JPH08261572A - Freezing device - Google Patents

Abstract

PURPOSE: To reduce a passing sound of refrigerant at a bypass mechanism so as to decrease low noise state. CONSTITUTION: There is provided a refrigerant circuit 20 in which a compressor 21, a condensor 22, a thermo-sensitive type expansion valve valve 25 and a cascade condensor 26 are connected in series. There is also provided a bypass mechanism 40 connected to a discharging side and a suction side of the compressor 21 so as to cause a part of the discharged refrigerant of the compressor 21 to be bypassed to the suction side. The bypass mechanism 40 is constructed such that a capillary tube 42 for use in reducing pressure of the bypassed refrigerant and a rated pressure type expansion valve 43 opened when a suction side refrigerant pressure of line compressor 21 becomes a predetermined value or less to control a flow rate of fir bypassed refrigerant are arranged in sequence in a bypass passage 41 from their upstream side.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refrigeration system, and more particularly to a bypass mechanism for controlling the capacity of a compressor.

[0002]

2. Description of the Related Art Conventionally, a refrigerating apparatus has been disclosed in JP-A-5-21.
5412, the compressor (a), the condenser (b), the expansion mechanism (c), the evaporator (d), and the accumulator (e) are disclosed as shown in FIG.
And are connected in order and configured. The refrigerant compressed by the compressor (a) is liquefied by the condenser (b) and then decompressed by the expansion mechanism (c), and then the decompressed refrigerant is evaporated and compressed by the evaporator (d). Returning to the machine (a), this circulation is repeated to perform the cooling action in the evaporator (d).

On the other hand, in the refrigerating apparatus, a constant capacity type is used as the compressor (a), and a bypass mechanism (f) is provided to control the capacity of the compressor (a).
This bypass mechanism (f) is provided with a constant pressure expansion valve (h) provided in the bypass passage (g), and the pressure introduction pipe (i) of the constant pressure expansion valve (h) is on the suction side of the compressor (a). It is connected between an accumulator (e) and a compressor (a). Then, when the suction side refrigerant pressure of the compressor (a) becomes equal to or lower than a predetermined value, the constant pressure expansion valve (h) opens and bypasses a part of the discharge refrigerant of the compressor (a) to the suction side for compression. The capacity of the machine (a) is controlled.

FIG. 11 shows another conventional example of the bypass mechanism (f), which is disclosed in JP-A-5-215412. The bypass mechanism (f) is opened and closed in the bypass passage (g). A solenoid valve (j) that is a valve and a capillary tube (k) are provided and configured. When the pressure sensor (m) for detecting the suction side refrigerant pressure of the compressor (a) detects a predetermined value or less, the solenoid valve (j) opens and a part of the refrigerant discharged from the compressor (a). Is bypassed to the suction side to control the capacity of the compressor (a).

[0005]

In the refrigeration system described above, since the bypass mechanism (f) for controlling the capacity of the compressor (a) is composed of one bypass passage (g), the constant pressure expansion valve ( h) and capillary tube (k)
However, there is a problem that the sound of passing the refrigerant is large.

In other words, when only one constant pressure expansion valve (h) is provided, there is no problem when the flow rate of the bypass refrigerant is small, but when the flow rate of the bypass refrigerant increases, the valve opening amount causes the bypass passage ( Since it is smaller than the cross-sectional area of g), the flow velocity of the refrigerant becomes too high, and there is a problem that the passing noise of the refrigerant is large. Further, also in the capillary tube (k), there is a problem that the sound of refrigerant passing through is large, as in the constant pressure expansion valve (h).

The present invention has been made in view of the above problems, and an object of the present invention is to reduce the passing noise of the refrigerant in the bypass mechanism to reduce the noise.

[0008]

[Means for Solving the Problems] In order to achieve the above object, the means taken by the present invention is to reduce the pressure of the bypass refrigerant or to divert the bypass refrigerant.

Specifically, as shown in FIG. 1, the means taken by the invention according to claim 1 is to use the compressor (21), the heat source side heat exchanger (22), the expansion mechanism (25) and the like. Side heat exchanger (2
It is premised on a refrigeration system provided with a refrigerant circuit (20) in which 6) and 6 are connected in sequence. A bypass mechanism (40) is provided which is connected to the discharge side and the suction side of the compressor (21) and bypasses a part of the refrigerant discharged from the compressor (21) to the suction side. Further, the bypass mechanism (40) opens when the throttle portion (42) for lowering the pressure of the bypass refrigerant and the suction side refrigerant pressure of the compressor (21) become equal to or lower than a predetermined value, and the flow rate of the bypass refrigerant is increased. Flow control valve for controlling (4
3) and 3) are arranged in the bypass passage (41) in order from the upstream side.

In the means taken by the invention according to claim 2, the compressor (21), the heat source side heat exchanger (22), the expansion mechanism (25) and the use side heat exchanger (26) are It is premised on a refrigeration system including a refrigerant circuit (20) connected in order. A bypass mechanism (40) is provided which is connected to the discharge side and the suction side of the compressor (21) and bypasses a part of the refrigerant discharged from the compressor (21) to the suction side. Furthermore,
The bypass mechanism (40) includes a plurality of bypass passages (44, 45, ...) Which divide the refrigerant to bypass it. In addition, the bypass passages (44, 45, ...) Are connected to the compressor (2
Flow control means (4C) for controlling the flow rate of the bypass refrigerant by communicating when the suction side refrigerant pressure in 1) becomes less than or equal to a predetermined value.
Is provided.

The means taken by the invention according to claim 3 is the flow control means (4C) according to the invention of claim 2 above.
Is constituted by a flow rate control valve (43) that opens to control the flow rate of the bypass refrigerant when the suction side refrigerant pressure of the compressor (21) becomes less than or equal to a predetermined value, and means provided by the invention according to claim 4. In the invention according to claim 2, the flow control means (4C) includes an opening / closing valve (46) which opens when the suction side refrigerant pressure of the compressor (21) becomes a predetermined value or less, and the opening / closing valve (46). It is composed of a diaphragm portion (47) provided in series.

Further, the means taken by the invention according to claim 5 is the flow control means in a part of the bypass passages (44, 45, ...) Of the plurality of bypass passages (44, 45, ...) In the invention according to claim 2. (4C) is composed of a flow rate control valve (43) that opens to control the flow rate of the bypass refrigerant when the suction side refrigerant pressure of the compressor (21) falls below a predetermined value, while the other bypass passage (45) The flow rate control means (4C) in (1), the opening / closing valve (46) that opens when the suction side refrigerant pressure of the compressor (21) becomes a predetermined value or less, and the throttle section (47) provided in series with the opening / closing valve (46). ) And is composed of.

The means taken by the invention according to claim 6 is the refrigerant circuit (20) according to the inventions of claims 1 to 5.
Is the high temperature side refrigerant circuit (20), and the use side heat exchanger (2
While 6) consists of a cascade capacitor (26),
The compressor (31), the cascade condenser (26), the expansion mechanism (33) and the evaporator (34) are connected in this order to a low temperature side refrigerant circuit (30).

[0014]

With the above construction, in the invention according to claim 1,
The refrigerant compressed by the compressor (21) is the heat source side heat exchanger (22).
After being liquefied in, the expansion mechanism (25) reduces the pressure, and the reduced pressure refrigerant evaporates in the utilization side heat exchanger (26) and the compressor (2
Return to 1) and repeat this cycle. Particularly, in the invention according to claim 6, the use side heat exchanger (26) is a cascade condenser (26), and in the low temperature side refrigerant circuit (30), the refrigerant compressed by the compressor (31) is a cascade condenser (26). After being liquefied in 26), it is decompressed in the expansion mechanism (33), and the decompressed refrigerant is evaporated in the evaporator (34) and returned to the compressor (31) to repeat this circulation.

When the suction side refrigerant pressure of the compressor (21) drops below a predetermined value during the refrigerant circulation, the flow control valve (43) of the bypass mechanism (40) opens,
A part of the refrigerant discharged from the compressor (21) is bypassed to the suction side of the compressor (21) to reduce the capacity of the compressor (21). The flow rate control valve (43) controls the flow rate of the bypass refrigerant by increasing or decreasing the valve opening amount according to the decrease amount of the suction side refrigerant pressure.
Controls the capacity of the compressor (21). During the bypass of the discharged refrigerant, the pressure of the bypass refrigerant is first reduced in the throttle portion (42), and then the flow rate is controlled by the flow rate control valve (43).

After that, when the suction side refrigerant pressure of the compressor (21) rises and becomes higher than a predetermined value, the flow control valve (43) of the second bypass mechanism (40) is fully closed and the compressor (21 )
Increase the capacity of.

Further, in the invention according to claim 2, when the suction side refrigerant pressure of the compressor (21) decreases, first, the flow rate control means (4C) of the one bypass passage (44) controls the flow rate of the bypass refrigerant. Then, a part of the refrigerant discharged from the compressor (21) is bypassed to the suction side. Furthermore, when the suction side refrigerant pressure decreases,
The flow rate control means (4C) of the other bypass passage (45) controls the flow rate of the bypass refrigerant to bypass a larger amount of the refrigerant discharged from the compressor (21) to the suction side.

Specifically, in the invention according to claim 3, when the suction side refrigerant pressure of the compressor (21) falls below a predetermined value, first, the flow control valve (43) of one bypass passage (44) is opened. After that, when the suction side refrigerant pressure further decreases to a predetermined value, the flow rate control valve (43) of the other bypass passage (45) opens, and the bypass refrigerant has a plurality of bypass passages (44, 45, ...).
Will be diverted to.

Further, in the invention according to claim 4, when the suction side refrigerant pressure of the compressor (21) falls below a predetermined value, first, after the opening / closing valve (46) of the bypass passage (44) of one is opened, Further, when the suction side refrigerant pressure decreases to a predetermined value, the opening / closing valve (46) of the other bypass passage (45) opens, and the bypass refrigerant is diverted to the plurality of bypass passages (44, 45, ...).

Further, in the invention according to claim 5, when the suction side refrigerant pressure of the compressor (21) falls below a predetermined value, first, the flow control valve (43) of the bypass passage (44) of one is opened. , Further, when the suction side refrigerant pressure drops to a predetermined value, the opening / closing valve (46) of the other bypass passage (45) opens,
The bypass refrigerant is divided into a plurality of bypass passages (44, 45, ...).

[0021]

Therefore, according to the first and sixth aspects of the invention, the bypass mechanism (40) is provided with the throttle portion (42) and the flow rate control valve (43) in order from the upstream side. Since the pressure of the bypass refrigerant can be reduced by the throttle portion (42), the speed of the refrigerant passing through the flow rate control valve (43) can be reduced. As a result, the noise of the refrigerant passing through the flow rate control valve (43) can be reduced, so that the noise can be reduced.

Further, since the capacity of the flow rate control valve (43) can be increased, the valve opening amount can be increased and the refrigerant passage speed can be surely reduced, so that the noise can be surely reduced. Can be achieved.

Further, the flow rate control valve (43) having a large capacity described above.
It is possible to prevent the capacity control accuracy of the compressor (21) from deteriorating when the compressor is used. That is, when the single flow rate control valve (43) having a large capacity is provided without providing the throttle portion (42), the valve opening amount is large, the control accuracy is rough, and the capacity of the compressor (21) is minute. Cannot be controlled. On the other hand, in the invention of claim 1, since the refrigerant pressure is reduced by the throttle portion (42), the flow control valve (4) having a large valve opening amount.
Even if 3) is used, it is possible to prevent the control accuracy from deteriorating, and it is possible to precisely control the capacity of the compressor (21).

Further, according to the second aspect of the present invention, since the plurality of bypass passages (44, 45, ...) Are provided, the bypass refrigerant can be diverted, so that the respective bypass passages (44, 45) are provided. , ...) can reduce the flow rate of the bypass refrigerant, and as a result, the flow rate control means (4C)
It is possible to reduce the passing sound of the refrigerant.

Specifically, according to the inventions of claims 3 and 5, the refrigerant passing sound in the flow rate control valve (43) can be reduced, and according to the invention of claim 4, Since it is possible to reduce the refrigerant passing sound in the throttle portion (42), it is possible to reduce noise.

[0026]

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

-Overall Structure-As shown in FIG. 2, (10) is a refrigerating apparatus applied to a freezer, and a plurality of indoor units (12, 12) are provided for one outdoor unit (11). , ...) are connected to form a so-called multi-type, and a dual refrigeration cycle including a high temperature side refrigerant circuit (20) and a low temperature side refrigerant circuit (30) is formed.

As shown in detail in FIG. 3, the outdoor unit (11) is provided with a heat source side circuit section (20-H) which constitutes a part of the high temperature side refrigerant circuit (20), and the heat source side circuit is provided. Department (20-
H) is a refrigerant pipe (2L) in which a condenser (22) which is a heat source side heat exchanger and a receiver (23) are arranged on the discharge side of the compressor (21) in this order.
And the accumulator (24) is connected to the suction side of the compressor (21) by a refrigerant pipe (2L).

On the other hand, each indoor unit (12, 12, ...)
Have the same configuration, and as shown in detail in FIG. 4, the use-side circuit section (20-
U) and the low temperature side refrigerant circuit (30) are mounted, and the use side circuit part (20-U) includes a temperature sensitive expansion valve (25) and a cascade condenser (26) which is a use side heat exchanger. Refrigerant piping (2L)
Are connected and configured by. And, the use side circuit section (20-U) of each indoor unit (12, 12, ...)
The high temperature side refrigerant circuit (20) is configured by being connected in parallel to the heat source side circuit section (20-H) of the outdoor unit (11) via the closing valves (2V, 2V).

The temperature-sensitive expansion valve (25) includes a pressure equalizing pipe (25-
E) Cascade capacitor (2 via solenoid valve (SV-1)
6) is connected to the downstream side refrigerant pipe (2L), and the temperature sensing tube (25-T) is attached to the downstream side refrigerant pipe (2L) of the cascade condenser (26).
The opening degree is controlled so that the superheat degree of the outlet side refrigerant becomes a predetermined value. The solenoid valve (SV-1) is the expansion valve (25).
Of the solenoid valve (SV-1) connected to the upstream refrigerant pipe (2L) of
The high-pressure refrigerant acts on the expansion valve (25) by the ON operation of, and the expansion valve (25) is fully closed by the high-pressure refrigerant.

The low temperature side refrigerant circuit (30) includes a compressor (3
1), four-way switching valve (32), and cascade condenser (26)
The temperature-sensitive expansion valve (33), the evaporator (34), and the accumulator (35) are sequentially connected by the refrigerant pipe (3L). In the temperature-sensitive expansion valve (33), the temperature-sensitive cylinder (33-T) is attached to the refrigerant pipe (2L) on the downstream side of the evaporator (34), and the refrigerant on the outlet side of the evaporator (34) is overheated. The opening is controlled so that the degree becomes a predetermined value. In the indoor unit (12, 12, ...), the evaporator (34) of the low temperature side refrigerant circuit (30) is installed in the inside (12-i), and other compressors (21) and use side circuits are included. Part (20-U) is installed outside (12-t).

-Structure of Auxiliary Circuit- Between the downstream refrigerant pipe (2L) of the receiver (23) and the upstream refrigerant pipe (2L) of the accumulator (24) in the outdoor unit (11), an injection passage ( 2i) is connected. The injection passage (2i) includes a temperature-sensitive expansion valve (TV), and the temperature-sensitive expansion valve (TV) has a pressure equalizing pipe (TV-E) on a suction side refrigerant pipe (2L) of a compressor (21). And a temperature sensing tube (TV-T) is attached to the suction side refrigerant pipe (2L) of the compressor (21). The injection passage (2i) controls the opening degree of the expansion valve (TV) so that the superheat degree of the suction side refrigerant of the compressor (21) reaches a predetermined value (for example, 3 ° C.), and the compressor ( The amount of liquid refrigerant supplied to the suction refrigerant in 21) is adjusted.

On the other hand, between the discharge side refrigerant pipe (3L) of the compressor (31) and the upstream side refrigerant pipe (3L) of the evaporator (34) in the indoor unit (12, 12, ...) Defrost. The hot gas passage (3d) is connected. The hot gas passage (3d) includes a solenoid valve (SV-2) and a capillary tube (CP-2). For example, the solenoid valve (SV-
2) is opened to supply hot gas to the evaporator (34) to remove frost from the evaporator (34).

A hot gas passage (3h) for the drain pan heater is connected between the four-way switching valve (32) and the refrigerant pipe (3L) on the upstream side of the evaporator (34). The hot gas passage (3h) has a solenoid valve (SV-3) and a capillary tube (CP).
-3) and a drain pan heater (DH). For example, in synchronization with the defrost operation, a solenoid valve (SV-3) is opened to supply hot gas to the drain pan heater (DH) to remove the frost from the drain pan. I am trying to do it. The four-way switching valve (32) is connected to the suction side refrigerant pipe (3L) of the compressor (21) via a check valve (CV).

An injection passage (3i) is connected between the compressor (31) and the refrigerant pipe (3L) on the downstream side of the cascade condenser (26). The injection passage (3i) includes a solenoid valve (SV-4) and a capillary tube (CP-4). When the discharge side refrigerant temperature of the compressor (31) rises excessively, the solenoid valve (SV-4) is turned on. The opening is opened to supply the liquid refrigerant to the compressor (31) to lower the discharge side refrigerant temperature.

-Structure of Pressure Switch-The discharge side refrigerant pipe (2L) of the compressor (21) in the outdoor unit (11) has a discharge side refrigerant pressure of the compressor (21) (hereinafter referred to as high pressure). ) Is excessively raised, the pressure switch (HPS1) for high pressure protection that turns on and activates the protective device
In the downstream refrigerant pipe (2L) of the accumulator (24), when the suction side refrigerant pressure of the compressor (21) (hereinafter referred to as low pressure LP) is excessively lowered, it is turned on to operate the protective device. Switch (LPS1) is the accumulator (24)
The low-pressure control pressure switch (LPS2), which is turned on when the low-pressure pressure LP drops to a predetermined low pressure and outputs a low-pressure signal, is provided in each of the upstream refrigerant pipes (2L).

The discharge side refrigerant pipe (3L) of the compressor (31) in the low temperature side refrigerant circuit (30) of the indoor unit (12, 12, ...) Has a discharge side refrigerant pressure (high pressure) of the compressor (31). Pressure switch (HPS2) for turning on the protective device when the pressure rises excessively, and the high pressure of the compressor (31) rises to a predetermined high pressure in the hot gas passage (3h) for the drain pan heater. Then, the solenoid valve (SV of the hot gas passage (3h)
-3) The first defrost control high-pressure pressure switch (HPS3) that closes the defrost to close the defrost when the high-pressure pressure rises to a predetermined high pressure in the discharge side refrigerant pipe (3L) of the compressor (31). Solenoid valve (SV-2) for hot gas passage (3d)
The second defrost control high-pressure switch (HPS4) that closes the valve and ends the defrost is turned on when the high-pressure pressure rises to a predetermined high pressure in the refrigerant pipe (3L) on the upstream side of the cascade condenser (26). High pressure control pressure switches (HPS5) that output signals are provided.

-Compressor capacity control configuration-High temperature side refrigerant circuit (20) in the outdoor unit (11)
Includes a first bypass mechanism (2b) and a second bypass mechanism (4
0) and are provided. The first bypass mechanism (2b)
Is the unload mechanism (not shown) of the compressor (21) at one end of the bypass passage (2w) equipped with the solenoid valve (SV-5), and the other end is the upstream refrigerant pipe (2L) of the accumulator (24). Respectively connected to. Further, one end of a pilot passage (2p) equipped with a capillary tube (CP-5) is connected to the bypass passage (2w), and the other end of the pilot passage (2p) is discharged from the compressor (21). It is connected to the side refrigerant pipe (2L).

Although not shown, the pilot passage (2p) closes the unload valve of the compressor (21), while the solenoid valve (SV-5) controls the low pressure of the low pressure control pressure switch (LPS2). When the low pressure LP of the compressor (21) drops to a predetermined low pressure value based on the signal, it opens and bypasses part of the high pressure refrigerant from the unload mechanism of the compressor (21) to the suction side of the compressor (21). It is configured to reduce the capacity of the compressor (21).

On the other hand, the second bypass mechanism (40) is a feature of the present invention, in which the capillary tube (42) and the constant pressure expansion valve (43) are arranged in the bypass passage (41) in order from the upstream side. It is provided and configured. The bypass passage (41) has one end connected to the discharge side refrigerant pipe (2L) of the compressor (21) and the other end connected to the upstream side refrigerant pipe (2L) of the accumulator (24). A part of the refrigerant discharged from (21) is bypassed to the suction side of the compressor (21) to reduce the capacity of the compressor (21).

The capillary tube (42) constitutes a throttle portion for reducing the pressure of the bypass refrigerant. That is, the capillary tube (42) is set to a throttle amount that reduces only the pressure without significantly changing the flow rate of the bypass refrigerant.

The constant pressure expansion valve (43) is provided with a pressure introducing pipe (43
-P) is connected to the refrigerant pipe (2L) on the downstream side of the accumulator (24) and starts to open when the low pressure LP of the compressor (21) drops to a predetermined operating set value, and the low pressure LP for that operating set value. A flow rate control valve that controls the flow rate of the bypass refrigerant by increasing or decreasing the valve opening amount in accordance with the decrease amount of
Further, the constant pressure expansion valve (43) has a larger capacity (for example, about 5 times) as compared with the conventional one, that is, the valve opening diameter is set larger than the conventional one, and the passage speed of the refrigerant becomes smaller. Is configured.

The operation set value of the constant pressure expansion valve (43) of the second bypass mechanism (40) is determined by the first bypass mechanism (2b).
Of the solenoid valve (SV-5) of the compressor is set higher than a predetermined low pressure value that opens, that is, the second bypass mechanism (40) comes first to the compressor (2
It is set to start bypassing the refrigerant discharged in 1).

-Refrigeration Operation- Next, the refrigeration operation of the refrigeration system (10) will be described.

First, in the high temperature side refrigerant circuit (20), the refrigerant compressed by the compressor (21) is liquefied by the condenser (22) and then decompressed by the expansion valve (25). It is evaporated in the cascade condenser (26) and returned to the compressor (21), and this circulation is repeated. In the cascade condenser (26), the low temperature side refrigerant circuit (30)
The cooling medium will be cooled.

On the other hand, in the low temperature side refrigerant circuit (30), the refrigerant compressed by the compressor (31) is liquefied by the cascade condenser (26) and then decompressed by the expansion valve (33). Is evaporated in the evaporator (34) and the compressor (3
Return to 1) and repeat this cycle. In the cascade condenser (26), the refrigerant in the low temperature side refrigerant circuit (30) is cooled by the cooling action of the high temperature side refrigerant circuit (20), while in the evaporator (34), inside the freezer (12-i). Will be cooled.

Further, in the high temperature side refrigerant circuit (20), for example, the number of operating indoor units (12, 12, ...) Decreases, and the low pressure LP of the compressor (21) decreases to exceed the operating set value. When it becomes lower, first, the second bypass mechanism (4
The constant pressure expansion valve (43) of (0) is opened, and a part of the refrigerant discharged from the compressor (21) is bypassed to the suction side of the compressor (21) to reduce the capacity of the compressor (21). The constant pressure expansion valve (43) increases / decreases the valve opening amount according to the decrease amount of the low pressure LP with respect to the operation set value, controls the flow rate of the bypass refrigerant, and controls the capacity of the compressor (21). During the bypass of the discharged refrigerant, the pressure of the bypass refrigerant is first reduced in the capillary tube (42), and then the flow rate is controlled by the constant pressure expansion valve (43).

When the low pressure LP of the compressor (21) further decreases, the solenoid valve (SV-5) of the first bypass mechanism (2b) is activated based on the low pressure signal of the low pressure control pressure switch (LPS2). A larger amount of the refrigerant discharged from the discharge refrigerant of the compressor (21) is bypassed to the suction side of the compressor (21), and the compressor (21) is opened.
Will reduce the capacity.

After that, when the low pressure LP of the compressor (21) rises and becomes higher than a predetermined low pressure value, first, the solenoid valve (SV-5) of the first bypass mechanism (2b) is closed to close the compressor ( twenty one)
When the low pressure LP of the compressor (21) becomes higher than the operating set value, the second bypass mechanism (40) is increased.
The constant pressure expansion valve (43) is fully closed to increase the capacity of the compressor (21).

-Effects peculiar to the embodiment-As described above, according to this embodiment, the second bypass mechanism (40) includes the capillary tube (42) and the constant pressure expansion valve (43).
Since the and are arranged in order from the upstream side, the pressure of the bypass refrigerant can be reduced by the capillary tube (42), so that the refrigerant velocity passing through the constant pressure expansion valve (43) can be reduced. As a result, the noise of the constant pressure expansion valve (43) passing through the refrigerant can be reduced, so that the noise can be reduced.

Further, since the capacity of the constant pressure expansion valve (43) can be increased, the valve opening amount can be increased and the refrigerant passage speed can be surely reduced, so that the noise can be surely reduced. Can be achieved.

Further, the constant pressure expansion valve (43) having a large capacity described above.
It is possible to prevent the capacity control accuracy of the compressor (21) from deteriorating when the compressor is used. That is, when one constant pressure expansion valve (43) having a large capacity is provided without providing the capillary tube (42), the valve opening amount is large, the control accuracy is rough, and the capacity of the compressor (21) is minute. Cannot be controlled. On the other hand, in the present embodiment, since the refrigerant pressure is reduced by the capillary tube (42), even if the constant pressure expansion valve (43) having a large valve opening amount is used, it is possible to prevent the control accuracy from decreasing. The capacity of the compressor (21) can be precisely controlled.

-Modification 1- FIG. 5 shows a modification of the second bypass mechanism (40) which is an embodiment of the invention of claim 5, and shows only a schematic structure. The second bypass mechanism (40) includes a first bypass passage (44) and a second bypass passage (45) connected in parallel, and the first bypass passage (44) has a flow rate control means (4C).
Is provided with a constant pressure expansion valve (43), and the second bypass passage (45) is connected to the solenoid valve (46) and the capillary tube (47) in series, and the flow rate control means (4) is provided.
C) is provided. The first bypass mechanism (2b) is omitted in FIG.

The constant pressure expansion valve (43) is the same as the conventional one, that is, the one having a smaller capacity than the constant pressure expansion valve (43) of the previous embodiment shown in FIG. 2 is applied. .
The capillary tube (47) controls the flow rate of the bypass refrigerant, and the solenoid valve (46) controls the valve opening set value P1.
And a valve closing set value P2 higher than the valve opening set value P1 are set, and configured to open and close based on the pressure signal of the pressure sensor (LP-S) that detects the low pressure LP of the compressor (21). Has been done.

The operation set value P3 at which the constant pressure expansion valve (43) starts to open is set to the highest value. That is, as shown in FIG. 6, when the low pressure LP of the compressor (21) falls below the operation set value P3, first, the constant pressure expansion valve (43) of the first bypass passage (44) opens, and then When the low pressure LP decreases to the valve opening set value P1, the solenoid valve (46) of the second bypass passage (45) opens, and the bypass refrigerant becomes the first bypass passage (44) and the second bypass passage (45). Shunted to. After that, the low pressure LP is set to the valve closing set value P2.
First, the solenoid valve (46) of the second bypass passage (45) is closed, and then, when the low pressure LP rises to the operation set value P3, the constant pressure expansion valve of the first bypass passage (44) ( 43) is fully closed.

Therefore, the low pressure of the compressor (21)
When LP decreases and the flow rate of the bypass refrigerant increases, the second bypass passage (45) also bypasses the refrigerant discharged from the compressor (21), thereby preventing an increase in the flow rate of the refrigerant passing through the constant pressure expansion valve (43). Therefore, the passing sound of the constant pressure expansion valve (43) can be reduced.

-Modification 2- FIG. 7 is a modification of the second bypass mechanism (40) according to the embodiment of the invention of claim 4, and shows only a schematic structure. The second bypass mechanism (40) includes a first bypass passage (44) and a second bypass passage (45) connected in parallel to each other, and is connected to the first bypass passage (44) and the second bypass passage (45). Is a flow control means (4C) which is composed of a solenoid valve (46) and a capillary tube (47) connected in series.
Is provided. In addition, also in FIG. 7, the first bypass mechanism (2b) is omitted.

Each of the above capillary tubes (47, 47) is
The flow rate of the bypass refrigerant is controlled by the solenoid valves (4
6 and 46) are set with valve opening set values P1 and P3 and valve closing set values P2 and P4 higher than the valve opening set values P1 and P3, respectively, and the suction side refrigerant pipe (2L) of the compressor (21) is set. The pressure sensor (LP-S, LP-S) that detects the refrigerant pressure in (1) is opened and closed based on the pressure signal.

The set values P1 and P2 of the solenoid valve (46) in the first bypass passage (44) are higher than the set values P3 and P4 of the solenoid valve (46) in the second bypass passage (45). It is set. That is, as shown in FIG. 8, when the low pressure LP of the compressor (21) falls below the valve opening set value P1,
First, after the solenoid valve (46) of the first bypass passage (44) is opened, when the low pressure LP further falls below the valve opening set value P3, the solenoid valve (46) of the second bypass passage (45) is opened. By opening, the bypass refrigerant is divided into the first bypass passage (44) and the second bypass passage (45). Then the low pressure
When LP increases to the valve closing set value P2, first, the solenoid valve (46) of the second bypass passage (45) closes, and then when the low pressure LP increases to the valve closing set value P4, the first bypass passage. The solenoid valve (46) of (44) will be closed.

Therefore, when the low pressure LP decreases and the flow rate of the bypass refrigerant increases, the second bypass passage (4
Since 5) also bypasses the refrigerant discharged from the compressor (21),
An increase in the flow rate of the refrigerant passing through each capillary tube (47, 47) can be prevented, and the capillary tube (47, 47) can be prevented.
It is possible to reduce the passing sound of 47).

-Modification 3- FIG. 9 shows a modification of the second bypass mechanism (40) which is an embodiment of the invention of claim 3, and shows only a schematic structure. The second bypass mechanism (40) includes a first bypass passage (44) and a second bypass passage (45) connected in parallel to each other, and is connected to the first bypass passage (44) and the second bypass passage (45). Each of them is provided with a constant pressure expansion valve (43) constituting a flow rate control means (4C). Incidentally, also in FIG.
The first bypass mechanism (2b) is omitted.

The constant pressure expansion valves (43, 43) have different operation set values for starting opening. That is, when the low pressure LP of the compressor (21) falls below the operating set value, first, the constant pressure expansion valve (43) of the first bypass passage (44) is opened, and then the low pressure LP is further operating set. When the pressure falls below the value, the constant pressure expansion valve (43) of the second bypass passage (45) is opened, and the bypass refrigerant flows into the first bypass passage (44) and the second bypass passage (44).
It is divided into the bypass passage (45). After that, when the low pressure LP rises to the operation set value, the constant pressure expansion valve (43) of the second bypass passage (45) is fully closed, and then when the low pressure LP rises to the operation set value, the first bypass. The constant pressure expansion valve (43) in the passage (44) is fully closed.

Therefore, when the low pressure LP decreases and the flow rate of the bypass refrigerant increases, the second bypass passage (4
Since 5) also bypasses the refrigerant discharged from the compressor (21),
It is possible to prevent an increase in the flow rate of the refrigerant passing through each constant pressure expansion valve (43), and reduce the passing noise of the constant pressure expansion valve (43).

-Other Modifications- In the present embodiment, the freezing device (10) of the freezer is described, but it goes without saying that the present invention can be applied to various freezing devices.

In addition, this embodiment uses the high temperature side refrigerant circuit (20).
Although the dual refrigeration cycle is provided with the low temperature side refrigerant circuit (30), it goes without saying that the inventions of claims 1 and 2 may include one refrigerant circuit.

The invention of claim 1 and claim 2 may be a refrigerant circuit equipped with a four-way switching valve and capable of reversible operation.

In the invention according to claims 2 to 5, the number of bypass passages (44, 45) is not limited to two, and three or more may be used.

[Brief description of drawings]

FIG. 1 is a refrigerant circuit diagram showing the configuration of the present invention.

FIG. 2 is a refrigerant circuit diagram of the refrigeration system.

FIG. 3 is a refrigerant circuit diagram of the outdoor unit.

FIG. 4 is a refrigerant circuit diagram of the indoor unit.

FIG. 5 is a refrigerant circuit diagram showing another second bypass mechanism.

FIG. 6 is a characteristic diagram of low-pressure pressure with respect to set values of a constant pressure expansion valve and a solenoid valve.

FIG. 7 is a refrigerant circuit diagram showing another second bypass mechanism.

FIG. 8 is a characteristic diagram of low-pressure pressure with respect to a set value of a solenoid valve.

FIG. 9 is a refrigerant circuit diagram showing another second bypass mechanism.

FIG. 10 is a schematic configuration diagram showing a conventional refrigeration system.

FIG. 11 is a schematic configuration diagram showing another conventional refrigeration system.

[Explanation of symbols]

 10 Refrigerator 20 High-temperature side refrigerant circuit 21, 31 Compressor 22 Condenser 25, 33 Expansion valve 26 Cascade condenser 30 Low-temperature side refrigerant circuit 34 Evaporator 40 Second bypass mechanism 41, 44, 45 Bypass passage 42, 47 Capillary tube ( Throttle part) 43 Constant pressure expansion valve (flow control valve) 46 Solenoid valve (open / close valve)

Claims (6)

[Claims] A refrigeration system comprising a refrigerant circuit (20) comprising a compressor (21), a heat source side heat exchanger (22), an expansion mechanism (25) and a use side heat exchanger (26), which are connected in order. The device is provided with a bypass mechanism (40) that is connected to the discharge side and the suction side of the compressor (21) and bypasses a part of the refrigerant discharged from the compressor (21) to the suction side. 40) is a throttle portion (42) for reducing the pressure of the bypass refrigerant, and a flow rate control for controlling the flow rate of the bypass refrigerant by opening when the suction side refrigerant pressure of the compressor (21) falls below a predetermined value. A refrigeration system comprising a valve (43) and a bypass passage (41) sequentially arranged from the upstream side. 2. A refrigeration system comprising a refrigerant circuit (20) comprising a compressor (21), a heat source side heat exchanger (22), an expansion mechanism (25) and a use side heat exchanger (26), which are connected in order. The device is provided with a bypass mechanism (40) that is connected to the discharge side and the suction side of the compressor (21) and bypasses a part of the refrigerant discharged from the compressor (21) to the suction side. 40) is provided with a plurality of bypass passages (44, 45, ...) By which the refrigerant is divided and bypassed, and each of the bypass passages (44, 45, ...) Has a predetermined suction side refrigerant pressure of the compressor (21). A refrigerating apparatus comprising flow rate control means (4C) for controlling the flow rate of the bypass refrigerant so as to communicate with each other when the value becomes less than or equal to a value. 3. The refrigerating apparatus according to claim 2, wherein the flow rate control means (4C) opens when the suction side refrigerant pressure of the compressor (21) becomes a predetermined value or less and controls the flow rate of the bypass refrigerant. A refrigeration system comprising a valve (43). 4. The on-off valve (46) according to claim 2, wherein the flow rate control means (4C) is opened and closed when the suction side refrigerant pressure of the compressor (21) becomes a predetermined value or less, and the on-off valve. (46) A refrigerating device comprising a throttle portion (47) provided in series. 5. The refrigeration apparatus according to claim 2, wherein the flow rate control means (4C) in a part of the plurality of bypass passages (44, 45, ...) Is the compressor (21). It is composed of a flow control valve (43) that opens to control the flow rate of the bypass refrigerant when the suction side refrigerant pressure becomes equal to or lower than a predetermined value, while the flow rate control means (4C) in the other bypass passage (45).
Is constituted by an on-off valve (46) that opens when the suction side refrigerant pressure of the compressor (21) becomes a predetermined value or less, and a throttle section (47) provided in series with the on-off valve (46). A refrigerating device characterized by the above. 6. The refrigeration system according to claim 1, wherein the refrigerant circuit (20) is a high temperature side refrigerant circuit (20), and the utilization side heat exchanger (26) is a cascade condenser (26). ), A compressor (31), the cascade condenser (26), an expansion mechanism (33), and an evaporator (34) are connected in this order to the low temperature side refrigerant circuit (30). Refrigerating device characterized by.