KR102026430B1 - Dryice blasting apparatus with pneumatic generator based on gas generator - Google Patents

Abstract

The present invention relates to a dry ice washer comprising a pneumatic generator using a decomposition reaction of a gas generator, the dry ice pellet storage unit is configured in the form of a hopper filled with dry ice pellets narrowed in the upper direction; A dry ice pellet supply unit for supplying dry ice pellets from the dry ice pellet storage unit to the following injection pipes; A pneumatic generator for decomposing the gas generating agent as a catalyst for promoting the decomposition reaction of the gas generating agent, and generating a high pressure gas by using the gas generated therein; A dry ice spray pipe whose one side is connected to the pneumatic generator and is discharged to the other side along with the dry ice pellets supplied from the dry ice pellet supply unit; A dry ice injection control gun connected to the other side of the dry ice injection pipe to control injection of dry ice pellets mixed with high pressure gas; And a nozzle coupled to the dry ice injection control gun for injecting dry ice pellets mixed with high-pressure gas to the outside, and a pneumatic generator using a decomposition reaction of a gas generator.

Description

DRYICE BLASTING APPARATUS WITH PNEUMATIC GENERATOR BASED ON GAS GENERATOR}

The present invention relates to a dry ice cleaner including a gas generator-based pneumatic generator, and more particularly, to a dry ice pellet sprayed at high speed without using a conventional pneumatic generator. Relates to a washer.

The present invention relates to a dry ice washer for washing contaminants such as rust on the surface of equipment and molds. Conventionally, although chlorine, hydrocarbon, compliant, and water based cleaners are used, there is no toxicity, flammability, volatility, etc. There is a disadvantage of high and long washing process and long washing time, high pressure washing with no harmful water has a high water content and can only be limited to equipment and mold, there was a problem such as electrical short and rust.

In addition, there is a washing method using abrasive particles such as sand, metal balls, glass grains, etc., because the surface is scraped off and washed, shortening the life of equipment and molds and causing secondary pollutants.

Dry ice washer developed due to the above problem is to spray the dry ice pellets at high pressure to clean the contaminants on the surface of the equipment and mold, dry cleaning method can be used in water difficult to clean, there is no toxicity and no harmful It is eco-friendly and harmless to workers because there is no discharge of secondary pollutants, and it is possible to clean the object without separation, and there is no need for post-treatment process such as drying. The problem with the washing method using particles and the like was solved.

Next, the prior art existing in the field to which the technology of the present invention belongs will be briefly described, and then the technical matters to be made differently from the prior art will be described.

First, Korean Patent Publication No. 10-0363955 (2002.12.11.) Relates to a dry ice washer that cleans various machinery and facilities by spraying particles of dry ice at high speed with compressed air. The frame plate is supported in the case and the discharge hole is drilled in the vertical direction, the guide plate is fixed to the upper portion of the frame plate and having a guide groove in the left and right direction, and the guide groove of the guide plate and sliding in the left and right directions by the cylinder It is possible to slide the opening rods in the vertical direction, the upper portion is wider and the lower portion is formed narrowly and has a outlet at the lower end of the hopper connected to the left and right inlet hole of the slide rod, one end of the frame through the inlet hole Pressure that connects to the discharge hole of the plate and the other end is connected to the compressor to blow the compressed air Airline and, at its one end portion is connected to the frame plate, the lower discharge hole and the other end has the structure of the dry ice jet cleaner consisting of a hose connected to the case it described minutes.

In addition, Korean Patent Publication No. 10-0781588 (Nov. 27, 2007) relates to a dry ice washer that cleans and cleans various machinery and facilities by spraying dry ice particles at high speed with compressed air. Shinan Publication No. 20-2008-0006336 (2008.12.18.) Forcibly impinges dry ice pellets on the surface of the object to be cleaned; And a method for cleaning the outer wall by dry ice pellets, the method comprising blowing contaminants spaced apart from the surface by blowing air pressure from the surface.

As described above, the dry ice cleaner until now uses a method of generating high pressure air through a pneumatic generator such as a compressor using a fan motor, and spraying dry ice pellets at high speed using the high pressure air. Large and pneumatic devices were an essential component.

As described above, since the conventional dry ice cleaner uses a pneumatic generator such as a compressor using a fan motor to inject dry ice pellets, the volume and weight of the device is large and costly in constructing the dry ice cleaner. There was a problem. In addition, there is a problem that the mobility is poor due to the volume and weight of the dry ice cleaner by the conventional pneumatic generator.

The present invention was created to solve the above problems, in a dry ice washing machine for spraying dry ice or dry ice snow at high speed to wash the surface of equipment, mold, etc., by contacting the gas generator with a catalyst or the like It is an object of the present invention to provide a new dry ice washer that does not require a pneumatic generator using a separate mechanical power by generating a gas and spraying dry ice using the generated gas. In addition, it is an object of the present invention to provide a dry ice washer using a pneumatic generator that is easy to apply a dry ice washer by appropriately adjusting the heat of reaction that can be simultaneously generated in the generation of high pressure gas through the gas generator.

A dry ice washer comprising a pneumatic generator using a decomposition reaction of a gas generating agent according to an embodiment of the present invention, the dry ice pellets are composed of a dry ice pellet is formed in the hopper form narrowed in the upper direction to the lower direction Storage unit; A dry ice pellet supply unit for supplying dry ice pellets from the dry ice pellet storage unit to the following injection pipes; A pneumatic generator for decomposing and reacting a gas generator using a catalyst to generate a high pressure gas; A dry ice spray pipe having one side connected to the pneumatic generator and discharged to the other side along with the dry ice pellet supplied from the dry ice pellet supply unit; A dry ice injection control gun connected to the other side of the dry ice injection pipe to control injection of dry ice pellets mixed with high pressure gas; And a nozzle coupled to the dry ice spray control gun for spraying dry ice pellets mixed with the high pressure gas to the outside.

In addition, as an embodiment, the dry ice may be obtained and stored in a solid phase, but may also be in the form of dry ice snow formed by adiabatic expansion of liquefied carbon dioxide. The dry ice washer in this case can be formed as follows.

That is, the liquefied carbon dioxide gas storage unit for storing the liquefied carbon dioxide gas: liquefied carbon dioxide gas adiabatic expansion unit for adiabatic expansion of the liquefied carbon dioxide gas supplied from the liquefied carbon dioxide gas storage unit to generate dry ice snow; A pneumatic generator for decomposing and reacting the gas generating agent so that the gas generated therein can be used to discharge dry ice snow; A dry ice injection pipe whose one side is connected to the pneumatic generator and is discharged to the other side along with the dry ice snow generated in the liquefied carbon dioxide adiabatic expansion unit; A dry ice injection control gun connected to the other side of the dry ice injection pipe to control injection of dry ice snow mixed with the generated gas; And a nozzle for injecting dry ice snow mixed with the gas generated by being coupled to the dry ice injection control gun to the outside; and a pneumatic generator using a decomposition reaction of a gas generator. It may be configured in the form of.

In addition, as an embodiment, the pneumatic generator, at least one refrigerant passage to which a refrigerant including ambient air or cooling water is supplied; And at least one gas generating passage having a catalyst coated on the wall and supplying a gas generating agent to generate a gas by reacting with the catalyst coated on the wall to generate a decomposition reaction. Adjacent to the gas generating passage in a structure such as a heat exchanger, it characterized in that to lower the temperature of the gas generating passage is raised due to the heat generated in the decomposition reaction of the gas generating agent.

In addition, as an embodiment, the pneumatic generator is characterized in that it has a heat exchanger structure of any one selected from double tube type, shell and tube type, cross flow type, plate type, compact type or helical heat exchanger.

In addition, as an embodiment, the gas generating passage is generated in the gas generating passage in the lower portion of the gas generating passage to prevent the water generated during the gas generating agent decomposition reaction from flowing into the dry ice injection pipe. Characterized in that it comprises a; reaction water outlet that is discharged water.

In addition, as an embodiment, the gas generating flow path, a gas generator injection unit for injecting a gas generating agent to the catalyst coated on the wall of the gas generating flow path; characterized in that it comprises a.

In addition, as an embodiment, the lower portion of the gas generating flow path; reaction water outlet for discharging the water generated during the decomposition of the gas generator; characterized in that it comprises a.

In addition, as an embodiment, the pneumatic generator is connected to the reaction water outlet of the gas generating passage, and stores the water discharged from the gas generating passage, the pressure of the gas generated in the gas generating passage is the reaction water Reaction water storage tank so as not to be lowered due to the outlet; characterized in that it further comprises.

In addition, as an embodiment, the pneumatic generator, characterized in that it further comprises a compressor body storage tank located between the upper portion of the gas generating passage and the dry ice injection pipe.

In addition, as an embodiment, the dry ice pellet supply unit is located below the dry ice pellet storage unit, the receiving groove is provided at regular intervals along the circumference of the dry ice pellet discharged to the dry ice pellet storage unit by gravity It is characterized in that the feeding to the injection pipe through the rotating disk or screw conveyor is formed.

In one embodiment, the gas generator is hydrogen peroxide, and the gas generator is platinum, silver, palladium, iridium, manganese oxide metal, iron oxide metal, perovskite-based La0.8Sr0.2CoO3. It is characterized in that the decomposition reaction by a catalyst comprising at least one or more.

The present invention is a dry ice washer to clean the surface of equipment, molds, etc. by spraying dry ice pellets at a high speed, in the dry ice washer, instead of a pneumatic generator that used a conventional mechanical power, a gas generator based on manganese dioxide or the like By spraying the dry ice pellets using the gas and pressure generated in the decomposition reaction of the catalyst, the size, weight and construction cost of the dry ice cleaner can be reduced, and the mobility can be improved to effectively utilize the dry ice cleaner in the industrial field. It has an effect.

1 is a view showing the structure of a conventional dry ice cleaner.
2 is an exemplary view for explaining a structure of a dry ice washer including a pneumatic generator using a decomposition reaction of a gas generator according to an embodiment of the present invention.
3 is an exemplary view for explaining a structure of a pneumatic generator of a dry ice washer including a pneumatic generator using a decomposition reaction of a gas generator according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings it will be described in detail a dry ice cleaner without a pneumatic device so that those skilled in the art can easily carry out the present invention.

In the drawings of the present invention, the size or dimensions of the structures are shown to be enlarged or reduced than actual for clarity of the present invention, and well-known configuration is omitted to show the characteristic configuration is not limited to the drawings. .

In describing the principles of the preferred embodiment of the present invention in detail, if it is determined that the detailed description of the related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In the present invention, "dry ice" refers to both dry ice and externally supplied in the form of pellets, and liquefied carbonic acid gas is adiabaticly expanded in a part of the dry ice washer to form dry ice snow.

In addition, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dry ice washer, wherein in a dry ice washer that sprays dry ice pellets at high speed to clean surfaces of equipment, molds, etc. It relates to a new dry ice washer to spray dry ice pellets using.

1 is a view showing the structure of a conventional dry ice cleaner 10 of the related art.

As shown in FIG. 1, a conventional general dry ice cleaner includes a pneumatic generator for generating high pressure air in order to spray dry ice pellets at a high speed. The pneumatic generator of the conventional dry ice cleaner is as described above. (11) compresses air and stores it in a tank using an air compression device composed of a piston, an impeller, a screw, and the like by using a mechanical power such as a motor such as an air compressor. It has a structure for injecting high pressure air stored in the tank with dry ice pellets.

Conventional pneumatic generator 11 as described above, by using a mechanical power, such as a motor to operate the air compression device such as piston, impeller, screw to configure the device due to the structural characteristics to compress the air and store in the tank There is a problem that a lot of cost and space is consumed, the weight of the device is a lot, a separate power source is required to operate the mechanical power, the mobility of the device is reduced, and the noise occurs in the operation of the device.

In order to solve the problems of the conventional pneumatic generator 11 of the dry ice cleaner, the present invention is to replace the pneumatic generator of the dry ice cleaner, generated through the decomposition reaction of the gas generator using a catalyst, etc. By using a gas-based pneumatic generator to configure the conventional pneumatic generator, it is possible to spray dry ice pellets without including the configuration of the mechanical power, air compression device, etc. that is the configuration of the pneumatic generator of the conventional dry ice cleaner It can generate the necessary gas pressure, which saves the cost and space required to construct the device, reduces the weight and eliminates the need for a separate power source, increasing device mobility and reducing noise. It can greatly improve the usability in the field.

2 is an exemplary view for explaining the structure of the dry ice cleaner 100 including the pneumatic generator 130 using the decomposition reaction of the gas generator according to an embodiment of the present invention.

As shown in FIG. 2, the dry ice cleaner 100 of the present invention includes a dry ice pellet storage unit 110, a dry ice pellet supply unit 120, a pneumatic generator 130, and a dry ice spray pipe 140. ), A dry ice spray control gun 150 and a nozzle 160.

More specifically, the dry ice pellet storage unit 110 is filled with dry ice pellets, is composed of a hopper-shaped housing that narrows from the top to the lower direction, the upper portion of the dry ice pellet storage unit 110 An inlet for filling the ice pellets is formed, the lower portion is formed with an outlet for discharging dry ice.

The dry ice pellet supply unit 120 supplies dry ice pellets from the dry ice pellet storage unit 110 to the following injection pipes, and the dry ice pellets supplied to the injection pipes are discharged from the pneumatic generator 130. It is carried in the gas and discharged to the outside.

In addition, the dry ice pellet supply unit 120 is located under the dry ice pellet storage unit, and supplies dry ice pellets discharged to the dry ice pellet storage outlet through the gravity by gravity to the injection pipe, the dry ice pellets The supply unit 120 may use a rotary disk method or a screw conveyor method to supply dry ice pellets to the injection pipe.

The rotary disk moves the dry ice pellets of the dry ice pellet storage unit to the dry ice spray pipe through the receiving groove while the rotating disk having the receiving grooves formed at regular intervals along the circumference rotates. The amount of dry ice pellets injected may be adjusted according to the rotational speed of the rotary disk.

In addition, the screw conveyor moves the dry ice pellets to the dry ice injection pipe by the screw blade while the spiral screw rotates, and like the rotating disk, the amount of dry ice pellets injected according to the rotational speed may be adjusted. Or it may take the form which dry ice comes in by injection of a compressor body.

The dry ice pellet storage unit may be replaced with a liquefied carbon dioxide storage unit. If the dry ice pellet storage is thus replaced by the liquefied carbon dioxide storage, the dry ice pellet supply must be replaced by the liquefied carbon dioxide adiabatic expansion. The liquefied carbonic acid gas will adiabaticly expand to form dry ice snow, and the generated dry ice snow is continuously discharged to the dry ice injection control gun using the gas generated in the pneumatic generator.

Here, the pneumatic generator 130 is a device for decomposing and reacting the gas generating agent using a manganese dioxide or the like as a catalyst, and to replace the pneumatic pressure using the gas generated therein.

The gas generator includes, but is not limited to, hydrazine (N2H4), monomethylhydrazine (MMH, CH3N2H3), asymmetric dimethylhydrazine (UDMH, C2H8N2), nitrous oxide (N2O), hydroxylammonium nitreart (HAN, NH3OHNO3), high Draginium nitroformate (HNF, N2H5C (NO2) 3), ammonium dinitramide (ADN, NH4N (NO2) 2), amnonium nitrate (AN, NH4NO3), hydrogen peroxide (H2O2), etc. The use of hydrogen peroxide is preferred for its environmental stability and accessibility.

The dry ice washer according to the present invention includes a gas generator storage tank 135 for storing the gas generator before supplying the gas generator to the gas generator flow path in the pneumatic generator 130. The storage tank 135 may be a structure included in the pneumatic generator 130, or may be of a structure provided outside the pneumatic generator 130.

If the gas generator is hydrogen peroxide, the decomposition reaction using the catalyst is as follows.

[Scheme]

Catalyst + 2H2O2 → Catalyst + 2H2O + O2

As described above, when the catalyst and hydrogen peroxide meet, hydrogen peroxide is decomposed into oxygen (O 2) and water (H 2 O).

That is, when hydrogen peroxide in the liquid state meets the catalyst, water vapor (water) and oxygen are generated, and dry ice pellets are injected by using the pressure of the generated oxygen. The catalyst is not limited thereto, but precious metals such as platinum, silver, palladium, iridium, and the like, or manganese oxide, oxidized steel, etc. Oxides of transition metals, La 0.8 Sr 0.2 CoO 3 of perovskite series, and the like may be used.

On the other hand, one side of the dry ice injection pipe 140 is connected to the pneumatic generator 130, the high-pressure gas flows from the pneumatic generator 130, dry ice is supplied from the dry ice pellet supply unit 120 It has a structure that is discharged to the other side with the pellet.

In addition, the dry ice injection control gun 150 is connected to the other side of the dry ice injection pipe 140 to control the injection of the dry ice pellets mixed with the high-pressure gas. The dry ice spray control gun 150 controls the spray of the dry ice pellets may include a switch, a button, a dial, and a handle.

The nozzle 160 is coupled to the dry ice spray control gun 150 to inject the dry ice pellets mixed with the high-pressure gas to the outside, the outlet discharged dry ice pellets vary depending on the washing target, washing method It can be manufactured in a shape.

On the other hand, hydrogen peroxide as a gas generating agent generates water (H 2 O) while decomposing as shown in the reaction scheme, which may be included in the gas generated in the gas phase of water vapor.

If water vapor generated from the pneumatic generator 130 flows into the dry ice spray pipe 140, it meets with the dry ice pellets and immediately cools with ice to dry ice spray pipe 140, dry ice spray control gun 150 or nozzle ( The problem of blocking the passage of 160 will occur.

In order to prevent such a problem from occurring, the pneumatic generator 130 of the dry ice cleaner 100 of the present invention lowers the temperature of the gas generating passage 131 to liquefy water vapor generated in the hydrogen peroxide decomposition reaction with water and then dry ice spray pipe. Do not discharge to 140.

 That is, the pneumatic generator 130 of the dry ice washer 100 of the present invention can prevent the condensable material from being discharged together with the gas to the dry ice injection pipe 140 at the temperature of dry ice, such as water vapor. It may have a structure, the prevention structure may be a system capable of liquefying the water vapor by cooling, or an adsorption method that can adsorb water vapor or a mixed structure of these methods.

3 is a structure of a pneumatic generator 130 of a dry ice cleaner 100 including a pneumatic generator 130 using a gas generator decomposition reaction when the gas generator is hydrogen peroxide according to an embodiment of the present invention. It is an example figure for demonstrating.

As shown in FIG. 3, the pneumatic generator 130 of the dry ice washer 100 according to the present invention includes at least one refrigerant passage 132 to which a coolant such as air and cooling water is supplied, and a catalyst on a wall thereof. It is coated and comprises a gas generator is supplied with at least one gas generating passage 131 for generating a gas while reacting with a catalyst coated on the wall to cause a decomposition reaction, the refrigerant passage 132 is The temperature rise of the generated gas is reduced by lowering the temperature of the gas generating passage 131 which is raised due to the heat generated in the decomposition reaction of the gas releasing agent, adjacent to the gas generating passage 131 in a structure such as a partition heat exchanger. You can prevent it.

For reference, the heat exchanger structure of the pneumatic generator 130 may be any one heat exchanger structure selected from a double tube type, shell end type tube type, cross flow type, plate type, compact type, or spiral type heat exchanger.

The gas generation passage 131 may include a gas generator injection unit for injecting the gas generator to the catalyst coated on the wall of the passage. The gas generator injection unit may be configured with various structures of a known technique as a device capable of evenly injecting the gas generator to the catalyst coated on the wall of the gas generating passage 131.

In addition, the gas generation passage 131 is a gas generation passage to prevent a condensable material from flowing into the dry ice injection pipe 140 at a temperature of dry ice such as water generated during a gas generator decomposition reaction. The lower portion 131 includes a reaction water outlet through which water generated during the gas generator decomposition reaction is discharged.

For example, when the gas generator is hydrogen peroxide, hydrogen peroxide injected into the gas generating passage 131 is decomposed into water and oxygen gas, and the generated water flows downward along the wall of the oxygen generating passage 131 to discharge the reaction water. And the oxygen gas is moved to the upper portion of the gas generating passage 131 to be discharged to the dry ice injection pipe 140.

A high pressure gas storage tank may be provided between the upper portion of the gas generation passage 131 and the dry ice injection pipe 140.

Meanwhile, the reaction water storage tank may be connected to the reaction water outlet of the gas generation passage 131 to prevent the pressure of the gas generated in the gas generation passage 131 from being lowered due to the reaction water outlet.

The present invention has been described above with reference to the embodiments shown in the drawings, but this is merely exemplary, and those skilled in the art to which the art belongs may various modifications and other equivalent embodiments therefrom. I will understand the point. Therefore, the technical protection scope of the present invention will be defined by the claims below.

10: dry ice washer (conventional)
11: pneumatic generator (conventional)
12: dry ice hopper (conventional)
13: dry ice supply unit (conventional)
14 discharge pipe (conventional)
15: spray gun (conventional)
16: nozzle (conventional)
100: Dry Ice Washer
110: dry ice pellet storage unit
120: dry ice pellet supply unit
130: pneumatic generator
131: gas generation flow path
132: refrigerant path
135: gas generator storage tank
140: dry ice injection pipe
150: dry ice spray control gun
160: nozzle

Claims (9)

A dry ice pellet storage unit configured to be filled with dry ice pellets and formed in a hopper shape that is narrowed in a downward direction from an upper side thereof;
A dry ice pellet supply unit for supplying dry ice pellets from the dry ice pellet storage unit to the following injection pipes;
A pneumatic generator for decomposing and reacting the gas generating agent to use the gas generated therein for dry ice discharge;
A dry ice spray pipe having one side connected to the pneumatic generator and the gas introduced into the other side together with the dry ice pellets supplied from the dry ice pellet supply unit;
A dry ice injection control gun connected to the other side of the dry ice injection pipe to control injection of dry ice pellets mixed with the generated gas and injected; And
And a nozzle for injecting dry ice pellets mixed with the gas generated by being coupled to the dry ice injection control gun to the outside.
The pneumatic generator includes at least one refrigerant passage to which a refrigerant including air or cooling water is supplied; And
A catalyst is coated on the wall to promote the decomposition reaction of the gas generator, at least one gas generating passage for generating a gas while reacting with the catalyst is supplied to the gas generator is coated on the wall to generate a decomposition reaction; ,
The refrigerant passage has a structure such as a partition wall heat exchanger, adjacent to the gas generating passage, to lower the temperature of the gas generating passage that is raised due to heat generated in the decomposition reaction of the gas generating agent. Dry ice cleaner comprising a pneumatic generator used. delete The method of claim 1,
The pneumatic generator,
Dry ice comprising a pneumatic generator using the decomposition reaction of the gas generator, characterized in that having a heat exchanger structure of any one selected from double tube, shell and tube, cross flow, plate, compact or helical heat exchanger syringe. The method of claim 1,
The gas generation passage,
And a reaction water outlet through which water generated during the gas generator decomposition reaction is discharged to the lower portion of the gas generation passage to prevent water generated during the gas generator decomposition reaction from being introduced into the dry ice injection pipe. Dry ice washer comprising a pneumatic generator using a decomposition reaction of the gas generator. The method of claim 1,
The gas generation passage,
And a gas generator injection unit for injecting a gas generator into the catalyst coated on the wall of the gas generation passage. The dry ice cleaner comprising a pneumatic generator using a decomposition reaction of the gas generator. The method of claim 1,
The pneumatic generator,
And a generator gas storage tank positioned between the upper portion of the gas generating passage and the compressed air discharge pipe. 2. The dry ice washer comprising the pneumatic generator using the decomposition reaction of the gas generator. The method of claim 1,
The dry ice pellet supply unit is located below the dry ice pellet storage unit, and a rotating disk or screw conveyor having receiving grooves formed at regular intervals along the circumference of dry ice pellets discharged to the dry ice pellet storage unit by gravity. Dry ice washer comprising a pneumatic generator using a decomposition reaction of the gas generator, characterized in that to supply to the injection pipe through. Liquefied carbon gas storage unit for storing liquefied carbon dioxide:
A liquefied carbonate gas adiabatic expansion unit for adiabatic expansion of the liquefied carbonate gas supplied from the liquefied carbon dioxide storage unit to generate dry ice snow;
A pneumatic generator for decomposing and reacting the gas generating agent so that the gas generated therein can be used to discharge dry ice snow;
A dry ice injection pipe whose one side is connected to the pneumatic generator and is discharged to the other side along with the dry ice snow generated in the liquefied carbon dioxide adiabatic expansion unit;
A dry ice injection control gun connected to the other side of the dry ice injection pipe to control injection of dry ice snow mixed with the generated gas; And
And a nozzle for injecting dry ice snow mixed with the gas generated by being coupled to the dry ice injection control gun to the outside.
The pneumatic generator includes at least one refrigerant passage to which a refrigerant including air or cooling water is supplied; And
A catalyst is coated on the wall to promote the decomposition reaction of the gas generator, at least one gas generating passage for generating a gas while reacting with the catalyst is supplied to the gas generator is coated on the wall to generate a decomposition reaction; ,
The refrigerant passage has a structure such as a partition wall heat exchanger, adjacent to the gas generating passage, to lower the temperature of the gas generating passage that is raised due to heat generated in the decomposition reaction of the gas generating agent. Dry ice cleaner comprising a pneumatic generator using. The method according to any one of claims 1 and 3 to 8,
The gas generator is hydrogen peroxide, and the gas generator decomposition catalyst may include at least one of platinum, silver, palladium, iridium, manganese oxide metal, iron oxide metal, and perovskite series La _0.8 Sr _0.2 CoO ₃ . Dry ice washer comprising a pneumatic generator using a decomposition reaction of the gas generator, characterized in that the decomposition reaction by a catalyst containing the above.

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