KR100202595B1 - Refrigerant control device of cooling cycle - Google Patents

Abstract

The present invention relates to a refrigerant control device of a refrigeration cycle, and a compressed refrigerant inlet unit through which a refrigerant discharged from a compressor for compressing a refrigerant is introduced as shown in the following drawings; A compressed refrigerant discharge unit for discharging the refrigerant through the compressed refrigerant inlet unit to a condenser for condensing the refrigerant; A condensation cold discharge inlet unit through which the refrigerant condensed in the condenser is introduced; A capillary discharge portion for discharging the condensed refrigerant through a condensation refrigerant inlet portion and into a capillary tube which is converted to low temperature and low pressure; An evaporator discharge section for bypassing the high temperature / high pressure refrigerant compressed by the compressor and discharging the low temperature / low pressure refrigerant from the capillary to an evaporator that exchanges heat with external air; When the normal refrigeration cycle is operated, the compressed refrigerant discharge unit, the condensation refrigerant inlet unit, and the capillary discharge unit are opened, and when defrosting the frost generated in the evaporator, the compressed refrigerant discharge unit and the condensation refrigerant inlet port are closed, and the evaporator is closed. A refrigerant control member capable of opening the discharge portion; A refrigerant control device for a refrigeration cycle, characterized by comprising a drive means for driving the refrigerant control member, and it is necessary to use a device such as a bypass valve even when a compressor is used in which a backflow does not occur when the compressor is stopped. Also, there is no need for components such as electromagnetic valves or high temperature refrigerant inlet shutoff valves, thereby reducing the piping line of the refrigerant and reducing the assembly labor, thereby reducing the production cost.

Description

Refrigeration control device of refrigeration cycle

The present invention relates to a refrigerant control device for a refrigeration cycle, and in particular, when the compressor constituting the refrigeration cycle is stopped, the high temperature / high pressure refrigerant collected in the condenser is blocked from entering the low temperature / low pressure evaporator, . The present invention relates to a refrigerant control device of a refrigeration cycle that can be defrosted by balancing the outlet at low pressure.

In general, as shown in Figs. 1 and 2, the refrigerating cycle is provided with a compressor (1) for compressing a refrigerant having a high temperature and a low pressure into a refrigerant having a high temperature and a high pressure. A condenser 2 for discharging the heat of the refrigerant to the outside and condensing it into a liquid refrigerant of room temperature and high pressure is installed, and a capillary tube 3 for converting the refrigerant condensed in the condenser 2 into a gas refrigerant of low temperature and low pressure is provided. And an evaporator (4) installed so that the refrigerant converted into a low-temperature, low-pressure gas refrigerant in the capillary tube (3) exchanges heat with external air to perform a freezing and refrigerating function.

And, the refrigerant control device of the refrigeration cycle basically configured as described above in detail with reference to Figures 1 and 2 as follows.

First, as shown in FIG. 1, an electromagnetic valve 5 is installed between the compressor 1 and the condenser 2 so that the electronic valve 5 is opened during the normal operation of the refrigeration cycle. ), The condenser (2), the capillary tube (3), the evaporator (4) sequentially performs the refrigeration cycle, and when the frost occurs in the evaporator (4), the operation of the compressor (1) is stopped The electromagnetic valve 5 is closed so that the refrigerant compressed at high temperature and high pressure in the compressor 1 flows into the evaporator 4 to remove frost generated in the evaporator 4.

As shown in FIG. 2, the compressor 1, the condenser 2, and the high temperature refrigerant inlet shutoff valve 6 for controlling the flow of the refrigerant between the condenser 2 and the capillary tube 3 and the compressor When a bar pass valve 7 is installed between the refrigerant outlet pipe 1a and the inlet pipe 1b to bypass the refrigerant, and the compressor 1 is driven to perform a normal refrigeration cycle. The refrigerant compressed by the high temperature and high pressure in the compressor (1) passes through the reverse variable reverse execution section (6a) of the high temperature refrigerant inlet shutoff valve (6) and flows into the condenser (2), and again the high temperature refrigerant inlet blocker. The valve 6 is circulated to the capillary tube 3 and the evaporator 4, and when the driving of the compressor 1 is stopped, the outlet pipe 1a and the inlet pipe 1b of the compressor 1 are stopped. ), The bypass valve (7) provided between the open and the bypass valve (7) is opened to the above The refrigerant between the accumulator 1 and the high temperature refrigerant inlet shutoff valve 6 is bypassed, and the pressure of the refrigerant drops. At this time, the pressure balance of the high temperature refrigerant inlet shutoff valve 6 is broken so that the high temperature refrigerant inlet is prevented. The check valve 6a of the shutoff valve 6 pushes the diaphragm 6b downward so that the high temperature coolant shutoff rod 6c of the high temperature coolant inlet shutoff valve 6 is connected to the condenser 2. In addition to blocking the capillary tube 3 and blocking the inflow of high-temperature refrigerant, and driving the compressor 1 again and closing the bypass valve 7, the high-temperature refrigerant inlet shutoff valve 6 The diaphragm 6b is raised so that the high temperature refrigerant blocking rod 6c of the high temperature refrigerant inlet shutoff valve 6 opens between the condenser 2 and the capillary tube 3.

Reference numeral 8 in the drawings is a reverse displacement.

However, the refrigerant control device of the refrigeration cycle configured as described above should always use a device such as a bypass valve when using a compressor that does not cause backflow when the compressor is stopped, that is, a reciprocating compressor. When controlling the refrigeration cycle using an electronic valve as shown, or controlling the refrigeration cycle using a high temperature refrigerant inlet shutoff valve as shown in Figure 2, many parts such as valves are used This resulted in an increase in assembly labor and production cost.

Accordingly, an object of the present invention is to solve the above problems by eliminating the bypass valve used in the compressor for compressing the refrigerant and the electromagnetic valve used in the compressor and the condenser to reduce the number of parts and to reduce the assembly labor and production costs It is to provide a refrigerant control device of the refrigeration cycle to reduce the.

1 is an explanatory diagram for explaining the structure of a refrigeration cycle according to the prior art.

2 is an explanatory view showing the structure of a refrigeration cycle to which the high temperature refrigerant inlet shutoff valve according to the prior art is applied.

3 is an explanatory view showing a state in the normal operation of the refrigeration cycle with the refrigerant control device of the refrigeration cycle according to the present invention.

4 is an explanatory view showing a state at the time of defrosting a refrigeration cycle having a refrigerant control device of the refrigeration cycle according to the present invention.

* Explanation of symbols for main parts of the drawings

1: compressor 2: condenser

3: capillary tube 4: evaporator

16: refrigerant control device 16a: body

16b: compressed refrigerant inlet 16c: compressed refrigerant chamber

16d: compressed refrigerant discharge portion 16e: condensed refrigerant inlet portion

16f: Condensation refrigerant chamber 16g: Condensation refrigerant discharge unit

16h: evaporator discharge section 16i: refrigerant control member

16j: drive means mounting portion 16k: first opening and closing

16l: Stator 16m: Magnet

16n: discharge prevention part 16o: second opening and closing part

16p: Compression Coil Spring

An object of the present invention is a compressed refrigerant inlet unit for introducing the refrigerant discharged from the compressor for compressing the refrigerant; A compressed refrigerant discharge unit for discharging the refrigerant through the compressed refrigerant inlet unit to a condenser for condensing the refrigerant; A condensation refrigerant inlet unit through which the refrigerant condensed in the condenser is introduced; A capillary discharge portion for discharging the condensed refrigerant through a capillary tube which is converted into low temperature and low pressure through the condensation refrigerant inlet portion; An evaporator discharge section for bypassing the high temperature / high pressure refrigerant compressed by the compressor and discharging the low temperature / low pressure refrigerant from the capillary to an evaporator that exchanges heat with external air; When the normal refrigeration cycle is operated, the compressed refrigerant discharge unit, the condensation refrigerant inlet unit, and the capillary discharge unit are opened. When defrosting the frost generated in the evaporator, the compressed refrigerant discharge unit and the condensation refrigerant inlet unit are closed, and the evaporator is closed. A refrigerant control member capable of opening the discharge portion; It is achieved by the refrigerant control device of the refrigeration cycle, characterized in that the drive means for driving the refrigerant control member is provided.

Next, a preferred embodiment of a refrigerant control device of a refrigeration cycle of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is an explanatory view showing a state in the normal operation of the refrigeration cycle with a refrigerant control device of the refrigeration cycle according to the present invention, Figure 4 is a first of the refrigeration cycle with a refrigerant control device of the refrigeration cycle according to the present invention. It is explanatory drawing which always showed the state.

As shown in the drawings, the refrigeration cycle having the refrigerant control device 16 according to the present invention is provided with a compressor (1) for compressing the refrigerant converted to normal temperature and low pressure by heat exchange in the evaporator (4) at high temperature and high pressure. And a compressed refrigerant inflow portion 16b through which the refrigerant derived from the compressor 1 flows is formed on one side of the main body 16a of the refrigerant control device 16, and the compressed refrigerant inflow portion 16b is provided. Compressed refrigerant chamber (16c) having a predetermined volume is formed in the main body (16a) is formed, the lower portion of the compressed refrigerant chamber (16c) is a heat dissipation of the refrigerant compressed to high temperature and high pressure in the compressor (1) 16 d of compressed refrigerant discharge parts for supplying the condenser 2 converting into normal temperature and high pressure are formed.

In addition, a condensation refrigerant inlet 16e through which the refrigerant condensed in the condenser 2 flows is formed to have an inclination angle at an upper portion of the body 16a, and the body in which the condensation refrigerant inlet 16e is formed. A condensation refrigerant chamber 16f having a predetermined volume is formed in 16a, and the refrigerant condensed in the condenser 2 is cooled at a low side at the side of the main body 16a in which the condensation refrigerant chamber 16f is formed. The capillary discharge portion 16g for supplying to the capillary tube 3 that converts the gas refrigerant into the gas coolant is formed.

In addition, between the capillary discharge portion 16g formed in the main body 16a and the compressed refrigerant inlet portion 16b, a high temperature / high pressure refrigerant compressed by the compressor 1 is cooled by the capillary tube 3 at a low temperature. An evaporator discharging portion 16h is formed for bypassing the refrigerant converted into the evaporator 4 to exchange heat with external air, and the compressor 16 is formed in the main body 16a in which the evaporator discharging portion 16h is formed. The drive means mounting portion 16j having a predetermined space in which the refrigerant compressed in 1) can flow and having a drive means for driving the coolant control member 16i to be described later is provided in the compressed refrigerant chamber 16c. ) And the condensation refrigerant chamber 16f are connected in a straight line.

The drive means mounting portion 16j, the compression refrigerant chamber 16c, and the condensation refrigerant chamber 16f are provided with a refrigerant control member 16i for controlling the flow of the refrigerant, and the refrigerant control member 16i is A first opening and closing portion 16k for opening and closing the compressed refrigerant discharge portion 16d formed at the lower portion of the compression refrigerant chamber 16c is formed, and is connected to and formed on an upper portion of the first opening and closing portion 16k. When the coil is installed in the outer periphery of the mounting portion (16j) when the power is applied to the stator (16l) wound there is a magnet portion (16m) is provided with a magnet so that the refrigerant control member (16i) can perform a vertical reciprocating movement, In addition, a discharge preventing portion 16n is formed on the magnet portion 16m to prevent the refrigerant flowing from the condensation refrigerant inlet portion 16e from being discharged to the evaporator discharge portion 16g. The upper portion of the prevention portion 16n has the inclination angle And a second opening and closing portion 16o for opening and closing the formed condensation refrigerant inlet portion 16e.

In addition, the drive means mounting portion 16j includes a compression type coil spring 16p that is an elastic member so that the refrigerant control member 16i can be returned to its original shape when the power applied to the stator 16l is cut off. It is installed.

The refrigerant control device 16 of the refrigeration cycle configured as described above, first, when the normal compressor 1 for freezing is driven, as shown in Figure 3 the elastic member is installed in the drive means mounting portion 16j The refrigerant control member 16i is raised by the expansion of the compressed coil spring 16p, and the first opening / closing portion 16k formed in the refrigerant control member 16i is raised by the rise of the refrigerant control member 16i. The compressed refrigerant discharge portion 16d formed at the lower portion of the compressed refrigerant chamber 16c is opened, and the second opening and closing portion 16o also opens the condensed refrigerant inlet portion 16e to form a normal refrigerant cycle. Done.

When frost is formed in the evaporator 4 by forming a normal refrigerant cycle as described above, the driving of the compressor 1 is stopped and power is applied to the stator 16l of the refrigerant control device 16. The refrigerant control member 16i is raised so that the first opening / closing portion 16k of the refrigerant control member 16i seals the compressed refrigerant discharge portion 16d formed under the compressed refrigerant chamber 16c. In addition, the second opening and closing part 16o also seals the condensation refrigerant inlet part 16e, and the refrigerant compressed at high temperature and high pressure in the compressor 1 is the compressed refrigerant inlet part 16b and the evaporator discharge part 16h. It is introduced into the evaporator (4) to remove the frost generated in the evaporator (4).

When the frost generated in the evaporator 4 is removed, the power applied to the stator 16l is cut off, and the coolant control member 16i is elastically installed in the driving means mounting portion 16j by cutting off the power. The compression coil spring 16p, which is a member, rises due to the expansion of the compression refrigerant chamber 16c, thereby opening the compressed refrigerant discharge portion 16d and opening the condensation refrigerant inlet portion 16e. Normal refrigerant cycle is to be formed.

By installing the refrigerant control device formed as described above in the refrigeration cycle, it is not necessary to use a device such as a bypass valve even if a compressor that does not generate a backflow when the compressor is stopped, and an electromagnetic valve or a high temperature refrigerant inlet shutoff valve. This eliminates the need for components such as reducing the piping line of the refrigerant and reduces the cost of planting, reducing the production cost.

Claims (6)

A compressed refrigerant inlet through which the refrigerant discharged from the compressor for compressing the refrigerant flows; A compressed refrigerant discharge unit for discharging the refrigerant through the compressed refrigerant inlet unit to a condenser for condensing the refrigerant; A condensation refrigerant inlet unit through which the refrigerant condensed in the condenser is introduced; A capillary discharge portion for discharging the condensed refrigerant through a condensation refrigerant inlet portion into a capillary tube which is changed to low temperature and low pressure; An evaporator discharge section for bypassing the high temperature / high pressure refrigerant compressed by the compressor and discharging the low temperature / low pressure refrigerant from the capillary to an evaporator that exchanges heat with external air; When the normal refrigeration cycle is operated, the compressed refrigerant discharge unit, the condensation refrigerant inlet unit, and the capillary discharge unit are opened. When defrosting the frost generated in the evaporator, the compressed refrigerant discharge unit and the condensation refrigerant inlet ratio are closed. A refrigerant control member capable of opening the evaporator discharge section; A refrigerant control apparatus for a refrigeration cycle, characterized in that the drive means for driving the refrigerant control member is provided. The refrigerant control device of a refrigeration cycle according to claim 1, wherein the condensation refrigerant inlet is formed to have an inclination angle. The refrigerant control device according to claim 1, wherein the refrigerant control member has a first opening and closing portion capable of opening and closing the compressed refrigerant discharge portion and a second opening and closing portion opening and closing the condensation refrigerant inlet portion. The refrigerant control device of a refrigeration cycle according to claim 3, wherein the second opening / closing part has an inclination angle formed to open and close the condensation refrigerant inlet formed to have the inclination angle. The refrigerant control device of a refrigeration cycle according to claim 1, wherein the refrigerant control member has a magnet portion provided with a magnet so that the refrigerant control member can move up and down by an induced current. The method of claim 1, wherein the driving means is applied to the power supply to generate a stator coil, the coil is wound, the magnet portion of the refrigerant control member and the power of the stator to shut off the refrigerant control member is returned to the original Refrigerant control device of a refrigeration cycle, characterized in that comprising an elastic member capable of.