KR101999391B1 - refrigerant pipe cleaning equipment and cleaning method using the same - Google Patents

Abstract

The present invention relates to a refrigerant pipe cleaning apparatus and a refrigerant pipe cleaning method, which can provide a refrigerant recycling method for significantly reducing energy consumption. According to the present invention, the refrigerant pipe cleaning apparatus comprises: a recovery tank; a four-pipe type heat exchange coil; a compressor sucking gas refrigerant to compress the same; an oil separator removing refrigeration oil included in the gas refrigerant; a condenser condensing and liquefying the gas refrigerant; a capillary pipe; and a storage tank connected to the capillary pipe.

Description

Technical Field [0001] The present invention relates to a refrigerant pipe cleaning apparatus and a refrigerant pipe cleaning method using the same,

The present invention relates to a refrigerant pipe cleaning apparatus and a refrigerant pipe cleaning method using the refrigerant pipe cleaning apparatus. More particularly, the present invention relates to a refrigerant pipe cleaning apparatus and a refrigerant pipe cleaning method using oil (frozen oil) The present invention relates to a refrigerant piping cleaning apparatus and a refrigerant piping cleaning method capable of cleaning a refrigerant piping embedded in a wall surface or a ceiling such as a system air conditioner using the system. will be.

In general, the Montreal Protocol on the ozone-depleting substances or the fluorocarbons (CFCs, HCFCs, HFCs), which are regulated by the Kyoto Protocol, are used as air-conditioners for buildings, It is used as refrigerators for refrigerators, household refrigerators, air conditioners, and automotive air conditioners. It is an environmentally damaging material that destroys the stratospheric ozone layer or causes global warming when leaking into the atmosphere. In Korea, the Air Quality Preservation Act defines these substances as substances that cause changes in the climate and ecosystem and inhibits their release into the atmosphere.

In order to respond to the use (consumption) regulation of international fluorinated gas refrigerant, the supply amount of fluorinated gas refrigerant is gradually reduced in the domestic market, and at the same time, the refrigerant is recovered in the maintenance, .

Generally, the refrigerant recovered from the refrigerating air conditioner contains refrigerant, acid, moisture, dust, etc., and a regeneration method and apparatus capable of removing these impurities are required for reuse. In particular, in order to remove the refrigerant contained in the refrigerant, the liquid refrigerant must be vaporized through a distillation method. The acid and water are generally removed through a filter drier.

A conventional refrigerant regeneration apparatus is a system in which a sheath heater is inserted and installed in a tank in which liquid refrigerant is recovered for distillation regeneration to supply external electricity to heat and vaporize the liquid refrigerant in the regeneration mode, A liquid coolant recovered by vaporizing the recovered liquid refrigerant is sucked and recovered by a compressor.

However, these methods have the additional complexity of consuming a large amount of electric energy and performing separate refrigerant recovery and regeneration by using an external electric heat source.

System air conditioners (heat pumps, multi air conditioners, refrigerant flow rate variable system) installed in residential complex buildings, large office buildings, public institutions (schools, libraries, etc.) are equipped with outdoor units (compressors, condensers, expansion valves) (Indoor unit) is connected to the refrigerant piping. If the refrigerant pipeline is embedded in the building wall or installed on the ceiling, it is impossible to dismantle the piping when replacing with an outdoor unit using new refrigerant, or it is necessary to re- .

In case of system air conditioner, the length of refrigerant piping is usually 20 ~ 40m for outdoor unit and indoor room, and the total length of refrigerant piping is 100 ~ 200m when it is more than 5 indoor unit.

Renewal System The air conditioner used HCFC-22 (R-22), which is a Montreal Protocol-regulated substance (ozone depleting substance), as a refrigerant. However, since 2010, products produced are subject to restrictions on refrigerant usage and international environmental issues. Accordingly, HFC is used as an alternative refrigerant.

If the refrigerant in the refrigerating circuit already installed and the refrigerant in the new refrigerant circuit are the same HCFC-22, there is no particular problem in using the refrigerant piping installed in the new system air conditioner outdoor unit, but the replaced new system air conditioner outdoor unit is replaced with the HFC refrigerant , Refrigerant piping must be cleaned inside the refrigerant piping because refrigerant or other contaminants are attached to the inside of the refrigerant piping in order to reuse the existing refrigerant piping as it is.

Mineral oil is used for HCFC-22 refrigerant, synthetic oil is used for HFC refrigerant. Therefore, if mineral oil remains in the existing refrigerant pipe, Contamination causes clogging of the new refrigerant circuit and damages the compressor. Further, the heat transfer performance of the condenser and the evaporator is deteriorated, thereby deteriorating the cooling capability.

Conventional refrigerant piping cleaning method is a method in which a cleaning solution is packed in a container and compressed into nitrogen to clean piping or an aerosol cleaning agent is injected directly into a cleaning pipe to clean it. In particular, since it is necessary to purge with nitrogen to remove the cleaning liquid in the pipe after washing, secondary pollutants are generated, and thus there is a problem that the waste treatment company has to entrust and treat it.

Also, when the refrigerant recovered from the device to be removed is used as the refrigerant for cleaning the piping, the refrigerant recovery device, the regenerating device, and the cleaning refrigerant storage container must be connected by piping, .

Patent Registration No. 10-0936464

The present invention has been conceived to solve the problems of the prior art described above, and it is an object of the present invention to provide an apparatus and a method for efficiently removing impurities by using distillation and regeneration using system heat and heat exchangers without using an external electric heat source for regenerating refrigerant, It is possible to provide a refrigerant recycling method capable of drastically reducing the amount of consumption, and it is also possible to provide a refrigerant recycling method in which a refrigerant recovery function, a distillation regeneration function, and a pipe cleaning function, And it is an object of the present invention to provide a refrigerant pipe cleaning device and a cleaning method that can efficiently clean the inside of a pipe.

The present invention relates to a system for separating refrigerant branch piping of a system air conditioner by a two-phase flow of liquid refrigerant and gas refrigerant (2Phase Flow), a liquid refrigerant discharge pipe of the refrigerant pipe cleaning device and a refrigerant recovery pipe In the apparatus for connecting and cleaning lines,

A recovery tank for recovering the cleaning refrigerant from the system air conditioner or the cleaning refrigerant pipe to be cleaned after returning the cleaned refrigerant from the system air conditioner, a recovery tank installed in the recovery tank, connected to the oil separator or the condenser, An oil separator for removing freezing oil contained in the gas refrigerant discharged from the compressor, an oil separator for separating the refrigerant discharged from the compressor, A condenser for condensing and liquefying the gaseous refrigerant discharged from the compressor through heat transfer with the outside air, and a condenser connected to the capillary heat exchange coil, wherein the recovered refrigerant in the recovery tank and the hot gas discharged from the compressor are discharged through heat exchange A capillary having two or more connected in parallel, lowering the temperature and the pressure, connected to the capillary , And a storage tank for storing the cleaning liquid refrigerant of low temperature and low pressure passed through the capillary.

The filter dryer further includes a filter dryer connected to the recovery tank and the capillary tube to remove moisture, acid components, and freezing oil contained in the liquid recovery refrigerant discharged from the capillary heat exchange coil.

The liquid cleaning refrigerant, which is connected to the shell inlet of the recovery tank and returns to the high pressure side liquid pipe of the refrigerant pipeline to be cleaned, is recovered or the refrigerant collected in the system air conditioner outdoor unit is recovered. A first refrigerant passage for recovering refrigerant from the air conditioner,

A second refrigerant passage connecting the capillary type heat exchange coil, the compressor and the oil separator, sequentially transferring the gaseous refrigerant vaporized by the capillary heat exchange coil in the recovery tank to the compressor and the oil separator,

The hot gas refrigerant passing through the capillary type heat exchange coil is supplied to the outlet of the capillary tube heat exchanger coil and the inlet of the capillary tube for transferring the low temperature liquid refrigerant present in the shell of the recovery tank and the liquid refrigerant liquefied after heat exchange to the storage tank A third refrigerant passage connected to the third refrigerant passage,

A fourth refrigerant passage connecting one of the capillary outlets and the storage tank for storing the liquid refrigerant whose pressure and temperature are lowered while passing through the capillary tube into the storage tank,

A fifth refrigerant flow path in which one end is branched from the third refrigerant flow path to pass the other capillary and the other end is connected to the fourth refrigerant flow path to disperse the liquid refrigerant,

When an amount of liquid refrigerant greater than the amount of liquid refrigerant that can pass through the two capillaries connected in parallel is supplied at the outlet of the capillary tube heat exchanger, it is branched in the fifth refrigerant passage for storage as a storage tank by-pass The sixth refrigerant passage,

A seventh refrigerant passage branched from the second refrigerant passage and connected to the second refrigerant passage after passing through the condenser to lower the pressure flowing into the capillary heat exchange coil when the amount of the gas refrigerant discharged from the compressor is larger than the set value,

And one end connected to the seventh refrigerant passage and the second refrigerant passage, the refrigerant remaining in the inner pipe, the capillary heat-exchanging coil and the condenser of the refrigerant pipe cleaning device for recovering the refrigerant is collected and stored in the storage tank, Refrigerant flow path,

A second refrigerant channel connected to the oil separator, and a ninth refrigerant channel connected to the fourth refrigerant channel to store the gas refrigerant discharged from the compressor in the process of recovering the remaining refrigerant to the storage tank for storage,

A tenth refrigerant passage branched from the second refrigerant passage and connected to the filling container filled with the refrigerant, for transferring the liquid refrigerant from the filling container to the storage tank in a push-pull manner when the amount of the washing liquid refrigerant is insufficient,

An eleventh refrigerant channel connected to the liquid tank and the storage tank, the eleventh refrigerant channel transferring the liquid refrigerant in the filling container to the storage tank,

A twelfth refrigerant passage connected to the storage tank and the gas pipe of the refrigerant pipe to be cleaned and discharging the distillation reclaimed refrigerant stored in the storage tank to the low pressure side of the refrigerant pipe to be cleaned in order to clean the refrigerant pipe to be cleaned,

A thirteenth refrigerant flow path branched from the twelfth refrigerant flow path and discharged into the atmosphere so as to maintain the gas pipe, the liquid pipe, and the twelfth refrigerant flow path of the pipe to be cleaned in a vacuum state before the pipe cleaning operation,

And a fourth refrigerant pipe connected to the storage tank and the recovery tank for introducing the gas refrigerant from the storage tank for generating a recovery pressure for discharging impurities remaining in the lower portion of the recovery tank after the distillation and regeneration in the recovery tank having the capillary heat exchange coil inserted therein, Euro,

And a fifteenth refrigerant passage for discharging impurities collected in the recovery tank.

The apparatus further includes a level sensor mounted on the upper portion and the lower portion of the recovery tank and the storage tank, respectively, for detecting the amount of the liquid cleaning refrigerant recovered after cleaning the refrigerant pipe to be cleaned, the amount of refrigerant for cleaning, and the overcharging prevention.

The apparatus further includes a load cell mounted on the recovery tank and the storage tank for detecting the amount of refrigerant stored in the recovery tank and the storage tank and for maintaining the amount of refrigerant for preventing overcharging, and an indicator for displaying the load cell signal.

The refrigeration system further includes a detecting unit that is installed in each of the compressor, the suction unit, and the discharge unit of the first refrigerant passage and the second refrigerant passage to measure pressure, and a control unit that controls the operation of the compressor in response to the detection result of the detecting unit do.

A refrigerant pipe cleaning method according to the present invention is a refrigerant pipe cleaning method comprising a filling refrigerant recovery step of recovering refrigerant filled in a system air conditioner into the recovery tank, a cleaning refrigerant replenishment step of securing an amount of cleaning refrigerant corresponding to the length of the refrigerant pipe to be cleaned, A connecting step of connecting the gas pipe of the indoor unit provided in the air conditioner and the liquid pipe to the bypass copper pipe, a vacuuming step of the refrigerant pipe to be cleaned to perform the vacuum work on the refrigerant pipe to be cleaned, A piping cleaning step of cleaning the refrigerant pipe to be cleaned using the liquid cleaning refrigerant of the refrigerant pipe cleaning device, a cleaning step of recovering the cleaning refrigerant remaining in the refrigerant pipe to be cleaned after completion of the cleaning of the refrigerant pipeline to be cleaned Equipment to recover refrigerant remaining in the refrigerant recovery stage, capillary heat exchanger coil, condenser and piping After the recovery step, distillation and recovery plays a cleaning liquid refrigerant from the combined recovery tank and a discharge step to discharge the impurities.

Further, it further includes a storage tank circulation cooling step of cooling the storage tank to lower the pressure and temperature of the storage tank in the pipe cleaning step or the cleaning refrigerant recovery step.

INDUSTRIAL APPLICABILITY The refrigerant pipe cleaning device and the refrigerant pipe cleaning method using the same according to the present invention can use waste heat generated in the system without using a separate energy source for distillation and regeneration, Since the distillation regeneration is performed at the same time, the time can be shortened.

As a piping cleaner in which the refrigerant distillation regenerating function and the piping cleaning function are integrated, it is possible to simplify the connection and improve user convenience by connecting the refrigerant separator, the regenerator, and the regenerated refrigerant storage container to the apparatus for cleaning the pipe. The refrigerant is recovered in the refrigeration air conditioner and reused as the refrigerant for cleaning, so that it is possible to contribute to the protection of the global environment when the resource recyclability is high and the refrigerant is a substance destroying global warming or ozone layer.

In addition, when the system air conditioner is renewed, the piping buried in the building wall or the ceiling is reused, the resources can be recycled and the amount of waste generated can be reduced. By circulating and cleaning the pipe with the liquid refrigerant distilled and regenerated by using the pipe cleaning apparatus according to the present invention, It is possible to prevent the compressor from being damaged due to these pollutants and to prevent the cooling ability from being deteriorated due to the removal of oil, deposits and other impurities therein.

Since the same liquid cleaning refrigerant used in the existing piping circulates through the piping to remove impurities and the liquid cleaning refrigerant recovered in the recovery tank after being cleaned is distilled and regenerated by the capillary heat exchange coil, it is possible to always maintain a clean refrigerant state The cleaning efficiency is high.

1 is a configuration diagram of a refrigerant pipe cleaning apparatus according to the present invention;
2 is a block diagram of a refrigerant pipe cleaning apparatus according to the present invention and a refrigerant pipe to be cleaned.
3 is a flowchart of piping cleaning of a refrigerant pipe cleaning apparatus according to the present invention.
FIG. 4 is a view showing the state of use of the refrigerant pipe cleaning apparatus according to the present invention. FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

FIG. 1 is a configuration diagram of a refrigerant pipe cleaning apparatus according to the present invention, FIG. 2 is a view illustrating a refrigerant pipe cleaning apparatus according to the present invention and a refrigerant pipe to be cleaned connected thereto, FIG. 3 is a cross- Fig. 4 is a view showing the state of use of the refrigerant pipe cleaning apparatus according to the present invention. Fig.

(2Phase Flow) of liquid refrigerant and gas refrigerant for refrigerant branch piping cleaning of system air conditioner System liquid to be cleaned Liquid refrigerant discharge pipe and refrigerant recovery line of refrigerant pipe cleaning device to gas pipe and liquid pipe of refrigerant pipe A method for cleaning an existing system air conditioner pipe buried in a wall surface or a ceiling by reusing a recovered refrigerant after removing impurities by a distillation regeneration method using a refrigerant recovered in a subject refrigeration air conditioner And an apparatus for recovering refrigerant by using a waste heat of high temperature and high pressure generated in a refrigerating compressor (30) as a heat source without using a separate heat source such as a conventional sheath heater, The contaminated refrigerant can be distilled and regenerated, and the refrigerant recovery function, the distillation regeneration function, and the pipe cleaning function can be continuously performed.

The refrigerant pipe cleaning apparatus 1 according to the present invention includes a recovery tank 10, a capillary heat exchange coil 20, a compressor 30, an oil separator 40, a condenser 50, capillaries 60a and 60b, , A filter dryer (80), and a storage tank (70).

The refrigerant pipe cleaning apparatus 1 according to the present invention is provided with the recovery tank 10, the compressor 30, the oil separator 40, the condenser 50, the filter drier 80, the capillaries 60a and 60b, And a first refrigerant passage (L1) to a fifteenth refrigerant passage (L15) connecting the storage tank (70) and including one or more valves.

Specifically, the first refrigerant passage L1 is connected to a shell inlet of a recovery tank 10 into which a capillary heat exchange coil 20 is inserted, and is connected to a shell inlet of the recovery tank 10, Liquid refrigerant recovered after returning or recovering the refrigerant collected in the system air conditioner outdoor unit, and the refrigerant is recovered from the refrigerant recovery target refrigerant air conditioner.

The second refrigerant passage L2 connects the inlet of the capillary type heat exchange coil 20, the compressor 30 and the oil separator 40 and is connected to the recovery tank 10 by a capillary heat exchange coil 20 And sequentially transfers the vaporized gas refrigerant to the compressor (30) and the oil separator (40).

The third refrigerant passage (L3) is connected to the low-temperature liquid refrigerant in the shell of the recovery tank (10) and the liquid refrigerant that has been liquefied after the heat exchange is stored Is connected to the outlet of the capillary heat exchange coil (20) and the inlet of the first capillary (60a) so that it can be transferred to the tank (70).

The fourth refrigerant passage L4 connects the outlet of the first capillary tube 60a connected to the two capillaries 60a and 60b connected in parallel to the storage tank 70 so that the pressure and temperature during the passage through the first capillary tube 60a So that the liquid refrigerant can be stored in the storage tank 70.

One end of the fifth refrigerant passage L5 is branched from the third refrigerant passage L3 and the other end of the fifth refrigerant passage L5 is connected to the fourth refrigerant passage L4 after passing through the second capillary tube 60b connected in parallel, Thereby dispersing the liquid refrigerant.

The sixth refrigerant passage L6 is connected to the fifth refrigerant passage L5 and the amount of liquid refrigerant greater than the amount of liquid refrigerant that can pass through the first and second capillaries 60a and 60b connected in parallel is larger than the amount of liquid refrigerant And can be stored in the storage tank 70 by a by-pass when supplied from the exchanger exit.

The seventh refrigerant passage L7 is connected to the second refrigerant passage L2 so that the pressure of the gas refrigerant discharged from the compressor 30 is lower than the set value, And the condenser (50).

The eighth refrigerant passage L8 is connected to the seventh refrigerant passage L7 and the second refrigerant passage L2 and is connected to the inner pipe and the capillary heat exchanger coil 20 included in the refrigerant pipe cleaning device to increase the refrigerant recovery rate And self-cleaning the refrigerant remaining in the condenser 50 to be stored in the storage tank 70.

The ninth refrigerant passage L9 is connected to the second refrigerant passage L2 connected to the oil separator 40 and the fourth refrigerant passage L4 so that the refrigerant is discharged from the compressor 30 in the course of recovering the remaining refrigerant. The gas refrigerant is transported to the storage tank 70 for storage.

The tenth refrigerant passage L10 is connected to the second refrigerant passage L2 and a filling container (not shown) filled with the refrigerant. When the amount of the washing liquid refrigerant is insufficient, the liquid refrigerant is pushed to the storage tank (70).

The eleventh refrigerant passage L11 is connected to the liquid valve of the filling container and the storage tank 70 and conveys the liquid refrigerant of the filling container to the storage tank 70. [

The twelfth refrigerant passage L12 is connected to the storage tank 70 and the low pressure side gas pipe V of the refrigerant pipe to be cleaned and is connected to the distillation recovery refrigerant line Is discharged to the low pressure side gas pipe (V) of the refrigerant pipe to be cleaned.

The thirteenth refrigerant passage L13 is connected to the twelfth refrigerant passage L12 to maintain the gas pipe V of the pipe to be cleaned, the liquid pipe L and the twelfth refrigerant passage L12 in a vacuum state before the piping cleaning operation, And discharges the internal air to the atmosphere through the pump (VACUUM P / P).

The 14th refrigerant passage L14 is connected to the storage tank 70 and the recovery tank 10 so that the pressure for discharging impurities remaining in the lower portion of the recovery tank 10 after distillation and regeneration in the recovery tank 10 .

The fifteenth refrigerant passage L15 is connected to the recovery tank 10 and discharges the collected impurities to the outside when a pressure is generated in the recovery tank 10.

A temperature sensor 150a controlled by level sensors 90c and 90d and a temperature controller 150b and a horizontal balance 100a with a load cell and an indicator for measuring the refrigerant weight are connected to the recovery tank 10, A level sensor 90a and 90b and a temperature sensor 150a controlled by the regulator 150b and a horizontal scale 100b with a load cell and an indicator for measuring the refrigerant weight are mounted on the storage tank 70 .

Subsequently, the recovery tank 10 recovers the refrigerant filled in the system air conditioner outdoor unit or the refrigerant recovery target refrigerant air conditioner for reuse as cleaning refrigerant, or recovers the liquid cleaning refrigerant that returns after cleaning the refrigerant pipe to be cleaned Function.

The tubular heat exchanger coil 20 is inserted into a shell of the recovery tank 10.

The liquid refrigerant as the low-temperature low-pressure rinsing refrigerant and the high-temperature and high-pressure gaseous refrigerant discharged from the compressor 30 are respectively collected in the shell of the recovery tank 10 and pass through the interior of the tubular heat exchange coil 20 .

The liquid refrigerant and the gaseous refrigerant undergo heat exchange while passing through the capillary heat exchange coil (20), whereby the liquid refrigerant at low temperature and low pressure is distilled and regenerated.

In the present invention, the recovery tank 10 also includes an accumulator characteristic disposed upstream of the compressor 30 to separate the gas refrigerant and the liquid refrigerant before delivering the gasified refrigerant to the compressor 30 Is used.

The compressor 30 is connected to the recovery tank 10 and recovers the refrigerant charged in the system air conditioner outdoor unit or the refrigerant recovery target refrigerant air conditioner for reuse as cleaning refrigerant, And is used as a heat source for a liquid refrigerant distillation / regeneration system for sucking the gaseous refrigerant vaporized in the recovery tank 10 in the process of recovering the cleaning refrigerant and discharging it to the capillary heat exchange coil with high temperature and high pressure gas refrigerant.

The oil separator 40 is connected to the compressor 30 and separates and recovers the refrigerant (oil) of the compressor 30 contained in the high-temperature and high-pressure gas refrigerant discharged from the gas refrigerant.

The condenser (50) is connected between the oil separator (40) and the recovery tank (10). The condenser 50 condenses and liquefies the gas refrigerant discharged from the oil separator 40 through heat transfer with the outside air.

The condenser 50 condenses and lowers the pressure and the temperature of the liquid refrigerant flowing into the capillary type heat exchange coil 20 when the amount of gas refrigerant discharged from the compressor 30 is larger than the set value.

At this time, the condenser 50 may be air-cooled.

The capillary can be stably stored in the storage tank 70 by lowering the temperature and pressure of the liquid refrigerant passed through the capillary heat exchange coil 20. [

At this time, the capillary tube may consist of a first capillary tube 60a and a second capillary tube 60b and may be connected in parallel.

The filter dryer 80 is connected to the recovery tank 10 and the capillary, and removes moisture, acid components, and freezing oil contained in the liquid regeneration refrigerant discharged from the capillary heat exchange coil.

The storage tank 70 is connected to the capillary, stores the refrigerant filled with the initial liquid cleaning refrigerant, recovered after piping cleaning, and distilled and regenerated by the capillary heat exchange coil 20.

The recovery tank 10 and the storage tank 70 may be provided with level sensors 90c, 90d, 90a and 90b, respectively, for measuring the amount of liquid refrigerant to prevent overcharging of the liquid refrigerant.

Further, the level sensors 90a and 90b installed in the storage tank 70 perform a function of detecting the amount of liquid cleaning refrigerant and activating the cleaning function.

In the refrigerant pipe cleaning apparatus 1 according to the present invention, horizontal scales 100a and 100b having a load cell may be applied instead of the level sensors 90a, 90b, 90c and 90d.

Specifically, the horizontal balances 100a and 100b sense the signals of the load cells 100a and 100b and function to prevent the amount of refrigerant collected or stored in the recovery tank 10 and the storage tank 70 from being overcharged .

In addition, the refrigerant pipe cleaning apparatus 1 according to the present invention may further include detection means for measuring pressure, temperature and weight of the respective components.

Specifically, the detecting means includes a recovery pressure sensor 140, a suction pressure sensor 150, a compressor discharge pressure sensor 160 installed in the recovery line, and a pressure sensor 140 installed in the recovery tank 10 and the storage tank 70 A pressure sensor 130, a safety valve, or the like.

In addition, the detection means is configured such that the detected pressure signal is used as an input signal of a control unit (not shown) for controlling the operation of the compressor 30 and outputted to the display screen.

More specifically, the recovery line recovery pressure sensor 140 recovers the refrigerant filled in the outdoor unit of the system air conditioner or the refrigerant recovery target refrigerating air conditioner as the cleaning refrigerant, or recovers the refrigerant remaining in the refrigerant pipeline to be cleaned The controller 30 outputs the measured pressure value to the display screen and stops the operation of the compressor 30 when the set pressure value is reached.

The suction pressure sensor 130 is a sensor for measuring the suction pressure of the compressor 30 and outputs the measured pressure value when the gas refrigerant present in the recovery tank 10 is sucked to the display screen, And stops the operation of the compressor (30) when the pressure value is less than the set value.

The discharge pressure sensor 160 installed in the discharge line of the compressor 30 detects the high pressure state of the compressor 30 and outputs the high pressure state of the compressor 30 on the display screen. The operation of the compressor 30 is stopped.

In addition, the compressor discharge pressure sensor 160 allows the gas discharged from the compressor 30 to flow into the condenser 50 within another set pressure range.

The pressure sensor 130 installed in the storage tank 70 is a sensor for detecting the pressure of the storage tank 70 and outputs the internal pressure of the storage tank 70 on the display screen. The compressor 30 sucks the gas refrigerant in the storage tank 70 through the recovery tank 10 to lower the pressure and the sucked gas refrigerant passes through the condenser 50 and the tubular heat exchange coil 20 And then stored in the storage tank 70. The sub-

A safety valve is provided in the recovery tank 10 and the storage tank 70, and performs a function of automatically discharging the pressure when the internal pressure of the tank becomes equal to or higher than the set pressure value.

FIG. 2 is a schematic configuration diagram of the refrigerant pipe cleaning apparatus shown in FIG. 1 and a refrigerant pipe to be cleaned.

As shown in Fig. 2, the refrigerant pipe cleaning apparatus is connected to the gas pipe (V) of the refrigerant pipe to be cleaned and the liquid pipe (L).

In order to recover the R-22 refrigerant collected in the system air conditioner outdoor unit condenser 50 or the receiver or in the system air conditioner by a pump-down method before connecting the cleaning device according to the present invention and the refrigerant pipe to be cleaned, The R-22 refrigerant charged in the existing system air conditioner (multi air conditioner) is used as the piping cleaning refrigerant by connecting / collecting the recovery line and the service port of the system air conditioner outdoor unit.

(V) and high-pressure side liquid pipe (L) for each indoor unit in order to constitute a closed refrigerant circuit after removing the indoor unit and remove the refrigerant charged in the existing system air conditioner equipment and piping, And an opening / closing ball valve for selectively shutting off the flow of the cleaning refrigerant for each of the lines for cleaning each branch line.

The liquid refrigerant discharge pipe and the refrigerant recovery line of the refrigerant pipe cleaning device 1 are connected to the gas pipe (V) of the refrigerant pipe to be cleaned and the liquid pipe L, respectively, to connect the refrigerant pipe cleaning device and the refrigerant pipe to be cleaned , The water and air existing in the refrigerant pipe to be cleaned are removed by a vacuum pump after connection to make a vacuum,

The R-22 liquid cleaning refrigerant discharged from the refrigerant pipe cleaning apparatus 1 is circulated and cleaned through the branch piping gas pipe (V) to be cleaned and the liquid pipe (L) to remove contaminants such as oil adhering to the pipe do. After the indoor unit is removed, the liquid pipe (L) is connected to the bypass pipe through the gas pipe (V) to which the indoor unit is connected for constitution of the waste refrigerant circuit.

As described above, the refrigerant pipe to be cleaned is connected to the gas pipe (V) and the liquid pipe (L) by a by-pass copper pipe equipped with a ball valve for each branch pipe, And selectively blocks the refrigerant flow.

Further, the gas pipe (V) and the liquid pipe (L) of the refrigerant pipe to be cleaned are connected by a by-pass copper pipe equipped with a ball valve, a valve is provided at the other end of the liquid pipe L to be cleaned, And a valve provided in the refrigerant recovery line of the refrigerant pipe cleaning device 1 are connected to each other.

A valve is provided at the other end of the gas pipe V to be cleaned and a pipe is connected between the valve and the valve provided in the liquid cleaning refrigerant discharge line of the refrigerant pipe cleaning apparatus 1. [

Next, a refrigerant pipe cleaning method using the refrigerant pipe cleaning apparatus 1 according to the present invention will be described with reference to FIGS. 2 and 3. FIG.

The method for cleaning a refrigerant pipe according to the present invention is characterized in that it comprises a filled refrigerant recovery step for recovering the refrigerant charged in the existing system air conditioner to the recovery tank 10, a cleaning refrigerant replenishment step for securing the amount of cleaning refrigerant suited to the length of the refrigerant pipeline to be cleaned, A connecting step of connecting the gas pipe (V) of the indoor unit provided in the system air conditioner to the liquid pipe (L) through a bypass copper pipe, a vacuum refrigerant pipe vacuum step of vacuuming the refrigerant pipe to be cleaned, ) Of the refrigerant pipeline is filled in the refrigerant pipe, a pipe cleaning step of cleaning the refrigerant pipe to be cleaned by using the liquid cleaning refrigerant of the refrigerant pipe cleaning device (1), a step of cleaning the refrigerant pipeline to be cleaned A cleaning refrigerant recovery step of recovering the cleaning refrigerant remaining in the refrigerant pipe to be cleaned, a capillary heat exchange coil 20, a condenser 50, an oil separator 40, a second refrigerant passage L2, A refrigerant remaining in the equipment for recovering the refrigerant remaining in the refrigerant passage L8, the refrigerant passage L7, the refrigerant in the refrigerant passage L8, and the like; a discharging step of discharging collected impurities after recovery and distillation recovery of the washing liquid refrigerant from the recovery tank 10; .

More specifically, the present invention connects a refrigerant recovery port of a refrigerant pipe cleaning apparatus 1 and a high-pressure service port of an existing system air conditioner outdoor unit, and is collected in a system air conditioner outdoor unit condenser 50 or a receiver by a pump- And the manifold gauge service pipe connected to the high pressure side and the low pressure side of the existing system air conditioner outdoor unit is connected to the refrigerant recovery line of the refrigerant pipe cleaning device 1 to recover the refrigerant filled in the existing system.

The R-22 refrigerant used in the existing system air conditioner recovered by the refrigerant pipe cleaning device 1 is utilized as a pipe cleaning refrigerant.

In addition, after the refrigerant charged in the existing system air conditioner is recovered, the system air conditioner outdoor unit and the refrigerant pipe cleaning apparatus 1 are separated, and R-22 liquid stored in a separate container for ensuring the amount of cleaning refrigerant suited to the refrigerant pipe length to be cleaned The refrigerant is recovered and charged into the refrigerant pipe washing machine storage tank 70 by a push-pull method.

Further, the gas side and the liquid side of the charging container (not shown) filled with the R-22 refrigerant for the liquid cleaning refrigerant replenishment are respectively connected to the gas pressure regulating electromagnetic valve (BV 10) of the refrigerant pipe cleaning device (1) Is connected to the valve BV11 by a hose and the compressor 30 of the refrigerant pipe cleaning device 1 is operated to transfer the R-22 liquid refrigerant to the storage tank 70 of the pipe cleaning device.

In this case, when the amount of refrigerant conveyed to the storage tank 70 of the refrigerant pipe cleaning apparatus 1 reaches the level value sensor 90b or the set value of the horizontal scale 100b installed in the storage tank 70, ) Operation is stopped and refrigerant transfer is stopped.

At this time, the amount of cleaned refrigerant can be appropriately adjusted according to the length of the refrigerant pipe to be cleaned by changing the indicator and the load cell value.

Further, after the indoor unit of the refrigerant pipe to be cleaned is removed, the indoor unit high pressure side liquid pipe (L) and the low pressure side gas pipe (V) are connected by the by-pass copper pipe and the opening ball valve is provided between the bypass copper pipe. The refrigerant discharge line and the refrigerant recovery line are connected to the gas pipe (V) and the liquid pipe (L) of the refrigerant pipe to be cleaned respectively and then the electromagnetic valves BV03 and BV03 provided on the refrigerant passage L13 of the refrigerant pipe cleaning device 1, BV04) manually.

Subsequently, the bypass copper tube solenoid valves BV03 and BV04 are set to " open ", and a separate vacuum pump is used to remove moisture and air in the refrigerant pipe to be cleaned so that the interior of the refrigerant pipe to be cleaned is evacuated.

In this case, the degree of vacuum of the refrigerant pipe to be cleaned can be confirmed through a pressure gauge (PG01) provided on the refrigerant flow path of the refrigerant pipe cleaning device 1. [ When the vacuum operation of the refrigerant pipe to be cleaned is completed, the bypass solenoid valves (BV03, BV04) are closed.

Next, the cleaning liquid refrigerant filled in the storage tank 70 flows into the refrigerant pipe to be cleaned in a vacuum state to fill it. The liquid cleaning refrigerant stored in the storage tank 70 is set to "open" in the discharge line solenoid valve BV03 and the bypass valve between the copper pipelines is set to open manually to gradually cool the refrigerant piping (all branch systems) to be cleaned Allow liquid cleaning refrigerant to fill.

In this case, the refrigerant recovery line valve (BV01) of the refrigerant line cleaning apparatus (1) should be in the "closed" state.

Next, except for the branch pipe to be cleaned, the bypass valve for opening and closing the bypass pipe of the remaining branch pipe is set to "Closed ", and the refrigerant recovery line solenoid valve BV01 of the refrigerant pipe cleaning device 1 is manually set to " Open "and then clean the refrigerant piping of the branch piping.

At this time, the solenoid valves SOV01, SOV02, SOV04, SOV08 are sequentially "opened" and the compressor 30 is operated to circulate and wash the liquid cleaning refrigerant stored in the storage tank 70. [

The liquid cleaning refrigerant in the storage tank 70 is discharged due to the opening of the solenoid valve SOV08 and the liquid refrigerant containing the impurities returning after cleaning the branch pipeline to be cleaned flows through the solenoid valve SOV01 At the same time, the distillation is regenerated through the counterflow heat exchange with the capillary heat exchange coil 20 to separate the gas refrigerant from the oil and the impurities.

Next, the vaporized gas refrigerant is sucked into the compressor (30) and discharged at high temperature and high pressure, then flows into the capillary heat exchange coil (20), and the liquid cleaning refrigerant flowing into the body of the recovery tank (10) , And the regenerated liquid refrigerant at low temperature and intermediate pressure after the heat exchange is stored in the storage tank 70 via the filter dryer 80.

As described above, the oil separator 40 is used for freezing oil separation contained in the gas refrigerant discharged between the discharge portion of the compressor 30 and the inlet of the condenser 50 or the capillary heat exchange coil 20 .

The solenoid valve SOV04 is closed and the solenoid valve SOV05 is opened to be guided to the condenser 50 through a bypass to generate a medium pressure high pressure Liquid coolant flows into the capillary heat exchange coil (20).

The amount of the liquid cleaning refrigerant stored in the storage tank 70 is sensed by level sensors 90a and 90b installed at the upper and lower portions of the storage tank 70, When the level of the recovered liquid refrigerant is sensed by the level sensor 90b, the operation of the compressor 30 is automatically stopped, and the liquid refrigerant delivery to the storage tank 70 is stopped.

Further, when the amount of liquid refrigerant is sensed by the level sensors 90c and 90d, the solenoid valve SOV08 automatically closes and the piping cleaning operation is automatically stopped because the liquid refrigerant is insufficient.

At this time, the branch pipe cleaning is cyclically cleaned for the programmed time.

Next, when the corresponding branch piping circulation rinsing is completed for the programmed time, set the bypass ball valve for opening and closing the ball valve to "closed" and open the ball valve for opening and closing the bypass pipe of the other branch pipe to be cleaned to "open" And repeats the refrigerant piping cleaning operation and terminates the cleaning operation upon completion of all branch piping cleaning circulation.

Next, the liquid cleaning refrigerant is used to completely recover the refrigerant remaining in the refrigerant pipeline to be cleaned after completion of the branch system refrigerant pipeline cleaning (S011)

At this time, the refrigerant recovery system uses a compression-liquefaction system using a compressor 30 of a pipeline cleaner, a cage-type heat exchanger, and an air-cooled condenser 50.

To this end, the bypass valve for opening and closing the bypass pipe of all the to-be-cleaned branch pipes is set to "open" and the solenoid valves SOV01, SOV02 and SOV04 provided on the refrigerant passage are set to "ON" .

Next, the compressor 30 sucks the gaseous refrigerant present in the recovery tank 10 to lower the pressure of the recovery tank 10 so that the liquid refrigerant and the gaseous refrigerant remaining in the branch system piping are returned to the recovery tank 10, The gas refrigerant flowing into the body and being vaporized is sucked into the compressor 30 and discharged at a high temperature and a high pressure and then flows into the capillary heat exchange coil 20 to distill and regenerate the liquid cleaning refrigerant flowing into the body of the recovery tank 10, The regenerated liquid refrigerant at a low temperature and pressure after the heat exchange is stored in the storage tank 70 via the filter dryer 80 and the first and second capillaries 60a and 60b.

At this time, when the gas refrigerant pressure discharged from the compressor 30 in the refrigerant recovery step exceeds the set value, the solenoid valve SOV04 is closed and the solenoid valve SOV05 is opened, and is guided to the condenser 50 through the bypass Liquid coolant at a middle temperature and a high pressure flows into the capillary heat exchange coil (20).

The refrigerant remaining in the branch system should be sucked to the final recovery vacuum through the refrigerant passage L1 and the recovery tank 10 by the compressor 30, Can be confirmed through the pressure sensor 140 attached to the line.

The pressure of the storage tank 70 during storage in the storage tank 70 after passing through the capillary heat exchange coil 20 for preventing pressure and temperature rise of the storage tank 70 during the refrigerant recovery step When the set pressure is reached, the storage tank (70) cooling function is activated.

To this end, when the pressure in the reservoir tank 70 reaches the set pressure, the compressor 30 is stopped, the alarm is automatically activated, and sub-cooling is performed for the manually programmed time.

At this time, the solenoid valves SOV01 and SOV08 connected to the refrigerant pipe cleaning apparatus 1 and the refrigerant pipe to be cleaned are set to "OFF ", and the electromagnetic valves SOV02, SOV05 and SOV07 are set to & (30).

The gas refrigerant in the storage tank 70 is supplied to the recovery tank 10 through the compressor 30 (suction and discharge), the condenser 50, the capillary heat exchanger coil 20 and the first and second capillaries 60a and 60b And then stored in the storage tank 70 again.

In the next step, when recovery of the refrigerant to the final recovered vacuum pressure level is completed in the refrigerant pipeline of the branch system to be cleaned, the solenoid valve (SOV01, SOV08) connected to the pipeline cleaner and the refrigerant pipe to be cleaned, The refrigerant remaining in the refrigerant passage of the refrigerant pipe cleaning apparatus 1 such as the condenser 50 in the refrigerant pipe cleaning apparatus 1 is recovered (Self-cleaning).

At this time, the solenoid valves SOV01, SOV02, SOV03 and SOV06 are set to the "ON" state, and the compressor 30 is operated to store the refrigerant on the refrigerant pipeline in the storage tank 70 in a gaseous state.

Next, the cleaning refrigerant returning to the body of the recovery tank 10 after cleaning the refrigerant pipe to be cleaned includes freezing oil, solid matter, water, etc., removed from the piping, The dryer 80 removes moisture, solid particulate contaminants and a part of the refrigerant, but the refrigerant containing a lot of refrigerant flows into the recovery tank 10.

At this time, the liquid refrigerant in the capillary type heat exchange coil 20 is vaporized into gas refrigerant through heat exchange, then flows into the capillary heat exchange coil 20 through the compressor 30 and is stored in the storage tank 70, Remains at the lower part of the body of the recovery tank (10) in which the capillary heat exchange coil (20) is inserted and is to be discharged after the recovery of the remaining refrigerating equipment.

To this end, the solenoid valve SOV07 is set to "ON " so that the gas refrigerant in the storage tank 70 flows into the recovery tank 10 to set the solenoid valve SOV07 to" OFF " , And the manual ball valve (BV08) provided at the lower portion of the recovery tank (10) is opened to discharge the impurities to the external container.

When the equipment remaining refrigerant recovery step is completed, the piping cleaning operation is terminated and the connection valve of the refrigerant pipe cleaning device (1) and the refrigerant pipe to be cleaned is closed and the connection hose is removed.

4 is a schematic use state diagram of the refrigerant pipe cleaning apparatus 1 according to the instant embodiment of the present invention.

As shown in the figure, the refrigerant pipe cleaner is connected to recover the liquid refrigerant and the gaseous refrigerant charged in the existing system air conditioner. After the charging refrigerant is recovered, the closed refrigerant circuit structure after removing the indoor unit Pressure side liquid pipe (L) is connected by bypass to the low-pressure side gas pipe (V) and the low-pressure side liquid pipe (L) for each indoor unit, and an opening / closing ball valve The liquid refrigerant discharge pipe of the refrigerant pipe cleaning apparatus 1 and the refrigerant recovery line are connected to the gas pipe (V) of the refrigerant pipe to be cleaned and the liquid pipe L, respectively, And the impurities attached to the refrigerant pipe to be cleaned can be removed by operating the ball valve for opening and closing the bypass copper pipe.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

1: refrigerant pipe cleaning device 10: recovery tank
20: capillary type heat exchange coil 30: compressor
40: Oil separator 50: Condenser
60a, a first capillary tube 60b: a second capillary tube
70: Storage tank 80: Filter dryer
90a, 90b, 90c, 90d: level sensors 100a, 100b: horizontal scales
130: pressure sensor 140: recovery pressure sensor
150: Suction pressure sensor 160: Discharge pressure sensor

Claims (8)

(2Phase Flow) of liquid refrigerant and gas refrigerant for refrigerant branch piping cleaning of system air conditioner System liquid to be cleaned Liquid refrigerant discharge pipe and refrigerant recovery line of refrigerant pipe cleaning device to gas pipe and liquid pipe of refrigerant pipe In the apparatus for cleaning and connecting,
A recovery tank for recovering the filled refrigerant of the system air conditioner or the cleaning refrigerant returned after cleaning the refrigerant pipe to be cleaned,
A cube-type heat exchange coil installed inside the recovery tank, connected to an oil separator or a condenser, for distilling the liquid refrigerant discharged from the oil separator or the condenser and recovered in the recovery tank,
A compressor for sucking and compressing the gas refrigerant that has passed through the recovery tank,
An oil separator for removing freezing oil contained in the gas refrigerant discharged from the compressor,
A condenser for condensing and liquefying the gas refrigerant discharged from the oil separator through heat transfer with the outside air,
A capillary tube connected to the capillary tube heat exchange coil and lowered in temperature and pressure of the recovered refrigerant and the liquid refrigerant discharged through heat exchange with the hot gas discharged from the compressor,
A storage tank connected to the capillary and storing the low-temperature, low-pressure liquid cleaning refrigerant that has passed through the capillary,
The liquid cleaning refrigerant returned to the high pressure side liquid pipe of the cleaning target refrigerant pipe is recovered or the refrigerant collected in the system air conditioner outdoor unit is recovered, A first refrigerant passage for recovering refrigerant from the first refrigerant passage,
A second refrigerant passage connecting the capillary type heat exchange coil, the compressor and the oil separator, sequentially transferring the gaseous refrigerant vaporized by the capillary heat exchange coil in the recovery tank to the compressor and the oil separator,
And a controller for controlling the operation of the compressor in response to a detection result of the detection means, wherein the control means controls the operation of the compressor, the compressor, the suction portion and the discharge portion of the first refrigerant passage and the second refrigerant passage,
The detection means
When the refrigerant charged in the outdoor unit of the system air conditioner or the refrigerant recovery target is recycled as the refrigerant for cleaning or the refrigerant remaining in the refrigerant pipe to be cleaned after the piping cleaning is recovered, the final recovered vacuum pressure is measured and set A recovery pressure sensor for stopping the operation of the compressor upon reaching the value,
Wherein the controller is configured to measure a suction pressure of the compressor to output a measured pressure value on the display screen when the gas refrigerant present in the recovery tank is sucked and to stop the operation of the compressor when the measured pressure value is less than a set value Pressure sensor,
A discharge pressure sensor for detecting the high pressure state of the compressor and outputting it to the display screen, stopping the operation of the compressor when the pressure is higher than the set pressure, and allowing the gas discharged from the compressor to flow into the condenser within the set pressure range,
Wherein the compressor is adapted to suck the gas refrigerant in the storage tank through the recovery tank to lower the pressure when the pressure of the refrigerant is higher than the set pressure, And a pressure sensor that is liquefied through the heat exchange coil and stored in the storage tank for sub-cooling.
The method according to claim 1,
And a filter dryer connected to the recovery tank and the capillary to remove moisture, acid components, and freezing oil contained in the liquid recovery refrigerant discharged from the capillary heat exchange coil.
3. The method of claim 2,
The hot gas refrigerant passing through the capillary type heat exchange coil is supplied to the outlet of the capillary tube heat exchanger coil and the inlet of the capillary tube for transferring the low temperature liquid refrigerant present in the shell of the recovery tank and the liquid refrigerant liquefied after heat exchange to the storage tank A third refrigerant passage connected to the third refrigerant passage,
A fourth refrigerant passage connecting one of the capillary outlets and the storage tank for storing the liquid refrigerant whose pressure and temperature are lowered while passing through the capillary tube into the storage tank,
A fifth refrigerant flow path in which one end is branched from the third refrigerant flow path to pass the other capillary and the other end is connected to the fourth refrigerant flow path to disperse the liquid refrigerant,
When an amount of liquid refrigerant greater than the amount of liquid refrigerant that can pass through the two capillaries connected in parallel is supplied at the outlet of the capillary tube heat exchanger, it is branched in the fifth refrigerant passage for storage as a storage tank by-pass The sixth refrigerant passage,
A seventh refrigerant passage branched from the second refrigerant passage and connected to the second refrigerant passage after passing through the condenser to lower the pressure flowing into the capillary heat exchange coil when the amount of the gas refrigerant discharged from the compressor is larger than the set value,
An eighth refrigerant passage connected to the seventh refrigerant passage and the second refrigerant passage for recovering the refrigerant remaining in the inner pipe, the capillary heat-exchanging coil and the condenser of the refrigerant pipe cleaning device to increase the refrigerant recovery rate, ,
A second refrigerant channel connected to the oil separator, and a ninth refrigerant channel connected to the fourth refrigerant channel to store the gas refrigerant discharged from the compressor in the process of recovering the remaining refrigerant to the storage tank for storage,
A tenth refrigerant passage branched from the second refrigerant passage and connected to the filling container filled with the refrigerant, for transferring the liquid refrigerant from the filling container to the storage tank in a push-pull manner when the amount of the washing liquid refrigerant is insufficient,
An eleventh refrigerant channel connected to the liquid tank and the storage tank, the eleventh refrigerant channel transferring the liquid refrigerant in the filling container to the storage tank,
A twelfth refrigerant passage connected to the storage tank and the gas pipe of the refrigerant pipe to be cleaned and discharging the distillation reclaimed refrigerant stored in the storage tank to the low pressure side of the refrigerant pipe to be cleaned in order to clean the refrigerant pipe to be cleaned,
A thirteenth refrigerant passage branched from the twelfth refrigerant passage and discharging the air existing therein to the atmosphere so as to maintain the gas pipe, the liquid pipe and the twelfth refrigerant passage of the pipe to be cleaned in a vacuum state before the piping cleaning operation,
And a fourth refrigerant pipe connected to the storage tank and the recovery tank for introducing the gas refrigerant from the storage tank for generating a recovery pressure for discharging impurities remaining in the lower portion of the recovery tank after the distillation and regeneration in the recovery tank having the capillary heat exchange coil inserted therein, Euro,
And a fifteenth refrigerant passage for discharging impurities collected in the recovery tank.
The method according to claim 1,
Further comprising a level sensor mounted on upper and lower portions of the recovery tank and the storage tank, respectively, for detecting the amount of the liquid cleaning refrigerant recovered after cleaning the refrigerant pipe to be cleaned, the amount of cleaning refrigerant, and the prevention of overcharge.
5. The method of claim 4,
Further comprising a load cell mounted on the recovery tank and the storage tank for detecting the amount of refrigerant stored in the recovery tank and the storage tank and for maintaining the amount of refrigerant for overcharging, and an indicator for displaying the load cell signal.
delete A refrigerant pipe cleaning method using a refrigerant pipe cleaning apparatus according to any one of claims 1 to 5,
A charged refrigerant recovery step of recovering the refrigerant charged in the system air conditioner to the recovery tank,
A cleaning refrigerant replenishment step for securing an amount of cleaning refrigerant corresponding to the length of the refrigerant pipe to be cleaned,
A connection step of connecting the gas pipe and the liquid pipe of the indoor unit provided in the system air conditioner to the bypass copper pipe,
A refrigerant piping vacuum to be cleaned in which the refrigerant pipeline to be cleaned is subjected to a vacuum operation,
A charging step of charging the liquid cleaning refrigerant in the storage tank into the refrigerant pipe,
A pipe cleaning step of cleaning the refrigerant pipe to be cleaned by using the liquid cleaning refrigerant of the refrigerant pipe cleaning device,
A cleaning refrigerant recovery step of recovering the cleaning refrigerant remaining in the refrigerant pipe to be cleaned after completion of the cleaning of the refrigerant pipeline to be cleaned,
The equipment for recovering the refrigerant remaining in the tube-type heat exchange coil, the condenser and the piping, the remaining refrigerant recovery step,
A discharging step of recovering the purified liquid refrigerant in the recovery tank, distilling and regenerating the recovered liquid refrigerant, and discharging the collected impurities;
And measuring the pressures of the compressor, the suction portion and the discharge portion of the first refrigerant passage and the second refrigerant passage through the detection means, respectively,
The detection means
When the refrigerant charged in the outdoor unit of the system air conditioner or the refrigerant recovery target is recycled as the refrigerant for cleaning or the refrigerant remaining in the refrigerant pipe to be cleaned after the piping cleaning is recovered, the final recovered vacuum pressure is measured and set A recovery pressure sensor for stopping the operation of the compressor upon reaching the value,
Wherein the controller is configured to measure a suction pressure of the compressor to output a measured pressure value on the display screen when the gas refrigerant present in the recovery tank is sucked and to stop the operation of the compressor when the measured pressure value is less than a set value Pressure sensor,
A discharge pressure sensor for detecting the high pressure state of the compressor and outputting it to the display screen, stopping the operation of the compressor when the pressure is higher than the set pressure, and allowing the gas discharged from the compressor to flow into the condenser within the set pressure range,
Wherein the compressor is adapted to suck the gas refrigerant in the storage tank through the recovery tank to lower the pressure when the pressure of the refrigerant is higher than the set pressure, And a pressure sensor that is liquefied through a heat exchange coil and stored in the storage tank for sub-cooling.
8. The method of claim 7,
And a storage tank circulation cooling step of cooling the storage tank to lower the pressure and temperature of the storage tank in the pipe cleaning step or the cleaning refrigerant recovery step.

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