KR100357457B1 - Packing structure of Nitrogen Gas Injection Apparatus for Evaporator of Refrigeration System - Google Patents

Abstract

The present invention relates to a nitrogen gas injection device of the evaporator for a refrigerant system, in the nitrogen gas injection device of the evaporator provided in the refrigerant system, the seal member of the rubber material made by press-fitting the injection part of the evaporator to completely block it. It is provided to provide a packing assembly structure of the nitrogen gas injection window of the evaporator for the refrigerant system to prevent leakage after the injection of nitrogen gas.

Description

Packing structure of Nitrogen Gas Injection Apparatus for Evaporator of Refrigeration System}

The present invention relates to a nitrogen gas injector for an evaporator for a refrigerant system, and more particularly, to a nitrogen gas injector provided for injecting nitrogen gas into an evaporator, which is one of the refrigerant systems, which is press-fitted to the inlet end of the evaporator. It relates to a packing assembly structure of the nitrogen gas injection device of the evaporator for the refrigerant system provided with a rubber seal member to be coupled to completely block it to prevent the leakage of the nitrogen gas injection.

The present invention relates to an evaporator which is one of the refrigerant systems, the present invention will be described by using a conventional air conditioner as an example.

As is well known, air conditioners use an artificial method to ensure that the temperature in a space is kept constant at all times.

The air conditioner uses the thermal action generated when the compressed refrigerant is expanded by the pressure drop action to take away the surrounding heat and release the heat to the outside to cool the room.

1 is a block diagram showing the principle of the conventional air conditioner described above, Figure 2 is a view showing a conventional air conditioner.

As shown in the drawing, the air conditioner 10 expands inside the second housing 15 and the heat dissipation device 14 in which the compressor 12 and the condenser 13 are installed inside the first housing 11 forming the exterior. It consists of a thermal sensor 18 provided with a valve 16 and an evaporator 17.

The first housing 11 constituting the heat dissipation device 14 is installed on an outdoor side, and includes a first suction part 19 for sucking outside air, and outside air sucked into the first suction part 19. After passing through), the first discharge unit 20 is provided to discharge to the atmosphere, and the suction blower 21 for outdoor unit which generates suction force to suck the outside air is installed close to the condenser 13, have.

In addition, the second housing 15 constituting the heat sensing device 18 is installed on the indoor side while passing through the second suction unit 22 and the evaporator 17 to suck the heated air from the heat source in the room. A second discharge unit 23 is provided to discharge the cooled air into the room, and a control unit 24 for controlling the air conditioner 10 is installed at the front center portion thereof, and the evaporator is provided. A discharge blower 25 for an indoor unit is installed to be close to 17, and the compressor 12 and the evaporator 17 are connected by a third pipe 26, and the condenser 13 and the expansion valve 16 are provided. ) Is connected to the fourth pipe (27).

When the control unit 24 installed in the middle of the first housing 11 is driven to drive the air conditioner 10 configured as described above, the compressor 12 installed in the first housing 11 is driven. .

As shown in FIGS. 1 and 2, the low temperature and low pressure liquid liquefied refrigerant is sucked into the third pipe 26 by the compressor 12 and connected to the condenser 13. Through the pipe is sent to the condenser 13 in a high temperature, high pressure gas state.

The high temperature and high pressure refrigerant flowing into the inlet of the condenser 13 is liquefied and discharged to the outlet side while being cooled by the outside air that enters through the first inlet 19 due to the suction force of the outdoor air suction blower 21. .

The refrigerant in the liquefied state discharged to the outlet side of the condenser 13 passes through the expansion valve 16 to expand the high-pressure, liquid-state refrigerant by the pressure strengthening action, and is converted into the low-temperature, low-pressure fog state refrigerant.

Thereafter, the refrigerant flows from the inlet side of the evaporator 17 to the discharge port side, absorbs heat from the outside, changes from a misty refrigerant state to a gas state, and repeats the circulation process of being supplied back to the inlet side of the compressor 12 within a predetermined space. By dissipating heat into the atmosphere, it is possible to maintain a comfortable environment (temperature).

As such, the evaporator 17, which is one of the refrigerant systems of the air conditioner 10, which is configured and driven by the compressor 12, the condenser 13, the expansion valve 16, and the evaporator 17, is shown in FIG. As one pipe is formed by bending a number of times, one end is connected to the outlet side of the expansion valve 16 and the other end is connected to the compressor 12 side.

However, the evaporator 17 formed by bending a number of times is in a state in which air in the atmosphere containing moisture is introduced therein. In this state, when driven in connection with the refrigerant system, the moisture contained in the air is mixed with the refrigerant of the refrigerant system, thereby reducing the efficiency of the refrigerant system and preventing the circulation of the refrigerant gas.

Therefore, the evaporator 17 injects nitrogen gas to remove moisture in the air introduced into the refrigerant system before being connected to the refrigerant system, and then discharges it to remove moisture, which is illustrated in FIG. As described above, one end of the evaporator 17 is blocked and nitrogen gas is injected into the other end side. At this time, the inlet 17a side of the evaporator 17 is provided with a connecting member 28 which is screwed thereto, and then nitrogen gas is injected.

When nitrogen gas is injected into the evaporator 17, the tip of the connecting member 17a is crushed by using a separate tool so as to be filled in the evaporator 17 for a predetermined time to eat moisture, and then sealed by soldering. . Subsequently, when applied to the refrigerant system, the connection member 17a is removed and nitrogen gas is discharged to connect one end to the compressor 12 and the expansion valve 16.

However, as described in the above-described process, after the nitrogen gas is injected, the tip of the connecting member is sealed by soldering in the state of leaking nitrogen gas, so that the nitrogen gas is not filled in the evaporator in a filled state. As a result, there is a problem that moisture in the air remains in the evaporator.

In addition, as described above, after the nitrogen gas injection, the operation for enclosing the connecting member is very complicated, so that a long time is required for encapsulation. Also, as in Japanese Laid-Open Utility Model No. 56-107473, injection of an evaporator is performed. Nitrogen gas injection device has been proposed having a packing member, a valve member penetrated through the center, a connecting member having an injection pin, etc., but the packing member has a center penetrated so that an injection pin for nitrogen supply can pass. It has a problem that the nitrogen gas leaks through the penetrating portion after the nitrogen gas injection made of a shape.

Accordingly, the present invention has been made to solve the above problems, in the nitrogen gas injection device provided for injecting nitrogen gas inside the evaporator which is one of the refrigerant system, it is press-fitted to the tip of the injection portion of the evaporator It is an object of the present invention to provide a packing assembly structure of a nitrogen gas injection device of a vaporizer for a refrigerant system having a seal member made of a rubber material to completely shut off to prevent leakage thereof when nitrogen gas is injected.

1 is a configuration diagram showing the principle of a conventional general air conditioner

2 is a perspective view showing a conventional air conditioner

3 is a perspective view of the evaporator provided in FIG.

4 is an exploded cross-sectional view showing a nitrogen gas injection apparatus of the evaporator for a refrigerant system according to the present invention.

Figure 5 is a cross-sectional view showing a state of nitrogen gas injection after the nitrogen gas injection device of the evaporator for a refrigerant system according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: evaporator 105: injection unit

110: sealing member 110a: groove

110: protrusion 115: cap member

115a: through hole 115b: extension piece

115c: thread 120: injection pin

125: connecting member

The present invention for achieving the above object is provided with a sealing member provided in close contact with the injection portion of the evaporator, the cap member is screwed into the injection portion while the seal member is fitted to the inside, and through the cap member and the seal member In the nitrogen gas injection device of the evaporator provided in the refrigerant system consisting of a connecting member equipped with an injection pin for supplying nitrogen, the injection end of the evaporator is formed in a shape having a slope and a locking jaw, the sealing member Is formed by a concave-convex cross-section having a concave-convex portion having a protrusion formed by being fitted into a fitting hole formed in the cap member so that one end thereof is formed with an inclined surface portion and a catching portion so as to press-fit and block the injecting portion of the evaporator. And packing tank of nitrogen gas injector of evaporator for refrigerant system, characterized in that it is made of rubber material It is achieved by the structure with reference to the following, illustrated by the appended drawings the present invention will be described in detail.

The accompanying drawings are described as an example for explaining the present invention, the evaporator provided in the air conditioner as an example.

Figure 4 is a separate cross-sectional view showing an evaporator for air conditioner showing a nitrogen gas injection device of the evaporator for the refrigerant system according to the present invention, Figure 5 is a nitrogen after the nitrogen gas injection device of the evaporator for a refrigerant system according to the present invention is combined. It is sectional drawing which shows the injection state of gas.

As shown in the present invention is to inject nitrogen gas into the evaporator 100 to remove the moisture in the air introduced into it, as an injection device to block the leakage of nitrogen gas when nitrogen gas is injected into the evaporator 100 , The evaporator 100 of the refrigerant system for an air conditioner composed of a compressor, a condenser, an expansion valve, and an evaporator is press-coupled to a nitrogen gas injection unit 105, which is one end of the evaporator 100 which is bent and conduit as many times as shown. One end is provided with a recess 110a, and the other end is provided with a rubber member seal member 110 formed as a cross-sectional shape of an uneven shape having a protrusion 110b. At this time, the evaporator 100 The injection part tip 104 has a locking step 104b and has a shape in which the inclined part 104a is formed on the outside thereof, and the recess 110a of the seal member 110 into which the injection part tip 104 is fitted. ) Corresponds to the inlet tip 104. That is, the recess 110a of the seal member 110 has a locking portion 110d and an inclined surface portion corresponding to the locking jaw 104b and the inclined portion 104a of the injection portion tip 104, respectively. It has a shape having (110c).

After the seal member 110 is press-fitted to the injection portion 105 of the evaporator 100, that is, after injection of nitrogen gas into the evaporator 100, the seal member 110 is injected by the injected nitrogen gas. Cap member of steel material that is screwed through the threaded portion 102 of the injection portion 105 so as to force the seal member 110 to the inside so that the seal member 110 is not separated from the (105) side ( 115 is provided.

The cap member 115 has a through hole 115a penetrated in the axial direction, and one end thereof is sealed by an extension piece 115b that is bent inwardly to prevent separation thereof when the seal member 110 is inserted. The fitting groove 115d to which the protrusion 110b of the 110 is fitted is formed, and on the inner circumferential surface of the other end of the extension piece 115b, the thread forming portion 102 formed on the injection portion 105 of the evaporator 100 is formed. Thread portion 115c is formed to be screwed to the).

Meanwhile, the seal member 110 and the cap member 115 are pre-loaded and screwed into the injection portion 105 of the evaporator 100, and thereafter, a nitrogen gas supply tank for injecting nitrogen gas into the evaporator 100. (Not shown) is provided with a connection member 125, the injection pin 120 is provided on the inside of the discharge port (not shown)

Nitrogen gas injection device of the evaporator for air conditioner according to the present invention made as described above is the yaw of the seal member 110 made of a rubber material at the tip 104 of the injection portion of the evaporator 100 as shown in Figs. After matching the groove 110a, the seal member 110 is press-fitted to the injection part tip 104 to completely block the injection part 105. At this time, the outer surface of the injection part tip 104 is inclined. Part 104a is formed to easily press-fit, and in the press-fitted state, the locking step 110b of the recess 110a formed in the sealing member 110 at the locking jaw 104b of the injection part tip 104 is formed. The sealing member 110 is not easily pulled out of the injection portion tip 104 by the locking.

Subsequently, the cap member 115 formed of the steel material having the through hole 115a penetrated in the central axis direction is inserted into the sealing member 110 press-fitted to the injection part tip 104, and then the cap member ( The screw portion 115c is formed on the inner circumferential surface of the screw 115 to be screwed into the injection portion 105. At this time, when the cap member 115 is completely locked to the injection portion 105, the protrusion 110b of the seal member 110 is fitted into the fitting groove formed between the extension pieces 115b of the cap member 115 to seal. The coupling of the member 110 is further strengthened.

Thereafter, the connection member 125 having the injection pin 120 fixed to the inside of the outlet side of the supply tank (not shown) for providing nitrogen gas is connected to the cap member 115.

Due to the connection of the connecting member 125, the injection pin 120 is inserted into the protrusion 110b of the seal member 110 forming the same plane as the extension piece 115b of the cap member 115, and thus, In communication with the injection portion 105.

Then, when nitrogen gas is provided from the nitrogen supply tank, the nitrogen gas is injected into the evaporator 100 through the injection pin 120.

Then, when the injection of nitrogen gas is injected into the appropriate amount inside the evaporator 100 is filled, the operator may leave the connection member 125 connected to the cap member 115. At this time, the injection pin 120 inserted into the seal member 110 is removed at the same time as the connection member 125 is detached, and thus the marks of the injection pin 120 formed on the seal member 110 are made of the material of the seal member 110. By being in close contact with the characteristics of the rubber material, the marks are automatically sealed to maintain airtightness.

As described above, when nitrogen gas is to be filled into the evaporator, the connection member with the injection pin is connected to the cap member with the seal member forcibly inserted therein so that the outlet of the providing tank and the evaporator communicate with each other. At this time, the seal member is press-fitted to the injection part tip 104 to completely block it, and made of a rubber material to prevent leakage after nitrogen gas injection, and the protrusion of the seal member is inserted into the fitting groove of the cap member. By being fitted together, the bond can be further strengthened to further prevent nitrogen gas from leaking out through the gap.

As described above, the present invention includes a connection member having an injection pin at an outlet side of a providing tank for providing nitrogen gas, having a seal member made of a rubber material that is press-fitted to the inlet end of the evaporator to completely block it. When connected, the connecting member of the supply tank and the injecting part of the evaporator communicate with each other. In addition, when the connecting member is removed from the cap member, the injecting part is automatically sealed by the sealing member. Therefore, the effect of ensuring leakage after injecting nitrogen gas is ensured. have.

Claims (7)

A sealing member provided in close contact with the injection part of the evaporator, a cap member screwed into the injection part while the seal member is fitted inside, and an injection pin for supplying nitrogen through the cap member and the seal member. In the nitrogen gas injection device of the evaporator provided in the refrigerant system consisting of a connecting member, The tip of the injection section of the evaporator is formed in a shape having a slope and a locking jaw, the seal member is press-fitted to the tip of the injection section of the evaporator so that one end thereof has a groove portion having a shape having a slope and a locking portion to block it. The other end of the packing assembly structure of the nitrogen gas injector of the evaporator for a refrigerant system, characterized in that formed in the cross-section of the concave-convex shape having a projection is inserted into the fitting hole formed in the cap member and made of a rubber material. delete delete delete delete delete delete