KR101214755B1 - System for refrigerant collection and apparatus for refrigerant collection use for the same - Google Patents

Abstract

PURPOSE: A refrigerant recovery system and a refrigerant recovery device used in the same are provided to recirculate and store refrigerant which is not liquefied stored in a storage tank, thereby efficiently recovering and storing refrigerant. CONSTITUTION: A refrigerant recovery and storage device consists of a refrigerant recovery device and an external storage tank assembly. A first pressure detection sensor and a first solenoid valve are disposed in a refrigerant recovery fluid path, and the first pressure detection sensor may control opening and closing of the first solenoid value if predetermined range varies, thereby controlling operation for refrigerant recovery. A first flexible fluid path, connecting the refrigerant recovery fluid path and the refrigerant recovery tank and a second flexible fluid path, connecting the refrigerant recovery tank and the refrigerant outlet port, are disposed in the refrigerant recovery device. The edge of the outlet port in the refrigerant storage tank is placed higher than the edge of the inlet port.

Description

REFRIGERANT COLLECTION AND APPARATUS FOR REFRIGERANT COLLECTION USE FOR THE SAME

The present invention relates to a refrigerant recovery system and a refrigerant recovery device used therein, and more particularly, to a refrigerant recovery by separating a storage tank for storing the liquefied refrigerant in the refrigerant recovery device for liquefying the refrigerant recovered from the refrigerant recovery object. In addition to making the device compact, a refrigerant recovery system capable of efficiently recovering and storing refrigerant, and a refrigerant recovery device used therein, can be recovered by storing the refrigerant that has not been liquefied among the refrigerant stored in the storage tank into the refrigerant recovery device. It is about.

Recently, as small refrigerators such as air conditioners, refrigerators, and water purifiers are widely used for vehicle air conditioners or households, disposal of refrigerants included in these refrigerators has emerged as an important environmental problem.

In particular, chlorofluorocarbon (CFC) refrigerants such as R-11 and R-12 and chlorofluorocarbon (HCFC) refrigerants such as R-123 and R-22 are the main culprit of ozone depletion and global warming. Hydrogen fluorocarbon (HFC) -based refrigerants are defined as global warming materials and need to be strictly managed so as not to be released into the atmosphere by recovering and appropriately treating them.

For example, when disposing of a vehicle, air conditioner refrigerants must be recovered first, but until now, there are very few junkyards equipped with facilities for recovering air conditioner refrigerants of vehicles. Even if there is a facility to recover the refrigerant, the recovery efficiency is very low in the external environment factors, that is, seasonal factors such as summer and high temperature working environment, so the refrigerant is often leaked into the atmosphere during the junk car process.

This problem applies to the disposal of other small refrigerators such as refrigerators and domestic air conditioners.

Therefore, in order to solve such a problem, a refrigerant recovery device capable of efficiently recovering refrigerant of a plurality of small refrigerators such as a vehicle air conditioner, a domestic air conditioner, a refrigerator, a water purifier, and the like has been disclosed.

However, the conventional refrigerant recovery apparatus includes a first refrigerant recovery tank for primarily cooling the refrigerant recovered therein, and a second refrigerant recovery tank for storing the refrigerant cooled in the first refrigerant recovery tank. As the recovery device has become larger, there are inefficient problems in transportation and storage.

In addition, the conventional refrigerant recovery apparatus is a system for storing the refrigerant cooled primarily in the first refrigerant recovery tank in the second refrigerant recovery tank secondaryly, so that the uncooled refrigerant is stored in the second refrigerant recovery tank to supply the refrigerant. There was a problem that can not be stored efficiently. In particular, the refrigerant stored in the second refrigerant recovery tank is not recycled back to the first refrigerant recovery tank, so there is a problem in that the refrigerant cannot be efficiently recovered and stored.

According to an aspect of the present invention, a refrigerant recovery system capable of compacting a refrigerant recovery apparatus by separating a storage tank for storing liquefied refrigerant from a refrigerant recovery apparatus for liquefying a refrigerant recovered from a refrigerant recovery object and a refrigerant used therein It is providing a recovery apparatus.

Another aspect of the present invention is to provide a refrigerant recovery system and a refrigerant recovery device that can be recovered and stored efficiently because the refrigerant can not be liquefied in the refrigerant stored in the storage tank can be recycled to the refrigerant recovery device have.

Still another aspect of the present invention is to provide a refrigerant recovery system and a refrigerant recovery apparatus used therefor, which can improve efficiency since the recovery and liquefaction of the refrigerant from the refrigerant recovery object can be performed simultaneously with the recycling cycle.

Another aspect of the present invention is to provide a refrigerant recovery system and a refrigerant recovery device used therein so as to provide a secondary storage tank in front of the refrigerant recovery tank so that the refrigerant can be recovered stably and smoothly.

The refrigerant recovery and storage device according to an embodiment of the present invention, the first refrigerant recovery port and the second refrigerant recovery port which is distinct from the first refrigerant recovery port to form an appearance and detachably connected to the refrigerant recovery target object And a refrigerant recovery tank disposed within the main body, the refrigerant recovery tank configured to recover the refrigerant along the recovery flow path from the refrigerant recovery object connected to the first refrigerant recovery port, and disposed in the main body and provided in the recovery flow path. A first compressor for providing a pressure for recovering the coolant, and a coolant recovery tank disposed inside the main body and connected to the coolant recovery tank to liquefy the coolant introduced from the coolant recovery tank to discharge the coolant through the coolant discharge port; And a second compressor for compressing the heat exchange refrigerant and condensing the heat exchange refrigerant via the second compressor. Is a refrigerant recovery device including a condenser, a cooling cycle device including an evaporator for liquefying gaseous refrigerant introduced into the refrigerant recovery tank, and an expansion valve provided between the evaporator and the condenser; A refrigerant storage tank disposed externally, an inflow port for supplying refrigerant discharged from the refrigerant discharge port to the refrigerant storage tank connected to the refrigerant discharge port and the first recirculation flow path, and the second refrigerant recovery port and the second refrigerant recovery port; An external storage tank assembly connected to a recirculation flow path and having an outlet port for recirculating the refrigerant that has not been liquefied in the refrigerant storage tank to the refrigerant recovery device, and adjacent to the first and second refrigerant recovery ports. A first pressure sensor and a first solenoid valve are sequentially disposed in the refrigerant recovery flow path. When the first pressure sensor is out of a preset range, the first pressure sensor controls the operation of the refrigerant recovery by controlling the opening and closing of the first solenoid valve, and inside the refrigerant recovery device, the refrigerant recovery passage and And a first flexible flow path connecting the coolant recovery tank and a second flexible flow path connecting the coolant recovery tank and the coolant discharge port.

In addition, the end of the outlet port is characterized in that it is disposed in a position higher than the end of the inlet port in the interior of the external storage tank.

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In addition, the refrigerant recovery device includes a main body forming the external appearance, a load cell provided at a lower end of the refrigerant recovery tank in the main body, and measuring the weight of the refrigerant recovery tank, and a side end of the refrigerant recovery tank in the main body. It is characterized in that provided with a temperature sensor for measuring the temperature of the refrigerant recovery tank.

In addition, the refrigerant recovery device further comprises an auxiliary storage tank provided in the refrigerant recovery flow path for primarily storing the refrigerant between the refrigerant recovery port and the first compressor.

In addition, the refrigerant recovery apparatus includes a weight indicator attached to the outer surface of the main body to display the information measured on the load cell, and a temperature indicator attached to the outer surface of the main body to display the information measured by the temperature sensor It is characterized by.

In addition, the refrigerant recovery device, characterized in that provided with a pressure indicator attached to the outer surface of the main body to display the information measured by the first pressure sensor.

The coolant recovery device further includes a sight glass for checking the flow rate of the coolant provided on the recovery flow passage adjacent to the recovery port.

Refrigerant recovery apparatus according to an embodiment of the present invention is disposed outside the main body of the refrigerant recovery device for storing the refrigerant discharged from the main body of the refrigerant recovery device recycled to the main body of the refrigerant recovery device for the refrigerant that has not been liquefied to the main body of the refrigerant recovery device It characterized in that it comprises a flow path. A main body having an external appearance and having at least one first coolant recovery port and a second coolant recovery port distinct from the first coolant recovery port, the second coolant recovery port being detachably connected to the refrigerant recovery object; A refrigerant recovery tank for recovering refrigerant along the recovery flow path from the refrigerant recovery object connected to the refrigerant recovery port, and a first compressor disposed inside the main body and provided in the recovery flow path to provide a pressure for recovering the refrigerant; A second compressor disposed inside the main body and connected to the refrigerant recovery tank to be connected to the refrigerant recovery tank to compress the heat exchange refrigerant in order to liquefy the refrigerant introduced from the refrigerant recovery tank to discharge the refrigerant through the refrigerant discharge port; A condenser for condensing the heat exchange refrigerant via a second compressor, and a device introduced into the refrigerant recovery tank; And a cooling cycle apparatus including an evaporator for liquefying the refrigerant, and an expansion valve provided between the evaporator and the condenser, wherein the refrigerant recovery flow path adjacent to the first and second refrigerant recovery ports includes a first pressure sensing sensor; When the first solenoid valve is sequentially disposed outside the preset range of the first pressure sensor, the first pressure sensor controls the opening and closing of the first solenoid valve to control the operation of the refrigerant recovery, and the refrigerant recovery. The inside of the apparatus is characterized by having a first flexible flow path connecting the coolant recovery flow path and the coolant recovery tank, and a second flexible flow path connecting the coolant recovery tank and the coolant discharge port.

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Accordingly, the refrigerant recovery system and the refrigerant recovery apparatus used therein are separated from the storage tank for storing the liquefied refrigerant in the refrigerant recovery apparatus for liquefying the refrigerant recovered from the refrigerant recovery object. In addition to making it compact, the refrigerant that has not been liquefied out of the refrigerant stored in the storage tank can be recycled and stored in the refrigerant recovery device, thereby effectively recovering and storing the refrigerant.

In addition, since the refrigerant recovery system and the refrigerant recovery apparatus used therein according to the embodiment of the present invention can perform the recovery and liquefaction of the refrigerant from the refrigerant recovery object at the same time as the recycle cycle has the effect of improving the efficiency. .

In addition, the refrigerant recovery system according to an embodiment of the present invention and the refrigerant recovery apparatus used therein is provided with an auxiliary storage tank in front of the refrigerant recovery tank has the effect of allowing the refrigerant to be recovered stably and smoothly.

1 is a view showing a refrigerant recovery system according to an embodiment of the present invention.
2 is a perspective view showing a refrigerant recovery apparatus according to an embodiment of the present invention.
3 is an enlarged view of a refrigerant recovery tank and a cooling cycle apparatus of the refrigerant recovery device illustrated in FIG. 2.
4 is a view showing an external storage tank according to an embodiment of the present invention.
5 is a view showing a refrigerant recovery system according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing a refrigerant recovery system according to an embodiment of the present invention, Figure 2 is a perspective view showing a refrigerant recovery device according to an embodiment of the present invention, Figure 3 is a refrigerant recovery device of FIG. The enlarged figure shows a refrigerant recovery tank and a cooling cycle apparatus.

1 to 3, the refrigerant recovery system 10 according to an embodiment of the present invention, the refrigerant recovery to provide a movement path from the refrigerant recovery target object 20 connected to the refrigerant recovery port 140A. A refrigerant recovery tank 110 for recovering refrigerant along the flow path 140, a first compressor 120 provided in the refrigerant recovery flow path 140 to provide a pressure for recovering the refrigerant, and a refrigerant recovery tank 110. A refrigerant recovery device (100) having a cooling cycle device (130) connected to the liquefied refrigerant introduced from the refrigerant recovery tank (110) to discharge the refrigerant through the refrigerant discharge port (110A); A refrigerant storage tank 210 disposed outside the 100 and an inlet port 220 connected to the refrigerant discharge port 110A to supply refrigerant discharged from the refrigerant discharge port 110A to the refrigerant storage tank 210. And a recirculation flow path 240 connected to the refrigerant recovery port 140A. And an external storage tank assembly 200 having an outlet port 230 for recirculating the refrigerant not liquefied by the refrigerant storage tank 210 to the refrigerant recovery device 100 through the refrigerant storage tank 210.

Refrigerant recovery apparatus 100 according to an embodiment of the present invention, the refrigerant recovery flow path 140 is formed with a main body (100A) to form the appearance, and a refrigerant recovery port 140A provided in the interior of the body (100A). , The first compressor 120, the refrigerant recovery tank 110 in which the refrigerant discharge port 110A is formed, the cooling cycle device 130, the weight indicator 100B provided on the outer surface of the main body 100A, and the pressure indicator 100C. ) And a temperature indicator 100D.

The main body 100A forms an outer appearance of the refrigerant recovery device 100 and may have an approximately rectangular parallelepiped shape.

The refrigerant recovery passage 140, the first compressor 120, the refrigerant discharge port 110A, and the refrigerant recovery tank 110 having the refrigerant recovery port 140A formed therein, and the refrigerant recovery tank 110 are formed inside the main body 100A. Cooling cycle apparatus 130 having an evaporator 133 for liquefying the refrigerant stored therein is provided in sequence.

The refrigerant recovery tank 110 recovers and stores the refrigerant recovered from the refrigerant recovery object 20. Here, the refrigerant recovery tank 110 of the refrigerant recovery device 100 primarily stores the gaseous phase refrigerant and the liquid phase refrigerant recovered from the refrigerant recovery object 20, and the refrigerant recovery tank 110 may include a cooling cycle device (described later) ( The liquid phase refrigerant may be changed and stored by liquefying the gas phase refrigerant among the stored gas phase refrigerant and the liquid phase refrigerant through 130).

The coolant recovery channel 140 serves to provide a movement path between the coolant recovery object 20 and the coolant recovery tank 110 so that the coolant in the coolant recovery object 20 moves to the coolant recovery tank 110.

A plurality of refrigerant recovery ports 140A are formed at one end of the refrigerant recovery flow path 140. The refrigerant recovery port 140A is connected to the refrigerant recovery object and the external storage tank assembly 200 to be described later so that the refrigerant recovery object 20 can be recovered and liquefied at the same time as the recycling cycle.

The refrigerant recovery port 140A includes at least one first refrigerant recovery port 141A that is detachably connected to the refrigerant recovery object 20, and a second refrigerant recovery that is detachably connected to the refrigerant storage tank 210. Port 142A may be included.

The first refrigerant recovery port 141A may be detachably connected to the refrigerant recovery object 20, and at the same time, a plurality of refrigerant recovery ports 140A may be provided to be connected to the plurality of refrigerant recovery objects 20. Of course.

The second refrigerant recovery port 142A recovers a gaseous refrigerant that has not been liquefied among the refrigerants stored in the refrigerant storage tank 210 to be described later, recycles it through the recirculation flow path 240, and then recirculates a recirculating movement path for changing into a liquid refrigerant. It may be detachably connected with the external storage tank assembly 200 to provide.

The first pressure detecting sensor 141, the first solenoid valve 142, the sight glass 143, and the filter 144 are provided in the refrigerant recovery flow path 140 adjacent to the first and second refrigerant recovery ports 141A and 142A. Are arranged sequentially.

The first pressure sensor 141 detects the pressure when the refrigerant is recovered from the refrigerant recovery object 20 and the refrigerant storage tank 210 through the first refrigerant recovery port 141A and the second refrigerant recovery port 142A. Allow the refrigerant to start or stop automatically.

That is, when the first pressure sensor 141 is out of the preset range, the first pressure sensor 141 controls the opening and closing of the first solenoid valve 142 to control the operation of the refrigerant recovery.

For example, the refrigerant recovery target 20 and the first refrigerant recovery port 141A are connected to each other, and the refrigerant storage tank 210 and the second refrigerant recovery port 142A are connected to the first pressure sensor 141 in advance. When a pressure value higher than the set pressure value is detected, the refrigerant recovery object 20 and the refrigerant in the refrigerant storage tank 210 are recognized, and the first solenoid valve 142 is opened to recover the refrigerant, When the low pressure value is sensed, the refrigerant recovery object 20 and the refrigerant recovery and recirculation within the refrigerant storage tank 210 are completed to close the first solenoid valve 142.

Therefore, since the refrigerant recovery device 100 according to the embodiment of the present invention automatically opens and closes the first solenoid valve 142 according to the detected pressure in the first pressure detection sensor 141, the entire drive of the refrigerant recovery device 100 is performed. It is possible to continuously recover the refrigerant from the refrigerant recovery object 20 and the refrigerant storage tank 210 without stopping.

On the other hand, the filter 144 is interposed between the first solenoid valve 142 and the first compressor 120 to filter the foreign matter contained in the refrigerant.

In addition, a sight glass 143 is provided between the filter 144 and the first solenoid valve 142 to check the flow rate of the refrigerant.

The first compressor 120 allows the refrigerant to flow into the refrigerant recovery tank 110 from the refrigerant recovery object 20 and the refrigerant storage tank 210 between the refrigerant recovery tank 110 and the refrigerant recovery port 140A. Sustain suction of the refrigerant to improve the recovery rate of the.

That is, the first compressor 120 forms the inside of the refrigerant recovery tank 110 in an initial vacuum state, and converts the refrigerant from the refrigerant recovery object 20 and the refrigerant storage tank 210 to the refrigerant recovery tank 110 by the pressure difference. Allow inflow.

The cooling cycle device 130 is connected to the refrigerant recovery tank 110 to exchange heat with the gaseous refrigerant introduced into the refrigerant recovery tank 110 to liquefy the gaseous refrigerant into a liquid refrigerant.

The coolant recovery tank 110 recovers the coolant from the coolant recovery object by the pressure difference. That is, the refrigerant recovery tank 110 is the evaporator 133 of the cooling cycle apparatus 130 inside the refrigerant recovery tank 110 after the refrigerant recovery tank 110 is initialized to a vacuum state by the driving of the first compressor 120. Cool the refrigerant flowing in through).

Therefore, by lowering the pressure inside the refrigerant recovery tank 110, the refrigerant is collected by the pressure difference between the refrigerant recovery object 20 and the refrigerant storage tank 210, and the first compressor for maintaining suction to improve the refrigerant recovery speed ( 120 is driven to collect the refrigerant.

The refrigerant recovery tank 110 is provided with a second pressure sensor 111 and a second solenoid valve 112 so that the pressure inside the refrigerant recovery tank 110 may be set in advance to the second pressure detection sensor 111. When detected in excess, the second solenoid valve 112 is automatically opened to lower the internal pressure.

The second solenoid valve 112 may also function to secure the space occupied by the refrigerant flowing from the refrigerant recovery object 20 and the refrigerant storage tank 210 by discharging the remaining gas in the refrigerant recovery tank 110 to the outside. Can be.

In addition, the refrigerant recovery tank 110 is provided with a temperature sensor 113 to control the operation of the cooling cycle device 130 when out of the range of the preset value.

In addition, when the load cell 114 is installed in the refrigerant recovery tank 110 and the predetermined amount of liquid refrigerant is filled in the refrigerant recovery tank 110, the driving of the first compressor 120 is stopped and the refrigerant storage tank 210 is stopped. Transfer liquid refrigerant.

The cooling cycle device 130 includes a second compressor 131 connected to the refrigerant recovery tank 110, a condenser 132 connected to the second compressor 131, and one side of the cooling cycle device 130 connected to the second compressor 131. It is connected to the condenser 132, and includes an evaporator 133 and the expansion valve 134 interposed between the evaporator 133 and the condenser 132 is circulated in the liquid heat exchange refrigerant.

The second compressor 131 compresses the heat exchange refrigerant in the cooling cycle apparatus 130, the condenser 132 condenses the heat exchange refrigerant via the second compressor 131, and the expansion valve 134 is the condenser 132. The heat exchange refrigerant is expanded through the evaporator, and the evaporator 133 liquefies the gaseous refrigerant introduced into the refrigerant recovery tank 110 through the heat exchange refrigerant via the expansion valve 134.

That is, the evaporator 133 is disposed in the refrigerant recovery tank 110 to convert the gaseous refrigerant into a liquid phase by heat exchange between the gaseous refrigerant introduced into the refrigerant recovery tank 110 and the heat exchange refrigerant in the evaporator 133.

In the cooling cycle apparatus 130 according to the embodiment of the present invention, first, when the liquefaction of the gaseous phase refrigerant in the refrigerant recovery tank 110 is required, the second compressor 131 is driven, the second compressor 131 The high-temperature, high-pressure heat exchange refrigerant compressed at is directed toward the condenser 132 and condensed through the condenser 132. The condensed heat exchange refrigerant flows into the expansion valve 134 and expands into a low temperature and low pressure state to liquefy and evaporate the gaseous refrigerant in the evaporator 133.

In particular, the evaporator 133 of the cooling cycle apparatus 130 according to an embodiment of the present invention is disposed in the refrigerant recovery tank 110 to directly heat exchange with the gaseous refrigerant, thereby increasing the conversion rate of the recovered gaseous refrigerant, Therefore, it is possible to promote the final refrigerant recovery to the refrigerant storage tank 210.

Meanwhile, a filter drier 135 may be interposed between the expansion valve 134 and the condenser 132 to remove moisture and foreign matter included in the heat exchange refrigerant, thereby improving heat exchange efficiency in the refrigerant recovery tank 110.

In addition, any part of connecting the refrigerant recovery channel 140 and the refrigerant recovery tank 110 may be formed as the flexible channel 145, and also connects the refrigerant recovery tank 110 and the refrigerant discharge port 110A. Some of the flexible flow paths 115 may be formed. The flexible flow paths 145 and 115 may be used to form free flow paths, and at the same time, the refrigerant recovery tank 110, the first compressor 120, and the refrigerant recovery path 140 may be formed. ), So that the operation of connecting and dismantling the refrigerant discharge port (110A) can be made easily.

On the outer surface of the main body 100A, a weight indicator 100B, a pressure indicator 100C, and a temperature indicator 100D are provided.

The weight indicator 100B is attached to the outer surface of the main body 100A of the refrigerant recovery device 100 to display the measured information on the load cell 114.

The temperature indicator 100D is attached to the outer surface of the main body 100A of the refrigerant recovery device 100 to display information measured by the temperature sensor 113.

The pressure indicator 100C is attached to the outer surface of the main body 100A of the refrigerant recovery device 100 to display information measured by the first pressure sensor 141.

Therefore, the refrigerant recovery apparatus 100 according to an embodiment of the present invention includes the weight of the refrigerant recovered in the refrigerant recovery apparatus 100 through the weight indicator 100B, the temperature indicator 100D, and the pressure indicator 100C. The temperature inside the coolant recovery tank 110 and the pressure of the coolant recovered through the coolant recovery flow passage 140 may be grasped in real time to enable a user to efficiently recognize the operation state of the coolant recovery device 100.

In addition, the exterior of the refrigerant recovery device 100 is provided with an external storage tank assembly 200 for performing a recycle cycle while storing the refrigerant liquefied in the refrigerant recovery device 100. 4 is a view showing an external storage tank assembly according to an embodiment of the present invention.

As shown in FIG. 4, the external storage tank assembly 200 according to an embodiment of the present invention includes a refrigerant storage tank 210 and a refrigerant discharge port 110A disposed outside the refrigerant recovery device 100. Is connected to the inlet port 220 for supplying the refrigerant discharged from the refrigerant discharge port 110A to the refrigerant storage tank 210 and the refrigerant recovery port 140A to be liquefied in the refrigerant storage tank 210. Outlet port 230 for recycling the failed refrigerant to the refrigerant recovery device 100 is provided.

Here, the end of the outlet port 230 is disposed at a position higher than the end of the inlet port 220 in the inside of the refrigerant storage tank 210, so that the end of the outlet port 230 is higher than the end of the inlet port By being disposed at the location, the gaseous refrigerant that has not been liquefied can flow out naturally through the recirculation flow path 240.

The recirculation flow path 240 may include a first recirculation flow path 241 connecting the refrigerant recovery port 142A and the outlet port 230, and a second recirculation flow path connecting the refrigerant discharge port 110A and the inflow port 220. And 242.

Therefore, the refrigerant stored in the refrigerant storage tank 210 again passes through the refrigerant recovery port 140A of the refrigerant recovery device 100 through the recirculation flow path 240, and again, the refrigerant recovery tank 110 of the refrigerant recovery device 100. It is possible to recycle a plurality of times to remove the gaseous refrigerant still present in the refrigerant storage tank 210 by supplying to.

This is because the refrigerant recovered by repeated liquefaction through the evaporator 133 of the cooling cycle apparatus 130 disposed in the refrigerant recovery tank 110 of the refrigerant recovery apparatus 100 is optimally stored in the refrigerant storage tank 210. To be possible.

In addition, since the recovery of the refrigerant from the refrigerant recovery object 20 and the liquefaction process can be performed simultaneously with the recycling cycle, the efficiency of the refrigerant recovery system 10 is improved.

Meanwhile, the coolant storage tank 210 may be detachably connected to the coolant recovery tank 110, and may be separated and replaced with a new coolant storage tank 210 when quantitatively filled liquid refrigerant is filled therein.

In the refrigerant recovery apparatus 100 according to the exemplary embodiment of the present invention, the evaporator 133 of the cooling cycle apparatus 130 may be disposed in the refrigerant recovery tank 110 to prevent the refrigerant recovery object 20 and the refrigerant storage tank 210. When the gaseous refrigerant recovered in the refrigerant recovery tank 110 is converted into a liquid refrigerant, the refrigerant is cooled by a direct cooling method to improve the liquefaction rate of the recovered refrigerant.

In addition, a discharge path for discharging the remaining gas in the refrigerant recovery tank 110 is formed so that the space occupied by the refrigerant flowing from the refrigerant recovery object 20 and the refrigerant storage tank 210 is not disturbed by the remaining gas. The refrigerant may be occupied by the space occupied by the remaining gas to improve the recovery rate of the refrigerant recovered into the refrigerant recovery tank 110.

Therefore, even if the final refrigerant recovery using the refrigerant recovery tank 110 of the same size as the conventional, the filling rate is high, the refrigerant recovery tank 110 does not need to be made larger than necessary, so it is compact and transport of the refrigerant recovery device And it becomes efficient also in storage.

Another embodiment of the present invention will be described with reference to Fig. The same reference numerals are assigned to the same components as those of the above-described embodiment, and a description thereof will be omitted. 5 is a view showing a refrigerant recovery system according to another embodiment of the present invention.

As shown in FIG. 5, the refrigerant recovery system 10 ′ according to another embodiment of the present invention provides a refrigerant recovery passage 140 that provides a movement path from the refrigerant recovery object 20 connected to the refrigerant recovery port 140A. Refrigerant recovery tank 110 for recovering the refrigerant along the), the first compressor 120 provided in the refrigerant recovery flow path 140 to provide a pressure for recovering the refrigerant, and a refrigerant recovery port for smooth recovery of the refrigerant The auxiliary storage tank 150 provided in the refrigerant recovery flow path 140 to store the refrigerant primarily between the 140A and the first compressor 120, and the refrigerant recovery tank 110 connected to the refrigerant recovery tank 110. A refrigerant recovery device (100 ') having a cooling cycle device (130) for liquefying the refrigerant introduced from the discharge port through the refrigerant discharge port (110A); and is disposed outside the refrigerant recovery device (100'). In contact with the refrigerant storage tank 210 and the refrigerant discharge port (110A) The inlet port 220 for supplying the coolant discharged from the coolant discharge port 110A to the coolant storage tank 210 and the coolant recovery port 140A to be connected to the coolant storage tank 240. And an external storage tank assembly 200 having an outlet port 230 for recirculating the refrigerant not liquefied at 210 to the refrigerant recovery device 100.

The auxiliary storage tank 150 of the refrigerant recovery device 100 ′ according to another embodiment of the present invention recovers refrigerant from a refrigerant recovery object by a pressure difference, and is initialized to a vacuum state by a vacuum pump (not shown). The refrigerant is collected by the pressure difference with the refrigerant recovery object 20 in which the refrigerant to be recovered is accommodated. In particular, the auxiliary storage tank 150 stores the refrigerant primarily before the recovered refrigerant flows into the refrigerant recovery tank 110 so that the refrigerant recovery to the refrigerant recovery tank 110 is smoothly performed.

On the other hand, the auxiliary storage tank 150 is connected to the oil pump 160 can discharge the oil flowing into the auxiliary storage tank 150 by the specific gravity difference.

Therefore, the refrigerant recovery system 10 ′ according to another embodiment of the present invention may be smoothly recovered through the auxiliary storage tank 150 to be cooled by the cooling cycle apparatus 130 in the refrigerant recovery tank 110. Will be.

As described above, the refrigerant recovery system according to an embodiment of the present invention and the refrigerant recovery device used therein are separated from the storage tank for storing the liquefied refrigerant in the refrigerant recovery device for liquefying the refrigerant recovered from the refrigerant recovery object Not only can the refrigerant recovery device be compact, but also the refrigerant that has not been liquefied among the refrigerants stored in the storage tank can be recycled and stored in the refrigerant recovery device. Able to know. Therefore, many modifications may be made by those skilled in the art without departing from the scope and spirit of the present invention.

10,10 '... Refrigerant Recovery System 100,100' ... Refrigerant Recovery Unit
110.Refrigerant recovery tank 120 ... First compressor
130 Cooling cycle unit 140 Refrigerant recovery flow path
150 ... Secondary storage tank 160 ... Oil pump
200 ... external storage tank assembly 210 ... refrigerant storage tank
220 ... inflow port 230 ... outflow port
240 ... Recycle Euro

Claims (10)

A main body provided with at least one first coolant recovery port and a second coolant recovery port distinct from the first coolant recovery port, the outer shape being detachably connected to the refrigerant recovery object;
A refrigerant recovery tank disposed inside the main body to recover the refrigerant along the recovery flow path from the refrigerant recovery object connected to the first refrigerant recovery port, and a pressure disposed in the recovery flow path disposed inside the main body to recover the refrigerant; A first compressor providing a heat exchange refrigerant disposed in the main body and connected to the refrigerant recovery tank to be connected to the refrigerant recovery tank to liquefy the refrigerant introduced from the refrigerant recovery tank to discharge through the refrigerant discharge port. A second compressor for compressing, a condenser for condensing the heat exchange refrigerant through the second compressor, an evaporator for liquefying the gaseous refrigerant introduced into the refrigerant recovery tank, and an expansion valve provided between the evaporator and the condenser. Refrigerant recovery apparatus having a cooling cycle device to;
A refrigerant storage tank disposed outside the refrigerant recovery device, an inlet port connected to the refrigerant discharge port and a first recirculation flow path and supplying the refrigerant discharged from the refrigerant discharge port to the refrigerant storage tank, and the second And an external storage tank assembly connected to a refrigerant recovery port and a second recirculation flow path, the external storage tank assembly having an outlet port for recirculating the refrigerant not liquefied in the refrigerant storage tank to the refrigerant recovery device.
A first pressure sensor and a first solenoid valve are sequentially disposed in the refrigerant recovery flow path adjacent to the first and second refrigerant recovery ports so that the first pressure sensor is out of a predetermined range in the first pressure sensor. Controls the operation of the refrigerant recovery by controlling the opening and closing of the first solenoid valve,
The refrigerant recovery device includes a first flexible flow path connecting the coolant recovery flow path and a coolant recovery tank, and a second flexible flow path connecting the coolant recovery tank and the coolant discharge port. And storage devices. The method of claim 1,
And an end portion of the outlet port is disposed at a position higher than an end portion of the inlet port in the refrigerant storage tank. delete The method of claim 1,
The refrigerant recovery device,
A load cell installed at a lower end of the refrigerant recovery tank in the main body to measure a weight of the refrigerant recovery tank;
And a temperature sensing sensor installed at a side end of the refrigerant recovery tank in the body to measure a temperature of the refrigerant recovery tank. The method of claim 1,
The refrigerant recovery device,
And an auxiliary storage tank provided in the coolant recovery flow path to primarily store the coolant between the coolant recovery port and the first compressor. 5. The method of claim 4,
The refrigerant recovery device,
A weight indicator attached to an outer surface of the main body to display the measured information on the load cell;
And a temperature indicator attached to an outer surface of the main body to display information measured by the temperature sensor. The method of claim 1,
The refrigerant recovery device,
And a pressure indicator attached to an outer surface of the main body to display information measured by the first pressure sensor. The method of claim 1,
The refrigerant recovery device,
And a sight glass provided on the recovery flow path adjacent to the recovery port to check a flow rate of the refrigerant to be recovered. A main body provided with at least one first coolant recovery port and a second coolant recovery port distinct from the first coolant recovery port, the outer shape being detachably connected to the refrigerant recovery object;
A refrigerant recovery tank disposed inside the main body to recover the refrigerant along the recovery flow path from the refrigerant recovery object connected to the first refrigerant recovery port, and a pressure disposed in the recovery flow path disposed inside the main body to recover the refrigerant; A first compressor providing a heat exchange refrigerant disposed in the main body and connected to the refrigerant recovery tank to be connected to the refrigerant recovery tank to liquefy the refrigerant introduced from the refrigerant recovery tank to discharge through the refrigerant discharge port. A second compressor for compressing, a condenser for condensing the heat exchange refrigerant through the second compressor, an evaporator for liquefying the gaseous refrigerant introduced into the refrigerant recovery tank, and an expansion valve provided between the evaporator and the condenser. Equipped with a cooling cycle device,
A first pressure sensor and a first solenoid valve are sequentially disposed in the refrigerant recovery flow path adjacent to the first and second refrigerant recovery ports so that the first pressure sensor is out of a predetermined range in the first pressure sensor. Controls the operation of the refrigerant recovery by controlling the opening and closing of the first solenoid valve,
The refrigerant recovery device includes a first flexible flow path connecting the coolant recovery flow path and a coolant recovery tank, and a second flexible flow path connecting the coolant recovery tank and the coolant discharge port. Device. delete

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