KR20110080257A - Refrigerant recovering apparatus - Google Patents

Abstract

PURPOSE: A refrigerant recovering apparatus is provided to recover a refrigerant of a refrigerant pipe effectively and stably by increasing a flow passage without using a larger needle. CONSTITUTION: A refrigerant recovering apparatus comprises a body(120) having a hollow(122), a needle(140) attached to be movable in the hollow of the body, a bracket(160) attached to be movable to approach or space out from the top of the body, and a refrigerant recovery pipe(128) installed to connect with the hollow of the body. If the needle makes a hole in a refrigerant pipe arranged between the body and the bracket, the refrigerant of the refrigerant pipe is discharged through the refrigerant recovery pipe.

Description

Refrigerant recovery device {REFRIGERANT RECOVERING APPARATUS}

The present invention relates to an apparatus for recovering the refrigerant (R-12, R-134A, etc.) of the cooler and the lubricating oil contained in the compressor in a high purity state for recycling without waste disposal during the disposal process of the cold water purifier.

1 illustrates a conventional refrigerant recovery apparatus. Referring to FIG. 1, in the conventional refrigerant recovery apparatus, a needle 20 having a hollow portion 22 is inserted into a refrigerant pipe 10 of a cooling system, and suctioned and recovered by vacuum pressure through a secured flow path.

However, in such a structure, as the suction through the small hollow portion 22 of the needle 20, the amount of refrigerant recovery is insignificant. In addition, a burr generated while the needle 20 passes through the refrigerant pipe 10 and a side surface of the needle 20 block the flow path to generate a flow loss. In the conventional refrigerant recovery apparatus, the diameter of the needle 20 is 4 mm, the diameter of the hollow portion 22 is 2 mm, and the recovery rate is known to be less than about 5%. However, if a large needle is used to increase the flow path, a breakage of the refrigerant pipe having an outer diameter of 6.35 mm may occur, resulting in leakage of the refrigerant. Therefore, a large needle cannot be used.

The present invention is designed to solve the problems of the prior art, and an object of the present invention is to provide a refrigerant recovery apparatus capable of efficiently and stably recovering a refrigerant in a refrigerant pipe by increasing a flow path without using a large needle.

According to a feature of the present invention for achieving the above object, a body having a hollow portion, a needle mounted to be movable in the hollow portion of the body, a bracket mounted to be movable so as to be close to or spaced apart from the upper surface of the body, And a refrigerant recovery tube installed to communicate with the hollow portion of the body, and when the needle makes a hole in the refrigerant tube disposed between the body and the bracket, the refrigerant in the refrigerant tube is discharged through the refrigerant recovery tube. A coolant recovery device is provided.

A packing lower is installed at an upper part of the body, and a packing upper is installed at a lower part of the bracket.

The packing lower is formed with a through hole through which the needle can pass and through which the refrigerant can be discharged.

The bottom portion of the packing upper is provided with a groove portion for accommodating the tip of the needle.

The body is provided with a shaft guide hole for movably mounting the shaft of the bracket and a pneumatic cylinder for operating the shaft of the bracket.

The refrigerant recovery pipe is provided with an open / close pneumatic solenoid valve for opening or closing the refrigerant recovery pipe.

The cylinder and the open / close pneumatic solenoid valve are simultaneously operated by a first pneumatic solenoid valve.

When the first pneumatic solenoid valve is turned on, the bracket moves closer to the body, and the open / close pneumatic solenoid valve is operated to open the refrigerant recovery pipe, and when the first pneumatic solenoid valve is turned off, the The opening and closing pneumatic solenoid valve is operated to close the refrigerant recovery pipe while the bracket is moved away from the body.

The body is equipped with a pneumatic cylinder for operating the needle, the pneumatic cylinder is operated by a second pneumatic solenoid valve.

According to the present invention, since the needle makes a hole in the refrigerant pipe and returns to the original position after recovering the refrigerant, the refrigerant is recovered through the hole so that a large hole size for securing the flow path can be secured and the same pressure (vacuum pressure) and the same time. The amount of recovery increases in the inside.

In addition, the device is stably operated using pneumatic pressure, and a packing is installed to prevent leakage of refrigerant during recovery, and after recovery, the refrigerant pipe is easily separated and the refrigerant recovery pipe is closed to close the recovery pipe. By preventing air from entering, the refrigerant can be easily recovered and the working efficiency can be increased.

1 illustrates a conventional refrigerant recovery apparatus.
2 is a perspective view of a refrigerant recovery apparatus according to an embodiment of the present invention.
3 is a cross-sectional view of a refrigerant recovery device.
Figure 4 shows a configuration for driving the movement of the bracket, opening and closing of the refrigerant recovery pipe, and the operation of the needle.
5a to 5c illustrate the operation of the refrigerant recovery device in order.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of a refrigerant recovery device according to an embodiment of the present invention, Figure 3 is a cross-sectional view of the refrigerant recovery device.

2 and 3, the refrigerant recovery device 100 includes a body 120 having a hollow portion 122, a needle 140 movably mounted in the hollow portion 122 of the body 120, It includes a bracket 160 that is mounted to be movable to be close to or spaced apart from the upper surface of the body (120). The needle 140 and the bracket 160 may be mounted and move with a cylinder operated by pneumatic pressure.

A packing lower seating portion having a larger diameter than the hollow portion 122 is formed at an upper portion of the body 120. The packing lower seating part is provided with a packing lower 124. The packing lower 124 is formed with a through hole 125 through which the end 142 of the needle 140 penetrates and the refrigerant in the refrigerant pipe can be discharged. Thus, the end 142 of the needle 140 can pass completely through the packing lower 124 through the through hole 125, and also in the coolant tube bored by the end 142 of the needle 140. The refrigerant may be discharged through the through hole 125.

A refrigerant outlet 126 is formed at a lower portion of the packing lower seating portion in which the packing lower 124 is mounted. A refrigerant recovery pipe 128 is connected to the refrigerant discharge port 126, and a vacuum pump is connected to the refrigerant recovery pipe 128. Therefore, the refrigerant of the refrigerant pipe may exit through the through hole 125 of the packing lower 124, and then be discharged and recovered through the refrigerant outlet 126 and the refrigerant recovery pipe 128. At this time, the refrigerant may be easily discharged by the suction force of the vacuum pump of the refrigerant recovery pipe 128.

In addition, two shaft guide holes are formed in the body 120. The shaft 164 of the bracket 160 is movably inserted into the shaft guide hole.

Meanwhile, the needle 140 includes a needle body 144 and a needle end 142. Needle body 144 is preferably formed of the same diameter as the hollow portion 122 of the body (120). Since the needle body 144 fits into the hollow portion 122 of the body 120, the refrigerant discharged through the through hole 125 is transferred between the needle body 144 and the hollow portion 122 of the body 120. It may not leak. The needle end 142 is formed to have a smaller diameter than the needle body 144, and has a tapered shape that gradually becomes sharper toward the end. Therefore, when the pointed end of the needle end 142 is pressed against the refrigerant pipe, a hole may be drilled in the refrigerant pipe.

The upper portion of the body 120 is equipped with a movable bracket 160 to move closer to or spaced apart from the upper surface of the body 120. Two shafts 164 are attached to the bracket 160, and the shafts 164 are movably inserted into the shaft guide holes of the body 120. Therefore, the bracket 160 may move to be close to or spaced apart from the upper surface of the body 120 along the shaft guide hole.

A packing upper seating part is formed at a lower portion of the bracket 160, and a packing upper 162 is installed at the packing upper seating part. The bottom of the packing upper 162 is formed with a groove 163 to accommodate the end of the needle end 142. Therefore, the needle end 142 penetrating the refrigerant pipe may move to the groove portion 163 of the packing upper 162.

4 illustrates a configuration for driving the movement of the bracket 160, the opening and closing of the refrigerant recovery pipe 128, and the operation of the needle 140.

4, the movement of the bracket 160 and the opening and closing of the refrigerant recovery pipe 128 are simultaneously controlled by the first pneumatic solenoid valve 180, and the operation of the needle 140 is performed by the second pneumatic solenoid valve 182. Is controlled by

First, the movement of the bracket 160 and the opening and closing of the refrigerant recovery pipe 128 will be described. When the first pneumatic solenoid valve 180 is turned on by operating a switch, the pneumatic cylinder 166 connected to the shaft 164 of the bracket 160 moves the shaft 164 downward so that the bracket 160 is moved to the body ( Move close to 120). When the bracket 160 is close to the body 120, a refrigerant pipe disposed between the bracket 160 and the body 120 is inserted and fixed between the bracket 160 and the body 120. At this time, the upper packing 162 of the bracket 160 and the lower packing 124 of the body 120 is in close contact with the upper and lower sides of the refrigerant pipe. In addition, the bracket 160 moves and the opening / closing pneumatic solenoid valve 129 opens the refrigerant recovery pipe 128.

Thus, by turning on the first pneumatic solenoid valve 180, the refrigerant pipe is inserted and fixed between the bracket 160 and the body 120, the opening and closing pneumatic solenoid valve 129 opens the refrigerant recovery pipe 128 The preparation for recovering the coolant is completed.

Next, the operation of the needle 140 will be described. When the switch installed in the second pneumatic solenoid valve 182 is pressed, the needle 140 moves upward along the hollow portion 122 of the body 120 by the pneumatic cylinder 146 that operates the needle 140. When the needle 140 moves upward, the needle end 142 moves along the through hole 125 of the packing lower 124. The needle end 142 penetrates through the refrigerant pipe and moves to the groove 163 of the packing upper 162. Then, when the switch is released, the needle 140 moves back to the lower portion of the body 120 and is returned to its original position.

As such, when the needle 140 moves upward by operating the second pneumatic solenoid valve 182 and then returns downward, a hole is drilled in the refrigerant pipe fixed between the bracket 160 and the body 120. .

When a hole is drilled in the coolant pipe, the coolant in the coolant pipe comes out of the hole. The refrigerant may be discharged and recovered through the through hole 125 of the packing lower 124, the hollow portion 122 of the body 120, the refrigerant outlet 126, and the refrigerant recovery pipe 128. At this time, the refrigerant may be easily discharged by the suction force of the vacuum pump of the refrigerant recovery pipe 128. On the other hand, since the packing lower 124 and the packing upper 162 are sealed in the hole of the refrigerant pipe, the refrigerant does not leak outside the through hole 125 of the packing lower 124.

When the recovery of the refrigerant is completed, the switch of the first pneumatic solenoid valve 180 is turned off. When the first pneumatic solenoid valve 180 is turned off, the pneumatic cylinder 166 connected to the shaft 164 of the bracket 160 moves the shaft 164 upwards so that the bracket 160 is spaced apart from the body 120. Make a move. When the bracket 160 is spaced apart from the body 120, the bracket 160 may be inserted between the bracket 160 and the body 120 to remove the fixed refrigerant pipe.

In addition, the opening and closing pneumatic solenoid valve 129 closes the refrigerant recovery pipe 128 with the movement of the bracket 160. Since the refrigerant recovery pipe 128 is closed at the same time as the refrigerant pipe is separated, air is not introduced into the refrigerant recovery pipe 128 so that only pure refrigerant can be recovered.

5a to 5c illustrate the operation of the refrigerant recovery device in order. When the refrigerant pipe is installed between the bracket 160 and the body 120 and the first pneumatic solenoid valve 180 is turned on, the bracket 160 moves downward to allow the refrigerant pipe between the bracket 160 and the body 120. And a pneumatic solenoid valve 129 open at the same time to open the refrigerant recovery pipe 128 (see Fig. 5A). In this state, when the needle 140 is moved upward by operating the second pneumatic solenoid valve 182, the needle 140 penetrates through the coolant pipe and drills a hole in the coolant pipe (see FIG. 5B). Then, when the needle 140 returns downward, the refrigerant is discharged through the drilled hole of the refrigerant pipe. The coolant is discharged through the through hole 125 of the packing lower 124, the hollow part 122 of the body 120, the coolant outlet 126, and the coolant recovery tube 128 (see FIG. 5C).

As described above, according to the present invention, since the needle makes a hole in the refrigerant pipe and returns to the original position after recovering the refrigerant, the refrigerant is recovered through the hole so that a large hole size for securing the flow path can be secured. The recovery amount is increased within the same time as. In fact over 30% of the refrigerant has been recovered.

In addition, the device is stably operated using pneumatic pressure, and a packing is installed to prevent leakage of refrigerant during recovery, and after recovery, the refrigerant pipe is easily separated and the refrigerant recovery pipe is closed to close the recovery pipe. By preventing air from entering, the refrigerant can be easily recovered and the working efficiency can be increased.

100 refrigerant recovery unit 120 body
122 Hollow Section 124 Packing Lower
126 Refrigerant outlet 128 Refrigerant recovery line
140 needle 142 needle end
144 needle body 160 bracket
162 Packing Upper 163 Grooving
180 first pneumatic solenoid valve
182 2nd Pneumatic Solenoid Valve

Claims (9)

A body 120 having a hollow portion 122,
Needle 140 is movably mounted in the hollow portion 122 of the body 120,
A bracket 160 that is movably mounted to be close to or spaced apart from an upper surface of the body 120, and
Refrigerant recovery pipe 128 is installed to communicate with the hollow portion 122 of the body 120,
When the needle 140 makes a hole in the refrigerant pipe disposed between the body 120 and the bracket 160, the refrigerant of the refrigerant pipe is discharged through the refrigerant recovery pipe 128. Device. The method according to claim 1,
The packing lower 124 is installed on the upper portion of the body 120,
Refrigerant recovery apparatus, characterized in that the packing upper 162 is installed below the bracket (160). The method according to claim 2,
The packing lower (124) is a refrigerant recovery device characterized in that the through-hole (125) through which the needle (140) can pass, through which the refrigerant can be discharged is formed. The method according to claim 3,
Refrigerant recovery apparatus characterized in that the bottom portion of the packing upper (162) is formed with a groove portion (163) for accommodating the tip of the needle (140). The method according to claim 1,
The body 120 has a shaft guide hole in which the shaft 164 of the bracket 160 is movably mounted and a pneumatic cylinder 166 for operating the shaft 164 of the bracket 160 is installed. Refrigerant recovery device. The method according to claim 5,
The refrigerant recovery pipe (128) is a refrigerant recovery device, characterized in that the opening and closing pneumatic solenoid valve (129) for opening or closing the refrigerant recovery pipe (128) is installed. The method of claim 6,
The cylinder (166) and the opening and closing pneumatic solenoid valve (129) is a refrigerant recovery device, characterized in that simultaneously operated by the first pneumatic solenoid valve (180). The method according to claim 7,
When the first pneumatic solenoid valve 180 is turned on, the bracket 160 moves to approach the body 120 and the open / close pneumatic solenoid valve 129 opens the refrigerant recovery pipe 128. Works,
When the first pneumatic solenoid valve 180 is turned off, the bracket 160 moves to be spaced apart from the body 120, and the open / close pneumatic solenoid valve 129 closes the refrigerant recovery pipe 128. Refrigerant recovery device characterized in that the operation. The method according to claim 1,
The body 120 is equipped with a pneumatic cylinder 146 for operating the needle 140,
And the pneumatic cylinder (146) is operated by a second pneumatic solenoid valve (182).

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