KR20180017946A - Liquid blast cleaning device - Google Patents

Abstract

The present invention relates to a direct injection cleaning device using liquefied carbon dioxide gas, comprising: a main body portion; a liquefied carbon dioxide storage portion for supplying stored liquefied carbon dioxide gas to the main body portion; a carrier gas supply portion for supplying carrier gas to the main body portion; and an injection portion for mixing the liquefied carbon dioxide gas and the carrier gas passed through the main body portion therein, atomizing the mixture, and injecting the atomized mixture for cleaning. Unlike to a prior art, the liquefied carbon dioxide gas is not processed through a dry ice pellet manufacturing process and is directly converted into an extra fine dry ice shape within an injector for cleaning an object to be cleaned, thereby capable of reducing a number of facilities and simplifying the cleaning process.

Description

{LIQUID BLAST CLEANING DEVICE}

More particularly, the present invention relates to a direct powder cleaning apparatus using liquefied carbon dioxide gas, and more particularly, to a direct powder cleaning apparatus using liquefied carbon dioxide gas, in which liquid carbon dioxide gas is directly converted into ultra- And more particularly, to a direct powder cleaning apparatus using liquefied carbon dioxide which can reduce the number of facilities and simplify the cleaning process.

The dry ice spray type cleaning device is a device that cleans various machinery and facilities by spraying particles of dry ice with compressed air at high speed.

Such a dry ice spray type cleaning device ejects hard dry ice particles which are harmless to industrial facilities and environment at a high speed and sublimes into harmless gas immediately upon collision with the surface to remove only foreign substances without damaging the washing surface, Do not leave pollutants or moisture.

Therefore, the dry ice cleaning method can extend the service life of the equipment, reduce the time required for the cleaning operation, and the time and cost required to collect and treat the secondary contaminants generated by the conventional cleaning, Can be saved.

A conventional dry ice spray type cleaning apparatus is provided with a rotor which is rotatably installed in a lower portion of an outlet of a hopper. The rotor is provided with a supply groove Are formed.

Compressed air is introduced into the air supply pipe by the compressor, and the dry ice pellets supplied from the supply grooves are discharged to the other side by the compressed air.

When the rotational force is transmitted to the rotor, the rotor is rotated, and the dry ice pellets are discharged from the hopper and filled in the supply groove formed in the outer periphery. The dry ice pellet filled in the supply groove falls when the rotor rotates and the supply groove is positioned downward. The dropped dry ice pellet flows at a high speed by the compressed air generated in the compressor and flowing in the air supply pipe, It can be sprayed strongly.

However, vibrations due to the operation of the vibrator are transmitted to other structures through the hopper, thereby deteriorating the durability and causing excessive noise, thereby deteriorating the working environment.

In order to solve this problem, Korean Utility Model Registration No. 20-0299381 (registered on Dec. 13, 2002, entitled: Design of a Dry Ice Blasting Apparatus), dry ice particles are selectively made to have a diameter of 1-5 mm , The supply amount of the dry ice particles is automatically controlled, and the residual particles in the pulverizing container after the cleaning operation can be conveniently removed.

However, in the conventional dry ice spraying apparatus, there is a problem that the initial investment cost for introducing the dry ice blaster equipment, the compressor facility, the dry ice manufacturing equipment, etc. is high and the continuous supply of dry ice is increased.

The technical structure described above is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for preparing pellets of a dry ice washing machine using a conventional dry ice pellet by directly converting the inside thereof into ultrafine dry ice, And it is an object of the present invention to provide a direct powder cleaning apparatus using a liquefied carbon dioxide gas which does not require any loss and is free from pellet entanglement and can be automated.

The present invention provides a direct powder cleaning apparatus using liquid carbon dioxide which can be efficiently cleaned as compared with a dry ice cleaner, except when high-intensity cleaning is required in consideration of losses occurring in the process of manufacturing dry ice pellets It has its purpose.

A direct powder washer cleaning apparatus using liquefied carbon dioxide gas according to the present invention comprises: a main body portion; A liquefied carbon dioxide gas storage unit for supplying the stored liquefied carbon dioxide gas to the main body unit; A carrier gas supply unit for supplying a carrier gas to the main body; And a jetting part for mixing the liquid carbonic acid gas and the carrier gas passing through the body part inside and atomizing the liquid carbonic acid gas and spraying it for washing.

The liquefied carbon dioxide gas storage part may be mounted on the moving part.

The supply amount of the liquefied carbon dioxide gas and the carrier gas transferred to the inside of the main body can be controlled by the control unit.

Wherein the jetting unit comprises: a jetting block for atomizing the liquefied carbon dioxide gas discharged from the main body part and the carrier gas after they are mixed; And an injection nozzle for injecting and guiding the atomized liquid carbon dioxide gas and the carrier gas.

Wherein the injection block comprises: a body; A liquefied carbon dioxide gas passage formed in the body and supplied with a predetermined amount of liquefied carbon dioxide gas from the body portion; A carrier gas passage formed in the body and supplied with a predetermined amount of carrier gas from the main body; An expansion unit formed in the liquefied carbon dioxide gas passage extending into the body and having a reduced diameter, for passing the supplied liquefied carbon dioxide gas while passing the liquefied carbon dioxide gas; And a vortex forming portion formed at a joint portion of the carrier gas passage extending to the inside of the body so as to be inclined with respect to the center axis of the liquefied carbon dioxide gas passage and inducing a vortex when mixing the liquefied carbon dioxide gas and the carrier gas.

The injection block includes a liquefied carbon dioxide gas which forms a vortex in the vortex forming part, and a throttle part which is formed inside the body to impart discharge straightness to the carrier gas.

As described above, unlike the conventional art, the direct powder cleaning apparatus using the liquefied carbon dioxide gas according to the present invention requires direct use of the dry ice pellets by directly converting into an ultra-fine dry ice form in the sprayer, It is not necessary to prepare and store the pellets in comparison with the dry ice washer, so that the loss can be reduced, and pellet entanglement phenomenon does not occur and automation can be possible.

In addition, the present invention can efficiently clean the dry ice pellet, compared to the dry ice washer, except for the case where high strength washing is required in consideration of loss occurring in the process of manufacturing dry ice pellets.

1 is a configuration diagram of a direct powder cleaning apparatus using liquefied carbon dioxide gas according to an embodiment of the present invention.
FIG. 2 is an enlarged view of a spraying portion of the direct powder cleaning apparatus using liquefied carbon dioxide according to an embodiment of the present invention.
3 is a cross-sectional view of a main portion of an ejection portion according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the direct powder cleaning apparatus using liquid carbon dioxide according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a configuration diagram of a direct powder washer cleaning apparatus using liquefied carbon dioxide gas according to an embodiment of the present invention, and FIG. 2 is an enlarged view of a direct spray cleaning apparatus using a liquefied carbon dioxide gas according to an embodiment of the present invention. And FIG. 3 is a cross-sectional view of the main part of the injection unit according to the embodiment of the present invention.

1 to 3, a direct powder cleaning apparatus 100 using liquid carbon dioxide according to an embodiment of the present invention includes a main body 110, a liquefied carbon dioxide storage unit 120, a carrier gas supply unit 130 And a jetting section 200.

The main body 110 plays a role of discharging the supplied liquefied carbon dioxide gas by a predetermined amount while temporarily storing it, or guiding the liquefied carbon dioxide gas to pass through it. The main body 110 serves to guide and discharge the supplied carrier gas by a certain amount while temporarily storing the carrier gas or to guide the carrier gas.

Particularly, the main body 110 may be provided with a pump (not shown) for discharging the liquefied carbon dioxide gas and the carrier gas at the set pressure, respectively.

At this time, the liquefied carbon dioxide gas serves as a washing water for washing the object to be cleaned, and the carrier gas is discharged at a set pressure while flowing at a high pressure.

 The body portion 110 can be easily moved to the position of the object to be cleaned by providing the wheel 112. [ Of course, the main body 110 can be deformed into various shapes.

The liquefied carbon dioxide gas storage unit 120 stores liquefied carbon dioxide gas to be sprayed onto the object to be cleaned and supplies liquefied carbon dioxide gas to the body unit 110. At this time, the liquefied carbon dioxide gas storage unit 120 is in the form of a tank, and the liquefied carbon dioxide storage unit 120 and the body unit 110 are connected to the liquefied carbon dioxide gas delivery hose 122.

Of course, the liquefied carbon dioxide delivery hose 122 may be connected to the body 110 and the liquefied carbon dioxide storage 120 in a variety of ways. In addition, the liquefied carbon dioxide gas storage unit 120 or the liquefied carbon dioxide gas delivery hose 122 may include an intermittent valve (not shown) for interrupting the flow of the liquefied carbon dioxide gas.

On the other hand, the carrier gas supply unit 130 stores a carrier gas which serves to increase the fluidity of the liquefied carbon dioxide gas, and supplies the carrier gas to the main body 110. At this time, the carrier gas supply unit 130 is in the form of a tank, and the carrier gas supply unit 130 and the body unit 110 are connected to each other by a carrier gas transfer hose 132.

Of course, the carrier gas transfer hose 132 may be connected to the main body 110 and the carrier gas supply 130 in various ways. In addition, the carrier gas supply unit 130 or the carrier gas transfer hose 132 may include an intermittent valve (not shown) for interrupting the flow of the carrier gas.

Here, the carrier gas is in a gaseous state and applicable to various gases.

Particularly, the main body 110 independently flows the liquefied carbon dioxide gas and the carrier gas.

In addition, the jetting unit 200 mixes the liquefied carbon dioxide gas passing through the main body 110 and the carrier gas internally, and atomizes the liquid carbon dioxide gas and the carrier gas, and injects the liquid carbon dioxide gas for washing.

At this time, the relatively bulky liquid carbon dioxide storage part 120 is moved to the moving part 124 and is easily moved. The moving means 124 is formed to variously fix the liquefied carbon dioxide storage unit 120 and to facilitate the movement of the liquefied carbon dioxide storage unit 120. Of course, the moving means 124 can be variously applied.

The supply amount of the liquefied carbon dioxide gas and the carrier gas to be transferred into the main body 110 can be controlled by the control unit 114. That is, the controller 114 can control the supply amount of the liquefied carbonic acid gas and the carrier gas to be supplied into the main body 110, respectively, after detecting the supply amount of the liquefied carbonic acid gas and the carrier gas supplied into the main body 110 . In addition, the controller 114 controls the main body 110 to discharge the liquefied carbon dioxide gas and the carrier gas in a predetermined amount.

The jetting unit 200 includes a jetting block 210 and a jetting nozzle 220.

The injection block 210 serves to directly supply the liquefied carbon dioxide gas and the carrier gas from the main body 200 and mix them to atomize them directly.

At this time, the ejection block 210 can detachably attach the handle 230.

The injection nozzle 220 is mixed inside the injection block 210, and serves to spray the atomized liquefied carbon dioxide gas and the carrier gas to the object to be cleaned. Of course, the injection nozzle 220 is applicable in various ways.

Particularly, the injection block 210 includes a body 211, a liquefied carbon dioxide gas passage 212, a carrier gas passage 213, an expansion portion 214, a vortex forming portion 216 and a throttle portion 217.

The body 211 forms an outer shape of the injection block 210 and removably connects the handle 230 to one side and integrally or detachably connects the injection nozzle 220 to the other side.

Of course, the body 211 can be deformed into various shapes.

The liquefied carbon dioxide gas passage 212 is formed in the body 211 and serves to receive liquefied carbon dioxide gas from the body 110 in a predetermined amount and the carrier gas passage 213 is formed in the body 211 And serves to receive carrier gas from the main body 110 by a predetermined amount.

Accordingly, the liquefied carbon dioxide gas passage 212 and the carrier gas passage 213 form a port opened to the body 211, respectively.

Particularly, as an example, the carrier gas passage 213 is formed in a hole shape penetrating the body 211 on both sides. The liquefied carbon dioxide gas passage 212 is formed in the body 211 so as to be inclined with respect to the central axis direction of the carrier gas passage 213 and connected to the carrier gas passage 213 inside the body 211.

Of course, the carrier gas passage 213 may be connected to the liquefied carbon dioxide gas passage 212.

The expansion portion 214 is formed in the liquefied carbon dioxide gas passage 212 extending to the inside of the body 211 so that the diameter of the liquefied carbon dioxide gas is drastically reduced and the supplied liquefied carbon dioxide gas is passed therethrough, . That is, the liquefied carbon dioxide gas is atomized into a solid state due to the pressure drop as it passes through the expanding portion 214. That is, the liquefied carbon dioxide gas is snowed while passing through the expansion portion 214. For the sake of convenience, the fluid that has been atomized in the subsequent liquid phase state is also referred to as liquefied carbon dioxide gas.

The vortex forming portion 216 is formed in the body 211 so that the corresponding portion of the carrier gas passage 213 connected to the liquefied carbon dioxide gas passage 212, that is, the liquefied carbon dioxide gas passage 212, As shown in Fig. Thus, the liquefied carbon dioxide gas and the carrier gas are mixed in the vortex forming portion 216 to form a vortex. By mixing the liquefied carbon dioxide gas and the carrier gas as much as possible, the carrier gas can concentrate and transport the liquefied carbon dioxide gas in the discharge direction.

The throttle portion 217 is formed so that the diameter of the throttle portion 217 is reduced inside the body 211 in order to impart discharge straightness to the liquefied carbon dioxide gas and the carrier gas forming the vortex in the vortex forming portion 216. As a result, the mixed liquefied carbon dioxide gas and the carrier gas are accelerated while passing through the throttle portion 217, thereby reaching the set discharge pressure.

As a result, the main body 110 supplies the liquefied carbon dioxide gas supplied from the liquefied carbon dioxide storage unit 120 and the carrier gas supplied from the carrier gas supply unit 130 into the injection block 210.

The injection block 210 injects the liquid carbon dioxide gas and the carrier gas through the injection nozzle 220 while mixing the liquid carbon dioxide gas and the carrier gas.

The moving unit 124 easily transports the liquefied carbon dioxide storage unit 120 having a high weight and fixes the liquefied carbon dioxide storage unit 120 in various ways.

In addition, the liquefied carbon dioxide gas storage unit 120 is a reservoir capable of stably storing and storing liquefied carbon dioxide gas, and has a function of increasing pressure and decreasing pressure, and can be detachably attached to the main body unit 110.

The control unit 114 controls the amount of the carrier gas supplied from the carrier gas supply unit 130 and the amount of the liquefied carbon dioxide gas supplied from the liquefied carbon dioxide storage unit 120.

The jetting unit 200 includes a jetting block 210, an injection nozzle 220, and a handle 230. The jetting unit 200 includes a jetting block 210, a jetting nozzle 220, and a handle 230.

At this time, the handle 230 is grasped by an operator to direct the injection nozzle 220 in a desired direction, and the operation switch 240 can be operated to eject or stop the operation.

The injection block 210 converts the supplied liquefied carbon dioxide gas into fine particles (ultrafine dry ice snow) through the expansion part 214 and then guides the liquefied carbon dioxide gas to the vortex forming part 216.

The vortex forming portion 216 allows the mixed liquefied carbon dioxide gas and the carrier gas to form a vortex, and the throttle portion 217 is further accelerated by passing the mixed carrier gas and the liquefied carbon dioxide gas, thereby enabling more effective cleaning.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the true scope of the present invention should be determined by the following claims.

100: straight line cleaning device 110:
114: control unit 120: liquefied carbon dioxide gas storage unit
124: moving means 130: carrier gas supply unit
200: Dispenser 211: Body
212: liquefied carbon dioxide gas passage 213: carrier gas passage
214: expansion part 216: vortex forming part
217: throttle part 220: injection nozzle
230: Handle portion

Claims (6)

A body portion;
A liquefied carbon dioxide gas storage unit for supplying the stored liquefied carbon dioxide gas to the main body unit;
A carrier gas supply unit for supplying a carrier gas to the main body; And
And a jetting portion for jetting the liquid carbon dioxide gas and the carrier gas passing through the body portion for washing after atomizing and mixing the liquid carbon dioxide gas and the carrier gas.
The method according to claim 1,
Wherein the liquefied carbon dioxide gas storage part is mounted on a moving part.
The method according to claim 1,
Wherein the supply amount of the liquefied carbon dioxide gas and the carrier gas transferred to the inside of the main body is controlled by a control unit.
The apparatus according to claim 1,
A spray block for atomizing the liquid carbonic acid gas and the carrier gas discharged from the main body portion after mixing them; And
And a spray nozzle for spraying and guiding the atomized liquefied carbon dioxide gas and the carrier gas.
[5] The apparatus according to claim 4,
body;
A liquefied carbon dioxide gas passage formed in the body and supplied with a predetermined amount of liquefied carbon dioxide gas from the body portion;
A carrier gas passage formed in the body and supplied with a predetermined amount of carrier gas from the main body;
An expansion unit formed in the liquefied carbon dioxide gas passage extending into the body and having a reduced diameter, for passing the supplied liquefied carbon dioxide gas while passing the liquefied carbon dioxide gas; And
And a vortex forming portion formed at a joint portion of the carrier gas passage extending into the body so as to be inclined with respect to the central axis of the liquefied carbon dioxide gas passage and inducing a vortex when mixing the liquefied carbon dioxide gas and the carrier gas A direct powder cleaning system using liquefied carbon dioxide gas.
6. The method of claim 5,
Wherein the injection block includes a liquefied carbon dioxide gas which forms a vortex in the vortex forming part and a throttle part which is formed in the body in order to impart discharge straightness to the carrier gas. .

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