KR200391531Y1 - Combination apparatus of capillary tube and suction pipe for refrigerating cycle - Google Patents

Abstract

The present invention relates to a coupling device of the suction tube and the capillary tube for the refrigeration cycle.

The configuration of the present invention is the refrigerant in the refrigerating device (A) configured to circulate the compressor 200, the condenser 201, the dryer 202, the capillary tube 203, the evaporator 204 and the compressor 200 In the case where the capillary tube 203 is installed in the suction pipe 205 connecting between the evaporator 204 and the compressor 200,

The suction pipe 205 is a main suction pipe 1 made of aluminum, an auxiliary suction pipe (2) (2a) for connection to be inserted into both sides of the main suction pipe (1), and the auxiliary suction pipe for connection. (2) (2a) is configured to connect the suction pipe (4) (4a), the capillary tube 203 into the main suction pipe (1) and the auxiliary suction pipe (2) (2a) for both sides of the connection And the caulking 3 and the silver solder soldering welding together with the capillary tube 203 at the portion connecting the suction suction pipes 4 and 4a to the auxiliary suction pipes 2 and 2a. It is made by joining in airtight state by Silver-alloy brgzing) (w).

The present invention as described above, first, by installing a combination of the suction pipe (Suction pipe) and the capillary tube (Capillary Tube) in the suction tube 205 in the refrigerating cycle to increase the efficient heat exchange.

Second, as the material of the main suction pipe (1) is composed of an aluminum material from the existing copper pipe can significantly reduce the material value of the material.

Third, the capillary tube may be built in the main suction pipe 1 by the auxiliary suction pipes 2 and 2a for connection.

Fourth, the capillary tube 203 is installed in the main suction pipe (1) and the auxiliary suction pipe (2) (2a) for connection, and the suction tube (4) for connection to the connection auxiliary suction pipe (2) (2a). The cabling 3 and the silver-alloy brgzing (w) at the portion connecting (4a) have an effect of being able to be bonded in a state of maintaining airtightness at a low cost.

Description

Combination apparatus of capillary tube and suction pipe for refrigerating cycle

The present invention relates to a coupling device of a suction tube and a capillary tube for a refrigeration cycle, and more particularly, the capillary tube in a refrigerating device configured to circulate a refrigerant to a compressor, a condenser, a dryer, a capillary tube, an evaporator, and a compressor. The present invention relates to a coupling device of a suction tube for a refrigeration cycle and a capillary tube installed in a suction pipe connecting between an evaporator and a compressor to allow heat exchange.

In general, the refrigeration cycle has a problem that the refrigerant evaporation temperature in the evaporator is very low, the refrigerant condensation temperature in the condenser is relatively high, the energy efficiency is lowered, and in order to increase energy efficiency, the refrigerant evaporation temperature is increased and the condensation temperature of the refrigerant is increased. In this case, it is difficult to reach the required cooling temperature due to the high evaporation temperature, and thus the freezing function is lost.

The technology adopted to solve this problem is to secure the refrigerant overheating performance of the evaporator and the refrigerant supercooling performance of the condenser. For this subcooling and thermal performance, the cost of manufacturing the refrigeration cycle increases when the capacity of the evaporator and the condenser is increased. Problems arise.

As a result, an initial refrigeration cycle manufacturing cost is increased to produce a high-efficiency refrigeration cycle with low operating costs, and an operation cost is increased to reduce the refrigeration cycle manufacturing costs.

On the other hand, the technology introduced to produce a refrigeration cycle at a low production cost to obtain sufficient evaporation temperature at a low operating cost is a heat exchanger of the suction tube and the capillary tube in the refrigeration cycle.

The combination of the suction pipe and the capillary tube in the conventional refrigeration cycle is installed between the condenser and the evaporator, as shown in FIGS. A portion of the capillary tube 100 that is delivered to the evaporator is axially matched by soldering welding 102 to the outer circumferential surface of the suction pipe 101 connecting the evaporator and the compressor. Bound circumscribed in the state.

Therefore, the suction pipe 101 and the capillary tube 100 of the refrigeration cycle are mutually spaced between the refrigerant of the capillary tube 100 and the refrigerant of the suction pipe 101. As the heat exchange takes place, the condensation refrigerant of the capillary tube 100 is supercooled by the low temperature evaporative refrigerant of the suction tube 101, and conversely, the evaporative refrigerant of the suction tube 101 is overheated by the high temperature condensation refrigerant of the capillary tube 100. Evaporates completely.

As a result, by combining the suction pipe 101 and the capillary tube 100, the refrigeration cycle can increase the evaporation temperature while lowering the necessary condensation temperature while obtaining the necessary evaporation temperature.

However, the combination of the suction pipe 101 and the capillary tube 100 of the conventional refrigeration cycle is expensive for welding by the soldering welding 102, and the uniform welding quality is improved. It is difficult to maintain, and soldering welding is becoming more regulated due to heavy metal contamination, and especially in the case of soldering welding, suction pipe 101 and capillary tube. This is possible when 100 is made of copper (Cu) material, so that the suction pipe 101 and the capillary tube 100 are required to be expensive.

Accordingly, the present invention is designed to solve the conventional problems as described above, an object of the present invention is the refrigerant in the refrigerating device configured to circulate the refrigerant to the compressor and condenser, dryer, capillary tube, evaporator and compressor. The tube is installed in the suction pipe connecting the evaporator and the compressor so that heat exchange can be made and the expensive soldering welding is omitted, and the material of the suction pipe is made of aluminum (AL). It can be composed of), which can greatly reduce the cost of material value, and provides a combination of suction tube and capillary tube for refrigeration cycle that can reduce uniform product manufacturing and manufacturing cost.

The means of the embodiment for achieving the object of the present invention is a suction tube in which the refrigerant tube is configured to circulate the compressor to the condenser, the dryer, the capillary tube, the evaporator and the compressor between the evaporator and the compressor. The suction pipe is installed in the suction pipe, and the suction pipe is a main suction pipe made of aluminum, a connection auxiliary suction pipe inserted into both sides of the main suction pipe and coupled by high frequency welding, and caulking to the connection auxiliary suction pipe. Consists of a coupling suction pipe to be coupled, and built a built-in capillary tube into the secondary suction pipe for connecting the main suction pipe and both sides.

Hereinafter, described in detail according to the accompanying drawings shown as a preferred embodiment of the present invention as follows.

First, it will be described with reference to Figures 3 to 5 as follows.

As shown in FIG. 5, the refrigerant A is configured to circulate into the compressor 200, the condenser 201, the dryer 202, the capillary tube 203, the evaporator 204, and the compressor 200. In the capillary tube 203 is installed to be embedded in the suction pipe (Suction pipe) 205 connecting between the evaporator 204 and the compressor 200.

That is, as shown in Figure 3, the suction pipe 205 is a main suction pipe (1) made of aluminum, and the auxiliary suction pipe (2) (2a) for insertion coupled to both sides of the main suction pipe (1) and coupled by high frequency welding. Configure.

In addition, the connection suction suction pipes 4 and 4a coupled to the caulking 3 as shown in FIGS. 3 and 4 are formed in the connection suction suction pipes 2 and 2a of the both sides, respectively. (1) and the capillary tube 202, which is built into the connection suction suction pipes (2) (2a) of both sides, are joined together by the caulking (3), and the suction suction pipe (4) ( 4a) and the capillary tube 202 are formed by sealingly bonding by silver-alloy brgzing as shown in FIG.

The main suction pipe 1 is made of aluminum (AL), and the auxiliary suction pipe (2) (2a) for connection and the suction pipe (4) 4a for connection are made of copper (Cu).

The length of the main suction pipe 1 is, for example, about 1,850 mm.

And the connection suction pipe of any one of the connection suction pipe (4) (4a) of both sides is connected to the evaporator and the connection suction pipe of any other side is connected to the compressor.

Referring to the operation of the present invention configured as described above are as follows.

That is, the combination of the suction pipe 205 and the capillary tube 203 of the refrigeration cycle according to the present invention is a portion of the capillary tube 203 is a suction pipe (Suction pipe) ( 205 is heat-exchanged between the refrigerant of the capillary tube (203) and the refrigerant of the suction pipe (205), the suction tube (205), the suction tube (205) by the low-temperature evaporative refrigerant At the same time, the condensation refrigerant of the 203 is supercooled, and on the contrary, the evaporative refrigerant of the suction tube 205 is completely evaporated by the high temperature condensation refrigerant of the capillary tube 203.

Therefore, the refrigeration cycle by the combination of the suction pipe and the capillary tube is evaporated while the capillary tube 203 is built into the suction tube 205 to obtain a sufficient evaporation temperature required by more efficient heat exchange. The temperature can be increased and the condensation temperature can be lowered.

In addition, by configuring the main suction pipe (1) made of aluminum material, the material value of the material can be greatly reduced, and the capillary tube (203) inside the main suction pipe (1) by the auxiliary suction pipe (2) (2a) for connection. The capillary tube 203 may be installed in the main suction pipe 1 and the auxiliary suction pipe 2 and 2a, and may be connected to the connection auxiliary suction pipe 2 and 2a. In the part connecting the dragon suction pipes (4) (4a), it is possible to bond in the airtight state by the caulking (3) and silver- solder soldering (Silver-alloy brgzing) (w).

The present invention as described above has the following effects.

First, in the refrigeration cycle, by combining the suction pipe and the capillary tube of the present invention with the capillary tube 203 embedded in the suction tube 205, efficient heat exchange can be enhanced.

Second, as the material of the main suction pipe (1) is composed of an aluminum material from the existing copper pipe can significantly reduce the material value of the material.

Third, the capillary tube may be built in the main suction pipe 1 by the auxiliary suction pipes 2 and 2a for connection.

Fourth, the capillary tube 203 is installed in the main suction pipe (1) and the auxiliary suction pipe (2) (2a) for connection, and the suction tube (4) for connection to the connection auxiliary suction pipe (2) (2a). The cabling 3 and the silver-alloy brgzing (w) at the portion connecting (4a) have an effect of being able to be bonded in a state of maintaining airtightness at a low cost.

1 is a front view of the prior art.

2 is an enlarged side view of the prior art.

3 is a front view according to the present invention.

4 is an enlarged side view according to the present invention.

5 is a state diagram used in accordance with the present invention.

<Brief description of symbols for the main parts of the drawings>

A: freezer w: silver solder soldering welding

1: main suction pipe 2,2a: auxiliary suction pipe for connection

3: caulking 4,4a: suction pipe for connection

200: compressor 201: condenser

202: dryer 203: capillary tube

204: evaporator 205: suction pipe

Claims (3)

The capillary tube 203 in the refrigerating device A configured to circulate refrigerant to the compressor 200, the condenser 201, the dryer 202, the capillary tube 203, the evaporator 204 and the compressor 200. ) Is installed in the suction pipe 205 connecting between the evaporator 204 and the compressor 200, The suction pipe 205 may include a main suction pipe 1, an auxiliary suction pipe 2 and a 2 for insertion and coupling to both sides of the main suction pipe 1, and an auxiliary suction pipe 2 for connection. (2a) consists of a suction suction pipe (4) (4a) coupled to the caulking (Caulking) (3), and the cap into the main suction pipe (1) and the auxiliary suction pipe (2) (2a) for connection of both sides The coupling device of the suction tube and the capillary tube for the freezing cycle, characterized in that the built-in installation of the tube 203. 2. The coupling device of a suction tube and a capillary tube according to claim 1, wherein the main suction tube (1) is made of aluminum. 2. The caulking (3) and silver solder soldering welding together with the capillary tube (203) at the portion connecting the auxiliary suction pipe (2) (2a) to the connection suction pipe (4) (4a). A coupling device of a suction tube and a capillary tube for a refrigeration cycle, characterized in that the coupling is configured to be kept airtight by alloy brgzing) (w).