, various valves are provided in the refrigerant circuit, and in the refrigerant circuit, a portion sandwiched between any of these valves and the closing valve may be formed. Therefore, when the operator makes a mistake in the operation of the closing valve during the pump down operation (hereinafter referred to as manual pump down operation) that is manually performed by the operator, a portion sandwiched between the two valves (piping) ) May remain in the liquid refrigerant (hereinafter referred to as a liquid seal). Further, even in an operation other than the manual pump-down operation, a liquid sealing state may occur depending on the operation of the valve (described later). In this liquid-sealed state, if the temperature of the liquid refrigerant left in the pipe rises for some reason, the pressure in that portion rises and an excessive force may be applied to the pipe.

  For this, it is conceivable to protect the refrigerant circuit by providing a pressure regulating valve at a place where the liquid seal state can be reached, but this increases the cost. If a fusible plug is used instead of the pressure regulating valve, the cost can be reduced. However, once the fusible plug is actuated, it cannot be closed again, so that it is difficult to normally operate the refrigerant circuit as it is. Of course, if the fusible plug is replaced, the refrigerant circuit operates normally. However, for example, if the fusible plug is actuated after leaving the port in an air conditioner for a ship, the exchanging operation on the ocean is not easy.

  The present invention has been made paying attention to the above-described problem, and aims to protect the refrigerant circuit in a liquid-sealed state while suppressing the increase in cost and ensuring the operation of the refrigerant circuit.

In order to solve the above problems, the first invention is
In a refrigeration apparatus comprising a refrigerant circuit (20) having a compressor (31, 31), a condenser (40), an expansion valve (50), and an evaporator (55) and circulating a refrigerant,
The refrigerant circuit (20) has a pipe part (102a, 103a) sandwiched between two valves,
At least one of the two valves is a manual valve (70,75) that is manually operated and is opened during operation of the refrigerant circuit (20);
The refrigerant circuit (20) is provided with a bypass path (90, 95) for bypassing the pipe portion (102a, 103a) to a position beyond the manual valve (70, 75).
The bypass passage (90, 95) is provided with a fusible plug (80).

  In this configuration, for example, when the piping parts (102a, 103a) are in a liquid-sealed state and the pressure rises above a predetermined level, the fusible plug (80) is activated. If it does so, the refrigerant | coolant in a piping part (102a, 103a) will be flowed to the position beyond a manual valve (70,75). As a result, the temperature and pressure in the pipe parts (102a, 103a) are reduced, and the pipe parts (102a, 103a), that is, the refrigerant circuit (20) are protected.

  During operation of the refrigerant circuit (20), the manual valve (70, 75) is in an open state, so that the fusible plug (80) is activated and the bypass section (90, 95) , 103a) is connected to the position beyond the manual valve (70,75), there is only a bypass path (90,95) parallel to the path through which the refrigerant flows during normal operation. The operation of the plug (80) does not affect the operation of the refrigerant circuit (20).

The second invention is the first invention, wherein
The piping section (102a, 103a) is a part of a piping system that connects the discharge port (31b, 31b) of the compressor (31, 31) and the refrigerant inlet of the condenser (40),
One of the two valves is a check valve (35) provided on the discharge port (31b, 31b) side of the compressor (31, 31), and the other is a refrigerant inlet of the condenser (40). It is a shut-off valve (70) provided on the side and operated manually.

  In this configuration, a state between the check valve (35) and the closing valve (70) can be in a liquid-sealed state depending on the operation of the closing valve (70). In that case, the pipe part in the liquid-sealed state is protected by the bypass passage (90, 95) having the fusible plug (80).

The third invention is the first or second invention, wherein
The piping part (103a) is a part of a piping system that connects the outlet of the condenser (40) and the inlet of the expansion valve (50),
One of the two valves is a closing valve (75) that is provided on the outlet side of the condenser (40) and is manually operated, and the other is provided on the inlet side of the expansion valve (50). It is a solenoid valve (45).

  In this configuration, a liquid seal state can be established between the electromagnetic valve (45) and the closing valve (70) depending on the operation of the closing valve (70). In that case, the pipe part in the liquid-sealed state is protected by the bypass passage (90, 95) having the fusible plug (80).

In addition, a fourth invention is any one of the first to third inventions,
The bypass passage (90, 95) is provided with a check valve (206) for preventing the refrigerant from flowing out from the pipe portion (102a, 103a) to the fusible plug (80). To do.

  In this configuration, the check valve (206) prevents the refrigerant from flowing into the bypass passage (90, 95).

  According to each of the first to third inventions, it is possible to protect the refrigerant circuit in the liquid-sealed state while suppressing the increase in cost and ensuring the operation of the refrigerant circuit.

  According to the fourth aspect of the invention, since the refrigerant is prevented from flowing into the bypass passages (90, 95), the fusible plug (80) can be easily removed.

FIG. 1 is a schematic configuration diagram of an air-conditioning apparatus according to Embodiment 1 of the present invention. FIG. 2 is a schematic configuration diagram of an air-conditioning apparatus according to Embodiment 2 of the present invention. FIG. 3 is a schematic configuration diagram of a bypass path according to the third embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1 of the Invention
FIG. 1 is a schematic configuration diagram of an air-conditioning apparatus (10) according to Embodiment 1 of the present invention. The air conditioner (10) of this embodiment is provided in a ship air conditioning system, and supplies conditioned air to a cabin (not shown). As shown in FIG. 1, the air conditioner (10) of this embodiment includes a refrigerant circuit (20) and a control unit (60). The control unit (60) controls a compressor unit (30) and a solenoid valve (45) which will be described later.

  The refrigerant circuit (20) includes a compressor unit (30), a condenser (40), a solenoid valve (45), an expansion valve (50), and an evaporator (55). The compressor unit (30), This is a closed circuit in which a condenser (40), a solenoid valve (45), an expansion valve (50), and an evaporator (55) are connected in order by piping. The refrigerant circuit (20) is filled with a refrigerant.

  The compressor unit (30) includes two compressors (31, 31). The number of compressors (31, 31) is merely an example. In this example, each compressor (31, 31) is a hermetic scroll compressor. Each compressor (31, 31) compresses the refrigerant sucked from the suction ports (31a, 31a), and discharges the compressed refrigerant from the discharge ports (31b, 31b).

  In the compressor unit (30), the two compressors (31, 31) are connected in parallel to each other. Specifically, the suction ports (31a, 31a) of the compressors (31, 31) are connected to the outlet pipe (101) of the evaporator (55). A check valve (35) is connected to the discharge port (31b, 31b) of each compressor (31, 31). These check valves (35) prevent the refrigerant from flowing back to the discharge ports (31b, 31b). The outlets of these check valves (35) are all connected to the pipe (102). The pipe (102) is connected to the refrigerant inlet of the condenser (40).

  Further, a gas side shut-off valve (70) is provided in the middle of the pipe (102), that is, between the check valve (35) and the condenser (40). The gas side closing valve (70) is a manual valve that switches between open and closed manually. The gas side shut-off valve (70) is used in the pump down operation described later. Further, the gas side shut-off valve (70) is opened while the refrigerant circuit (20) is in operation. That is, the gas side closing valve (70) is an example of the manual valve of the present invention.

  By the way, in the refrigerant circuit (20), there is a piping part (a part of the piping system) sandwiched between two valves. For example, the refrigerant circuit (20) has a pipe part (102a) sandwiched between two valves, a check valve (35) and a gas side shut-off valve (70). In the present embodiment, a first bypass passage (90) is provided for bypassing the pipe portion (102a) to a position beyond the gas-side stop valve (70) (a pipe portion (102b) described later). . The first bypass path (90) will be described in detail later.

  The condenser (40) is a so-called shell and tube type heat exchanger. The condenser (40) causes the refrigerant to exchange heat with cooling water (for example, seawater). The refrigerant outlet of the condenser (40) is connected to the evaporator (55) via the pipe (103).

  In the middle of the pipe (103), a liquid side shut-off valve (75), a solenoid valve (45), and an expansion valve (50) are provided in this order from the condenser (40) side. The liquid side shut-off valve (75) is also a manual valve that manually switches between open and close, like the gas side shut-off valve (70). The liquid side shut-off valve (75) is also used in the pump down operation described later. Further, the liquid side closing valve (75) is also opened while the refrigerant circuit (20) is in operation. That is, the liquid side closing valve (75) is an example of the manual valve of the present invention.

  The solenoid valve (45) is a valve used when stopping the compressor (31, 31), and is provided to protect the compressor (31, 31). If the liquid refrigerant remains in the evaporator (55) after the compressor (31, 31) is stopped, the liquid (3, 31) is operated when the compressor (31, 31) is operated next time. The refrigerant enters the compressor, and an excessive load is applied to the compressor (31, 31). Therefore, when stopping the compressor (31, 31), with the solenoid valve (45) closed, the compressor (31, 31) is operated for a while until the liquid refrigerant in the evaporator (55) runs out. Thereafter, the compressors (31, 31) are stopped.

  The expansion valve (50) is a so-called temperature automatic expansion valve. The temperature sensing cylinder (not shown) of the expansion valve (50) is attached to the outlet pipe (101) of the evaporator (55) and is in contact with the surface of the outlet pipe (101).

  In the present embodiment, the piping part (103a) sandwiched between the two valves, the electromagnetic valve (45) and the liquid side closing valve (75), is positioned beyond the liquid side closing valve (75). Part (103b)) is provided with a second bypass path (95) for bypassing. The piping part (103b) is a part of a piping system that connects the outlet of the condenser (40) and the inlet of the expansion valve (50).

<Bypass path>
-First bypass (90)-
The first bypass passage (90) straddles the gas side shut-off valve (70), and connects the pipe part (102a) to the pipe part (102b) between the gas side shut-off valve (70) and the condenser (40). It is a route to connect. The first bypass passage (90) is provided with a fusible plug (80). The fusible plug (80) is a screw-shaped part with a through hole filled with a low melting point metal. When the supplied fluid (refrigerant in this example) exceeds a predetermined temperature, the low melting point metal melts. Thus, fluid can pass through the through hole. Specifically, the fusible plug (80) is formed with a screw so that two pipes can be connected to each other, and in the absence of the low melting point metal, fluid can flow from one pipe to the other, The through hole is formed.

  In this embodiment, the fusible stopper (80) is provided in the first bypass passage (90), and when the temperature of the refrigerant in the pipe portion (102a) exceeds a predetermined value, the low melting point metal is melted, The refrigerant in the pipe part (102a) flows through the pipe part (102b) between the gas side shut-off valve (70) and the condenser (40). The operating temperature of the fusible plug (80) in the first bypass passage (90) (the temperature at which the low melting point metal melts) is such that the refrigerant pressure in the pipe section (102a) is the maximum allowable pressure in the pipe section (102a). In this case, the temperature is set lower than the refrigerant temperature. In the first bypass passage (90), a filter (90a) is provided on the downstream side of the fusible plug (80) (the side closer to the piping portion (102b)). This filter (90a) captures the low melting point metal melted when the fusible plug (80) is activated.

-Second bypass (95)-
The second bypass path (95) straddles the liquid side shut-off valve (75) and connects the pipe part (103a) to the pipe part (103b) between the liquid side shut-off valve (75) and the condenser (40). It is a route to connect.

  The second bypass path (95) is provided with a fusible plug (80). The fusible plug (80) of the second bypass passage (95) has the same structure as that of the first bypass passage (90). In the present embodiment, when the temperature of the refrigerant in the pipe portion (103a) exceeds a predetermined value, the low melting point metal in the fusible plug (80) of the second bypass passage (95) is melted and the pipe portion ( The refrigerant in 103a) is caused to flow through a pipe part (103b) between the liquid side shut-off valve (75) and the condenser (40). The operating temperature of the fusible plug (80) in the second bypass passage (95) (the temperature at which the low melting point metal melts) is such that the refrigerant pressure in the pipe section (103a) is the maximum allowable pressure in the pipe section (103a). In this case, the temperature is set to be lower than the refrigerant temperature. In the second bypass passage (95), a filter (95a) is provided on the downstream side of the fusible plug (80) (the side closer to the piping portion (103b)). The filter (95a) captures the low melting point metal melted when the fusible plug (80) is activated.

<Operation in liquid seal state>
In the air conditioner (10), when performing maintenance or repair, the compressor (31, 31) is operated and the refrigerant in the refrigerant circuit (20) is accommodated in the condenser (40), so-called pump-down operation. Is done manually. In this manual pump-down operation, the refrigerant is accommodated in the condenser (40) by operating the compressor (31, 31) with the liquid side closing valve (75) closed, and then the gas side closing valve (70 ) To close the refrigerant in the condenser (40).

  At the end of this manual pump-down operation, although the refrigerant remains in the pipe (102a) or in the pipe (102b), the operator accidentally operates the gas-side shut-off valve (70) or electromagnetic When the valve (45) is operated, there is a possibility that the liquid refrigerant may be confined in the pipe part (102a), that is, a so-called liquid seal state may occur. For example, when the compressor (31, 31) is stopped with the liquid side shut-off valve (75) closed and the gas side shut-off valve (70) open, depending on conditions such as the ambient temperature of the pipe (102), There is a possibility that the refrigerant in the condenser (40) moves to the pipe (102). In such a case, if the operator closes the gas side shut-off valve (70) after a certain amount of time has passed since the compressor (31, 31) was stopped, the pipe part (102a) may be in a liquid-sealed state. There is sex.

  However, in the present embodiment, the refrigerant circuit (20) is protected by the fusible plug (80) provided in the bypass passage (90, 95) even when the liquid seal state is reached.

  For example, it is assumed that the piping part (102a) is in a liquid sealed state. In this state, when the temperature of the liquid refrigerant remaining in the pipe part (102a) rises for some reason, the refrigerant vaporizes and the pressure in the pipe part (102a) rises. However, in this embodiment, the fusible plug (80) is activated (that is, the low melting point metal is melted) before the pressure in the pipe part (102a) exceeds the maximum allowable pressure of the pipe part (102a), and the pipe The refrigerant in the section (102a) flows into the pipe section (102b). As a result, the temperature and pressure in the pipe part (102a) are reduced, and the pipe part (102a), that is, the refrigerant circuit (20) is protected.

  Further, in the air conditioner (10), when the operation is stopped (that is, when the compressor (31, 31) is stopped), a predetermined operation operation (hereinafter, referred to as “liquid refrigerant” in the evaporator (55)) is eliminated. For convenience of explanation, this is called automatic pump down operation). This automatic pump-down operation is automatically performed when the user instructs the air conditioner (10) to stop the operation. Specifically, in the automatic pump-down operation, the compressor (31, 31) is operated for a while until the liquid refrigerant in the evaporator (55) runs out with the solenoid valve (45) closed, and then the compressor ( 31,31) is stopped. The gas side closing valve (70) and the liquid side closing valve (75) are normally open.

  However, after the automatic pump-down operation is performed and the compressor (31, 31) is stopped, if the operator accidentally operates the gas-side shutoff valve (70) or the liquid-side shutoff valve (75), There is a case. For example, if the operator accidentally closes the gas-side stop valve (70) after the compressor (31, 31) is stopped, the pipe (102a) may be liquid-sealed depending on conditions such as the temperature of the pipe (102). There is a possibility of becoming a state. In this case, the piping part (102a) is protected by the fusible plug (80) of the first bypass path (90).

  If the operator accidentally closes the liquid side shut-off valve (75) after the automatic pump-down operation has been performed and the compressor (31, 31) has stopped, the solenoid valve (45) is closed. The piping part (103a) may be in a liquid-sealed state. Thus, even if the piping part (103a) is in a liquid-sealed state and the temperature of the liquid refrigerant rises, the fusible plug (80) provided in the second bypass passage (95) operates. Thus, the piping part (103a) is protected.

  Even if any of the fusible plugs (80) is activated, the refrigerant circuit (20) can be operated as usual. For example, during operation of the refrigerant circuit (20), the gas side shut-off valve (70) is in an open state, so that the fusible plug (80) of the first bypass passage (90) is activated and the first bypass passage (90 ), The pipe part (102a) and the pipe part (102b) are connected, but the first bypass path (90) exists in parallel with the path through which the refrigerant flows during normal operation. The operation of (80) does not affect the operation of the refrigerant circuit (20). Further, since the liquid side shut-off valve (75) is opened during the operation of the refrigerant circuit (20), the fusible plug (80) of the second bypass passage (95) is activated to connect the piping part (103a) and the piping. Even if the unit (103b) is connected, the refrigerant circuit (20) can still operate normally.

<Effect in this embodiment>
As described above, according to the present embodiment, the refrigerant circuit (20) in the liquid-sealed state can be protected by the fusible plug (80). The fusible plug (80) is very inexpensive compared to a pressure regulating valve that is a general pressure regulating means, and in this embodiment, it is possible to suppress an increase in cost for protecting the refrigerant circuit (20). become.

  In the present embodiment, the refrigerant circuit (20) can be operated as usual even after the fusible plug (80) is activated. Therefore, for example, even if the fusible plug (80) is activated after leaving the port in a ship air conditioner (10), the air conditioner (10) can be used without performing an exchange operation during voyage. Convenience is great.

<< Embodiment 2 of the Invention >>
FIG. 2 is a schematic configuration diagram of an air-conditioning apparatus (10) according to Embodiment 2 of the present invention. In the air conditioner (10) of the second embodiment, the gas side closing valve (70) and the liquid side closing valve (75) of the first embodiment are replaced with three-way valves. Also in this embodiment, the gas side closing valve (70) and the liquid side closing valve (75) are manually operated valves.

  The first bypass path (90) has one end connected to the gas side shut-off valve (70) and the other end connected to the pipe section (102b). The second bypass passage (95) has one end connected to the liquid side shut-off valve (75) and the other end connected to the pipe section (103b). And the three-way valve for the gas side shut-off valve (70) allows the flow between the pipe part (102a) and the first bypass path (90) while allowing the flow between the pipe part (102a) and the pipe part (102b). Switching between the first state for blocking and the second state for blocking the flow between the pipe part (102a) and the pipe part (102b) while allowing the flow between the pipe part (102a) and the first bypass path (90). It is like that. In this embodiment, the gas side shut-off valve (70) is in the first state (both open state) to allow the flow between the pipe part (102a) and the pipe part (102b) during operation of the refrigerant circuit (20). Is called). That is, the gas side closing valve (70) of the present embodiment is also an example of the manual valve of the present invention.

  The three-way valve for the liquid side shutoff valve (75) allows the flow between the pipe part (103a) and the second bypass path (95) while allowing the flow between the pipe part (103a) and the pipe part (103b). Switching between the first state for blocking and the second state for blocking the flow between the pipe part (103a) and the pipe part (103b) while allowing the flow between the pipe part (103a) and the second bypass path (95). It is like that. During operation of the refrigerant circuit (20), the state is switched to the first state (also referred to as an open state) so as to allow the flow between the pipe part (103a) and the pipe part (103b). That is, the liquid side closing valve (75) of the present embodiment is also an example of the manual valve of the present invention.

<Operation in liquid seal state>
Even in the air conditioner (10) of the second embodiment, the fusible plug (90, 95) provided in the bypass passage (90, 95) even if the liquid is in a sealed state in the case of the manual pump down operation or the automatic pump down operation. 80) protects the refrigerant circuit (20).

  For example, it is assumed that the piping part (102a) is in a liquid sealed state. In this case, it should be in the 2nd state which interrupts the flow between piping part (102a) and piping part (102b), allowing flow between piping part (102a) and the 1st bypass way (90). is there. In this state, even if the pressure in the piping part (102a) rises for some reason, in this embodiment, before the pressure in the piping part (102a) exceeds the maximum allowable pressure of the piping part (102a), The fusible plug (80) is activated, and the refrigerant in the pipe part (102a) is caused to flow to the pipe part (102b) via the gas-side stop valve (70) and the first bypass passage (90). As a result, the pressure in the pipe part (102a) decreases, and the pipe part (102a), that is, the refrigerant circuit (20) is protected. Similarly, even when the pipe part (103a) is in a liquid-sealed state, the liquid side shut-off valve (75) and the second side valve (80) are activated by the operation of the fusible plug (80) provided in the second bypass path (95). The refrigerant in the pipe part (103a) is caused to flow through the pipe part (103b) via the bypass path (95), and the pipe part (103a) is protected.

  Therefore, the same effects as in the first embodiment can be obtained in this embodiment.

<< Embodiment 3 of the Invention >>
In the third embodiment, a configuration that facilitates replacement of the fusible plug (80) will be described. FIG. 3 is a schematic configuration diagram of the first and second bypass paths (90, 95) according to the third embodiment of the present invention. In this example, as shown in FIG. 3, the first bypass passage (90) is provided with two check valves (205, 206). Specifically, a check valve (205) is provided between the fusible plug (80) and the pipe part (102a). The check valve (205) is connected to the pipe part (102a) from the fusible plug (80). Blocks the flow of refrigerant in the direction toward. Further, a check valve (206) is provided between the filter (90a) and the pipe part (102b), and the check valve (206) is directed from the pipe part (102b) to the fusible plug (80). Block the refrigerant flow.

  Further, as shown in FIG. 3, the second bypass passage (95) is also provided with two check valves (205, 206). Specifically, a check valve (205) is provided between the fusible plug (80) and the pipe portion (103a), and the check valve (205) of the second bypass passage (95) ) Is blocked from flowing in the direction from the pipe to the pipe section (103a). A check valve (206) is provided between the filter (95a) and the piping part (103b), and the check valve (206) of the second bypass passage (95) can be connected to the piping part (103b). Shut off the flow of refrigerant in the direction toward the plug (80).

<Replacement of fusible stopper>
When any of the fusible plugs (80) needs to be replaced, first, a pump-down operation is performed to collect the refrigerant in the condenser (40), and the gas-side shut-off valve (70) and Close the liquid side closing valve (75). Even if the fusible plug (80) is removed in this state, the check valve (205, 206) prevents the refrigerant from leaking out. That is, in this embodiment, the work for replacing the fusible plug (80) can be easily performed.

<Effect in this embodiment>
As described above, in the present embodiment, the fusible plug (80) can be easily replaced without removing the refrigerant from the refrigerant circuit (20) one by one.

<< Other Embodiments >>
In addition, the pressure adjustment mechanism of the liquid sealing part demonstrated in Embodiment 1 or Embodiment 2 is applicable also to refrigerant circuits other than an air conditioning apparatus.

  The present invention is useful as a refrigeration apparatus.

DESCRIPTION OF SYMBOLS 10 Air conditioning apparatus 20 Refrigerant circuit 31 Compressor 31b Discharge port 35 Check valve 40 Condenser 45 Electromagnetic valve 50 Expansion valve 55 Evaporator 70 Gas side closing valve (closing valve)
75 Liquid side closing valve (closing valve)
80 fusible plug 90 first bypass path 95 second bypass path 102a piping section 103a piping section 205 check valve 206 check valve

Claims (4)

In a refrigeration apparatus comprising a refrigerant circuit (20) having a compressor (31, 31), a condenser (40), an expansion valve (50), and an evaporator (55) and circulating a refrigerant,
The refrigerant circuit (20) has a pipe part (102a, 103a) sandwiched between two valves,
At least one of the two valves is a manual valve (70,75) that is manually operated and is opened during operation of the refrigerant circuit (20);
The refrigerant circuit (20) is provided with a bypass path (90, 95) for bypassing the pipe portion (102a, 103a) to a position beyond the manual valve (70, 75).
A refrigerating apparatus in which a fusible plug (80) is provided in the bypass passage (90, 95). In claim 1,
The piping section (102a, 103a) is a part of a piping system that connects the discharge port (31b, 31b) of the compressor (31, 31) and the refrigerant inlet of the condenser (40),
One of the two valves is a check valve (35) provided on the discharge port (31b, 31b) side of the compressor (31, 31), and the other is a refrigerant inlet of the condenser (40). A refrigeration apparatus comprising a closing valve (70) provided on a side and manually operated. In claim 1 or claim 2,
The piping part (103a) is a part of a piping system that connects the outlet of the condenser (40) and the inlet of the expansion valve (50),
One of the two valves is a closing valve (75) that is provided on the outlet side of the condenser (40) and is manually operated, and the other is provided on the inlet side of the expansion valve (50). A refrigeration apparatus comprising a solenoid valve (45). In any one of Claims 1-3,
The bypass passage (90, 95) is provided with a check valve (206) for preventing the refrigerant from flowing out from the pipe portion (102a, 103a) to the fusible plug (80). Refrigeration equipment.

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