KR20220073066A - Disposal ammonia recovery Apparatus having double separation unit - Google Patents

Abstract

The present invention is a waste ammonia recovery device having a transfer unit, a compression unit, a heat exchange unit, and a condensing unit whose operation is controlled by a control unit, and communicates with the waste ammonia storage unit 10 to collect liquid ammonia stored in the waste ammonia storage unit 10 . Liquid transfer unit 100 for transferring to the recovered ammonia storage unit 20 through the heat exchange unit 400; and a vapor transfer unit communicating with the waste ammonia storage unit 10 and transferring the vapor phase ammonia stored in the waste ammonia storage unit 10 to the recovered ammonia storage unit 20 through the compression unit 300 and the heat exchange unit 400 ( 200), wherein the gas phase transfer unit 200 includes a first separation unit 210 into which gaseous ammonia transported from the waste ammonia storage unit 10 is primarily introduced, and a gas phase discharged from the first separation unit 210 . It is a waste ammonia recovery device equipped with a double separator, characterized in that it includes a second separator 220 through which ammonia is introduced secondarily to remove foreign substances from gaseous ammonia.

Description

Disposal ammonia recovery Apparatus having double separation unit

The present invention relates to a waste ammonia recovery device. Specifically, it relates to a waste ammonia recovery device equipped with a double separation unit.

Because ammonia is easy to liquefy, a general-purpose compressor can be used, so it can be designed to be shared with HFC. The latent heat of evaporation is second only to water, so it is superior to other refrigerants. For this reason, the refrigeration capacity per unit volume enclosed in the system is extremely high. In addition, the critical temperature is high as 132.4℃, and the refrigerant evaporation temperature in the refrigeration cycle can be applied in a wide temperature range from 0 to 60℃.

In general, the smaller the molecular weight of a substance, the higher the thermal conductivity. Ammonia, which has a very small molecular weight, has a very high thermal conductivity, which has the advantage of downsizing the heat exchanger. In addition, since the optimum valve passing speed is proportional to the square root of molecular weight in a reciprocating compressor, it is possible to speed up ammonia with a small molecular weight. From the above physical characteristics, the refrigeration system using ammonia can be miniaturized.

However, ammonia as a refrigerant has many advantages, but problems due to toxicity, flammability, explosiveness, and compatibility with refrigerating oil in ammonia refrigerators and corrosiveness have also been suggested. In addition, the problem of insufficient technology for recovering and recycling waste ammonia was also presented.

Recently, the use of ammonia gas is on the rise, but in the case of the existing recovery device, it was exposed to safety accidents due to leakage due to the toxicity and flammability of ammonia.

In addition, since the existing recovery device is separately divided into primary and secondary recovery tanks, it is inconvenient to separate the liquid and gaseous refrigerants as well as to increase the size of the device.

Such an increase in cost and additional disposal cost due to the enlargement of the device were occurring.

(Document 1) Korean Patent Publication No. 10-2017-0098478 (2017.08.30)

The waste ammonia recovery device provided with a double separator according to the present invention has the following problems.

First, it is intended for recycling by recovering and recycling the waste ammonia refrigerant.

Second, it is intended to separate and recover liquid ammonia and gaseous ammonia independently.

Third, liquid ammonia and gaseous ammonia are simultaneously recovered.

Fourth, it is intended to increase the recovery rate and purity of gaseous ammonia.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The present invention relates to a waste ammonia recovery device having a transfer unit, a compression unit, a heat exchange unit, and a condensing unit whose operation is controlled by a control unit. The liquid ammonia stored in the waste ammonia storage unit communicates with the waste ammonia storage unit and stores the recovered ammonia through the heat exchange unit. a liquid transfer unit for transferring to the unit; and a gas-phase transfer unit communicating with the waste ammonia storage unit to transfer gas-phase ammonia stored in the waste ammonia storage unit to the recovered ammonia storage unit through a compression unit and a heat exchange unit.

The gas phase transfer unit according to the present invention is provided with a first separation unit through which gaseous ammonia transferred from the waste ammonia storage unit is primarily introduced and a second separation unit through which gaseous ammonia discharged from the first separation unit is introduced secondarily, It can remove foreign substances from ammonia.

In the present invention, a first gas-phase transfer unit for transferring the gas-phase ammonia discharged from the first separation unit directly to the compression unit is provided, and a second gas-phase transfer unit for transferring the gas-phase ammonia discharged from the first separation unit to the second separation unit is provided. and a third vapor transfer unit for transferring gaseous ammonia discharged from the second separation unit to the compression unit may be provided.

In the present invention, the first gas-phase transfer unit is provided with a first valve for controlling the transfer of gaseous ammonia, the second vapor-phase transfer unit is provided with a second valve for controlling the transfer of vapor-phase ammonia, and the third vapor-phase transfer unit is provided with gaseous ammonia A third valve is provided for controlling the transfer, and the opening and closing of the first valve, the second valve, and the third valve may be controlled by a control unit.

In the present invention, the control unit may be provided with a first operating mode to directly transfer the gaseous ammonia discharged from the first separation unit to the compression unit.

In the present invention, the first operating mode may open the first valve, close the second valve and the third valve, and apply a negative pressure to the first separation unit through the compression unit.

In the present invention, the control unit may be provided with a second operation mode in which gaseous ammonia discharged from the first separation unit is transferred to the compression unit through the second separation unit.

In the present invention, the second operation mode has a 2-1 operation mode in which the first valve and the second valve are closed, and the third valve is opened, and then negative pressure is applied to the second separation unit through the compression unit. can

In the present invention, after the 2-1 operation mode, the first valve and the third valve are closed and the second valve is opened, so that gaseous ammonia is transferred to the compression unit through the first separation unit and the second separation unit. It may have a 2-2 operation mode.

In the present invention, the gas phase transfer unit is provided with a fourth valve on one side transferred from the compression unit to the heat exchange unit, and the control unit closes the fourth valve to recover unreacted gaseous ammonia to the waste ammonia storage unit.

In the present invention, the first separation unit and the second separation unit may be provided with an inlet, an upper outlet, and a lower outlet, respectively.

In the present invention, filters are respectively disposed inside the first separation unit and the second separation unit, gaseous ammonia flows under the filter, and gaseous ammonia passes through the filter and then through the upper outlet provided on the upper side of the filter can be emitted.

In the present invention, the second separation unit may be provided to be larger than the first separation unit.

In the present invention, gaseous ammonia may be transferred to the heat exchange unit through an oil separation unit provided between the compression unit and the heat exchange unit.

In the present invention, gaseous ammonia may be condensed through the condensing unit in the heat exchange unit.

In the present invention, the condensed ammonia may be transferred to a recovered ammonia storage unit.

The waste ammonia recovery device provided with a double separator according to the present invention has the following effects.

First, there is an effect of recycling by recovering and recycling the waste ammonia refrigerant.

Second, there is an effect of independently separating and recovering liquid ammonia and gaseous ammonia.

Third, there is an effect of simultaneously recovering liquid ammonia and gaseous ammonia.

Fourth, by utilizing the double separator, there is an effect of increasing the recovery rate and purity of gaseous ammonia.

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a schematic diagram of a waste ammonia recovery device according to the present invention.
2 is a view for explaining the operating principle of the first separation unit and the second separation unit of the gas phase transfer unit according to the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described so that those of ordinary skill in the art can easily carry out the present invention. As can be easily understood by those of ordinary skill in the art to which the present invention pertains, the embodiments described below may be modified in various forms without departing from the concept and scope of the present invention. Wherever possible, identical or similar parts are denoted by the same reference numerals in the drawings.

The terminology used herein is for the purpose of referring to specific embodiments only, and is not intended to limit the present invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite.

The meaning of "comprising," as used herein, specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component and/or It does not exclude the presence or addition of groups.

All terms including technical terms and scientific terms used in this specification have the same meaning as those commonly understood by those of ordinary skill in the art to which the present invention belongs. Terms defined in the dictionary are further interpreted as having a meaning consistent with the related art literature and the presently disclosed content, and unless defined, are not interpreted in an ideal or very formal meaning.

The present invention corresponds to a technology for recovering and refining ammonia gas, which is mainly used as a refrigerant in a refrigeration warehouse, when completely replacing the ammonia gas.

The present invention is characterized by a technology for simultaneously removing liquid and gaseous ammonia gas.

Hereinafter, the present invention will be described with reference to the drawings. For reference, the drawings may be partially exaggerated in order to explain the features of the present invention. In this case, it is preferable to be interpreted in light of the whole meaning of this specification.

1 is a schematic diagram of a waste ammonia recovery device according to the present invention. 2 is a view for explaining the operating principle of the first separation unit and the second separation unit of the gas phase transfer unit according to the present invention.

As shown in FIG. 1, the waste ammonia recovery apparatus according to the present invention has a conveying unit, a compression unit, a heat exchange unit, and a condensing unit controlled by a control unit (not shown). The control unit may be driven by a computing means.

The waste ammonia recovery device according to the present invention communicates with the waste ammonia storage unit 10 and transfers the liquid ammonia stored in the waste ammonia storage unit 10 to the recovered ammonia storage unit 20 through the heat exchange unit 400 . transfer unit 100; and a vapor transfer unit communicating with the waste ammonia storage unit 10 and transferring the vapor phase ammonia stored in the waste ammonia storage unit 10 to the recovered ammonia storage unit 20 through the compression unit 300 and the heat exchange unit 400 ( 200) is included.

A general recovery device is operated by replacing a liquid phase transfer line and a gas phase transfer line in the same recovery line. In this case, there is a risk of refrigerant leakage, and the present invention is a structure for independently separating the liquid phase transfer unit 100 and the gas phase transfer unit 200 . Due to this structure, since replacement installation is unnecessary, refrigerant leakage during replacement installation can be prevented.

Liquid ammonia can be used immediately, but in the case of gaseous ammonia, water, oil, and other foreign substances contained in the gaseous ammonia must be removed. The present invention has a feature of removing such foreign substances by using a double separation unit.

The gas phase transfer unit 200 according to the present invention is a first separation unit 210 into which gaseous ammonia transported from the waste ammonia storage unit 10 is primarily introduced and a gas phase ammonia discharged from the first separation unit 210 is 2 It is possible to remove foreign substances from gaseous ammonia by providing the second separation unit 220 that is introduced sequentially.

The second separation unit according to the present invention is configured to increase the recovery rate of ammonia gas and to allow the reuse of gas by separating oil.

As shown in FIG. 2 , a first gas phase transfer unit 201 for transferring gaseous ammonia discharged from the first separation unit 210 directly to the compression unit 300 is provided, and in the first separation unit 210 , A second gas phase transfer unit 202 for transferring the discharged gaseous ammonia to the second separation unit 220 is provided, and a third gas phase for transferring the gaseous ammonia discharged from the second separation unit 220 to the compression unit 300 . A transfer unit 203 may be provided.

Each vapor transport unit may be provided with the same transport pipe.

In the present invention, the first gas-phase transfer unit 201 is provided with a first valve 231 for controlling the transfer of vapor-phase ammonia, and the second vapor-phase transfer unit 202 has a second valve for controlling transfer of vapor-phase ammonia 232 is provided, and the third gas phase transfer unit 203 is provided with a third valve 233 for controlling the transfer of gaseous ammonia, and the first valve, the second valve and the third valve are opened and closed by the control unit can be controlled.

In the present invention, the basic structure of the first separating unit 210 and the second separating unit 220 is the same. However, it is preferable that the second separation unit 220 is larger than the first separation unit 210 in order to generate a negative pressure, control a foreign material removal rate and a recovery rate, and the like.

The first separation unit 210 and the second separation unit 220 according to the present invention may be provided with inlets 211 and 221, upper outlets 212 and 222, and lower outlets 213 and 223, respectively. have.

Gas phase ammonia is introduced through the inlet, and foreign substances such as moisture and oil separated by the first separation unit and the second separation unit may be discharged through the lower outlet. The gaseous ammonia may move upward and be discharged through the upper outlet.

In the present invention, filters 214 and 224 may be disposed inside the first separating part 210 and the second separating part 220, respectively. In this case, gaseous ammonia may be introduced under the filter, and gaseous ammonia may be discharged through an upper outlet provided above the filter after passing through the filter. The filter functions to remove foreign substances as much as possible and increase the purity of gaseous ammonia.

Hereinafter, the first operation mode and the second operation mode in which the first separation unit and the second separation unit are operated through the control unit will be described.

In the case of the first operation mode according to the present invention, the control unit is an operation mode in which the gaseous ammonia discharged from the first separation unit 210 is directly transferred to the compression unit 300 .

In the first operating mode, the first valve 231 is opened, the second valve 232 and the third valve 233 are closed, and negative pressure is applied to the first separation unit 210 through the compression unit 300 . let it go

By the negative pressure, gaseous ammonia in the first separation unit 210 may be directly transferred to the compression unit 300 .

In the case of the second operation mode according to the present invention, the control unit is an operation mode in which the gaseous ammonia discharged from the first separation unit 210 is transferred to the compression unit 300 through the second separation unit 220 .

The second operation mode may be sequentially implemented by being divided into a 2-1 operation mode and a 2-2 operation mode.

In the 2-1 operation mode, after closing the first valve 231 and the second valve 232 , and opening the third valve 233 , the second separation unit 220 through the compression unit 300 . It is an operating mode in which negative pressure is applied.

In the 2-2 operation mode, after the 2-1 operation mode, the first valve 231 and the third valve 233 are closed, and the second valve 232 is opened, so that gaseous ammonia is separated from the first separation unit ( 210) and the second separation unit 220, the operation mode is transferred to the compression unit (300).

In the second operation mode, the residual gas remaining in the gas phase transfer unit may be efficiently recovered, thereby increasing the recovery rate of the total waste ammonia and may also increase the purity.

The compression unit 300 pressurizes the gaseous ammonia refrigerant through compression to increase the temperature of the refrigerant gas, and as a result, the distance between molecules becomes a dense state, which can be easily liquefied at room temperature.

The compression unit 300 may be driven by a separate driving unit 600 .

The compression unit 300 may be operated in connection with a separate cooling water supply unit 700 .

The cooling water supply unit 700 may also be used as a device for storing and supplying cooling water used in the heat exchange unit.

In the present invention, the gas phase transfer unit 200 may be provided with a fourth valve 234 on one side transferred from the compression unit 300 to the heat exchange unit 400 . The controller may close the fourth valve 234 to recover unreacted gaseous ammonia to the waste ammonia storage unit 10 .

The non-response may be determined by using a separate detection sensor.

In addition, by arranging a pressure sensor (not shown) at a plurality of positions of the gas phase transfer unit according to the present invention, the pressure such as negative pressure is checked and transmitted to the control unit, so that the control unit can control the overall system.

In the present invention, gaseous ammonia may be transferred to the heat exchange unit 400 through the oil separation unit 230 provided between the compression unit 300 and the heat exchange unit 400 .

The heat exchange unit 400 may mix the waste ammonia refrigerant composed of the introduced liquid and gaseous phases.

The oil separation unit 230 serves to remove oil, such as lubricating oil, into gaseous ammonia while passing through the compression unit 300 . That is, the oil separation unit corresponds to a kind of buffer device for removing foreign substances of refrigeration oil or oil component entering the compression unit and recovering gaseous ammonia.

In the present invention, gaseous ammonia may be condensed through the condensing unit 500 in the heat exchange unit 400 .

The condensing unit 500 cools and liquefies the high-temperature and high-pressure waste ammonia refrigerant delivered through the compression unit 300 by a water cooling type (water), an evaporation type (latent heat of evaporation), an air cooling type (atmospheric sensible heat), and the like.

In the present invention, the condensed ammonia may be transferred to the recovered ammonia storage unit 20 .

The embodiments described in this specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Accordingly, since the embodiments disclosed in the present specification are for explanation rather than limitation of the technical spirit of the present invention, it is obvious that the scope of the technical spirit of the present invention is not limited by these embodiments. Modifications and specific embodiments that can be easily inferred by those skilled in the art within the scope of the technical spirit included in the specification and drawings of the present invention should be interpreted as being included in the scope of the present invention.

10: waste ammonia storage unit 20: recovered ammonia storage unit
100: liquid transfer unit 200: vapor transfer unit
201: first vapor transfer unit 202: second vapor transfer unit
203: third gas phase transfer unit
210: first separation 211: inlet
212: upper outlet 213: lower outlet
214: filter
220: second separation 221: inlet
222: upper outlet 223: lower outlet
224: filter
231: first valve 232: second valve
233: third valve 234: fourth valve
240: oil separation unit
300: compression unit 400: heat exchange unit
500: condensing unit 600: driving unit
700: cooling water supply unit 800: water tank

Claims (15)

A waste ammonia recovery device having a transfer unit, a compression unit, a heat exchange unit, and a condensing unit whose operation is controlled by a control unit,
a liquid transfer unit communicating with the waste ammonia storage unit and transferring the liquid ammonia stored in the waste ammonia storage unit to the recovered ammonia storage unit through the heat exchange unit; and
It communicates with the waste ammonia storage unit and includes a gas phase transfer unit for transferring the gaseous ammonia stored in the waste ammonia storage unit to the recovered ammonia storage unit through a compression unit and a heat exchange unit,
The gas phase transfer unit includes a first separation unit through which gaseous ammonia transferred from the waste ammonia storage unit is primarily introduced and a second separation unit through which gaseous ammonia discharged from the first separation unit is introduced secondarily, and foreign substances from gaseous ammonia Waste ammonia recovery device with a double separation unit, characterized in that to remove. The method according to claim 1,
A first gas-phase transfer unit for transferring the gas-phase ammonia discharged from the first separation unit directly to the compression unit is provided;
A second gas phase transfer unit for transferring the gaseous ammonia discharged from the first separation unit to the second separation unit is provided,
A waste ammonia recovery device with a double separation unit, characterized in that the third gas phase transfer unit for transferring the gaseous ammonia discharged from the second separation unit to the compression unit is provided. The method according to claim 1,
The first gas-phase transfer unit is provided with a first valve for controlling the transfer of vapor-phase ammonia,
The second gas-phase transfer unit is provided with a second valve for controlling the transfer of vapor-phase ammonia,
The third vapor transfer unit is provided with a third valve for controlling transfer of vapor phase ammonia,
The first valve, the second valve and the third valve is a waste ammonia recovery device with a double separator, characterized in that the opening and closing is controlled by a control unit. The method according to claim 3, wherein the control unit
A waste ammonia recovery device with a double separator, characterized in that it is provided with a first operation mode for directly transferring gaseous ammonia discharged from the first separator to the compression part. 5. The method according to claim 4,
The first operating mode is
open the first valve, close the second and third valves,
A waste ammonia recovery device with a double separation unit, characterized in that the negative pressure is applied to the first separation unit through the compression unit. The method according to claim 3, wherein the control unit
A waste ammonia recovery device with a double separator, characterized in that it is provided with a second operation mode in which gaseous ammonia discharged from the first separator is transferred to the compression part through the second separator. 6. The method of claim 5,
The second operating mode is
After closing the first and second valves and opening the third valve,
A waste ammonia recovery device with a double separation unit, characterized in that it has a 2-1 operation mode in which negative pressure is applied to the second separation unit through the compression unit. 8. The method of claim 7,
After the 2-1 operation mode,
closing the first and third valves and opening the second valve,
A waste ammonia recovery device with a double separation unit, characterized in that it has a 2-2 operation mode in which gaseous ammonia is transferred to the compression unit through the first separation unit and the second separation unit. The method according to claim 1,
A fourth valve is provided at one side transferred from the compression unit to the heat exchange unit in the gas phase transfer unit,
The control unit closes the fourth valve to recover unreacted gaseous ammonia to the waste ammonia storage unit. The method according to claim 1,
A waste ammonia recovery device with a double separation unit, characterized in that the first separation unit and the second separation unit are provided with an inlet, an upper outlet and a lower outlet, respectively. 11. The method of claim 10,
A filter is disposed inside the first separation unit and the second separation unit, respectively,
gaseous ammonia is introduced under the filter,
Gas-phase ammonia is a waste ammonia recovery device with a double separator, characterized in that discharged through the upper outlet provided on the upper side of the filter after passing through the filter. The method according to claim 1,
A waste ammonia recovery device with a double separation unit, characterized in that the second separation unit is larger than the first separation unit. The method according to claim 1,
Gas-phase ammonia is a waste ammonia recovery device provided with a double separation unit, characterized in that transferred to the heat exchange unit through the oil separation unit provided between the compression unit and the heat exchange unit. 14. The method of claim 13,
Gas-phase ammonia is a waste ammonia recovery device with a double separator, characterized in that condensed through the condensing unit in the heat exchange unit. 15. The method of claim 14,
The condensed ammonia is a waste ammonia recovery device with a double separator, characterized in that transferred to the recovered ammonia storage.

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