CN112517544A - Dry ice particle adjusting device and dry cleaning machine capable of controlling dry ice particles - Google Patents

Abstract

The present invention relates to a dry ice particle adjusting device and a dry cleaning machine capable of controlling dry ice particles, which can adjust cleaning force by selectively and freely adjusting particle diameters of dry ice, and aims to clean various mechanical devices, equipment and the like by spraying the dry ice with the adjusted particle diameters at a high speed by compressed air. The dry ice particle regulating device according to the present invention includes: a body part, wherein an inlet for inputting dry ice is formed at the upper side of the body part, and a discharge port for discharging the dry ice is formed at the lower side of the body part; a grinding part including a grinder disposed in the inner space of the body part and grinding dry ice, and a support part disposed opposite to the grinder and supporting the dry ice; and an adjusting part which enables the supporting part to move forwards or backwards relative to the grinding machine in order to adjust the grinding range of the dry ice. The dry cleaning machine capable of controlling dry ice particles comprises: a dry ice particle adjusting device that adjusts the particle size of the dry ice; and a spraying part which is arranged on the main body part and sprays the dry ice collected in the collecting tank of the fixing component to the outside.

Description

Dry ice particle adjusting device and dry cleaning machine capable of controlling dry ice particles

Technical Field

The present invention relates to a dry ice particle adjusting device and a dry cleaner capable of controlling dry ice particles, and more particularly, to a dry ice particle adjusting device and a dry cleaner capable of controlling dry ice particles, which can selectively and freely adjust the particle size of dry ice, and can clean various machines, equipment, and the like by ejecting the dry ice having the adjusted particle size at a high speed by compressed air.

Background

Recently, a technique for cleaning the surface of an object to be cleaned without any defect has been developed for dry cleaning using sublimable solid particles typified by dry ice.

Dry ice, which is one of the sublimable solid particles used in the dry cleaning process, is formed into a pellet shape, and the pellet-shaped dry ice is mixed with high-pressure compressed air and sprayed onto the surface of the cleaning object, thereby cleaning the cleaning object.

In a conventional dry ice cleaning device, hard dry ice particles harmless to industrial equipment and the environment are sprayed at a high speed to remove foreign matters.

Since the amount and speed of the dry ice sprayed can be adjusted to some extent, foreign substances attached to the surfaces of machines and products made of various materials, such as ceramics, synthetic resins, rare metals, glass fibers, rubbers, plastics, steel materials, etc., can be removed. The dry ice particles can be immediately sublimated into harmless gas by colliding with the surface, and only foreign matters are removed without causing any damage to the cleaning surface, and pollutants, moisture and the like are not left for 2 times.

If dry ice cleaning is adopted, investment expenses newly invested in a punching die, a forming frame and the like can be saved due to the fact that the service life of equipment is prolonged. The time required for the cleaning work and the time and expense required for collecting and treating 2 contaminants generated in the conventional cleaning can be reduced, and thus the total operating expenses can be reduced. At present, production facilities or products can be perfectly cleaned at industrial sites even without using Volatile Organic Compounds (VOC), Ozone Depleting Substances (ODS), wastewater-inducing solvents, and the like, which are prohibited from being used by environmental protection related regulations.

Dry ice cleaning is widely used in all industrial fields such as food processing, pastry making, rubber, plastics, pharmacy, automobile manufacturing, aircraft maintenance, space aviation, electrical and electronic, semiconductor industry, petrochemical, iron making, printing, casting industry and the like. Dry ice cleaning is currently used in all industrial fields that depend on chemical products such as sandblasting (sandblasting), steam cleaning, solvents (solvent), etc., or on conventional cleaning operations such as manual scraping, etc., so that not only can the cost be saved, the productivity be improved, the quality be improved, the environment be protected, but also a safe and clean working environment can be ensured.

As described above, the conventional dry ice cleaning apparatus, which is carefully examined, includes: a hopper formed to have a wide upper portion and a narrow lower portion so that dry ice can be filled therein, and having an inlet and an outlet at a lower end thereof; a rotor provided rotatably at a lower portion of an outlet of the hopper, and having a supply groove formed at an outer periphery thereof at regular intervals, the supply groove being capable of receiving a supply of dry ice discharged from the outlet; and a supply pipe connected to the supply tank of the rotor, for discharging the dry ice falling from the supply tank by compressed air of the compressor.

In such a conventional dry ice cleaning device, if the rotor is rotated by the motor, the rotor rotates and, at the same time, dry ice is discharged from the hopper and filled into the supply groove formed on the outer periphery thereof, and then falls down to the supply pipe. At this time, if the compressor injects compressed air, the dry ice pellets are injected at a high speed and collide with the surface of the object to be cleaned, thereby removing the foreign matter layer.

However, the conventional dry ice cleaning device has a problem that the cleaning power cannot be adjusted because the particle size of the dry ice cannot be adjusted.

Further, since the adjustment of the cleaning force is not easy, there is a problem that damage due to impact is generated when cleaning precision electronic parts and the like.

Prior art documents

Patent document

(patent document 001) Korean registered patent publication No. 10-0662241 (2006.12.28 publication)

Disclosure of Invention

The present invention has been made to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide a dry ice particle adjusting device and a dry cleaner capable of controlling dry ice particles, which can selectively and freely adjust the particle size of dry ice, and can clean various mechanical devices, equipment, and the like by spraying the dry ice having the adjusted particle size at a high speed with compressed air.

The dry ice particle regulating device according to the present invention includes: a body part, wherein an inlet for inputting dry ice is formed at the upper side of the body part, and a discharge port for discharging the dry ice is formed at the lower side of the body part; a grinding part including a grinder disposed in the inner space of the body part and grinding dry ice, and a support part disposed opposite to the grinder and supporting the dry ice; and an adjusting part which enables the supporting part to move forwards or backwards relative to the grinding machine in order to adjust the grinding range of the dry ice.

And the support part is formed into a polygonal body so as to generate surface friction to the dry ice.

Further, the adjusting portion includes:

a rotating shaft eccentrically fixed to the support portion; a rotation control member including a rotation handle disposed outside the main body and a spacing adjustment lever coupled to the rotation handle and rotating the rotation shaft in the same direction while rotating in a forward direction or a reverse direction to adjust a spacing between the support portion and the grinding machine; a fixing member facing the grinding machine, having an inlet groove for the support part to enter and exit in a height direction, having an inclined surface on which dry ice falls, and having a collecting groove formed on a bottom surface for collecting the dry ice falling between the grinding machine and the support part; and a protective member disposed opposite to the fixing member to protect the grinder.

The apparatus further includes a display unit disposed on an outer surface of the main body, the display unit being operated in conjunction with the rotation of the interval adjustment lever, and the display unit numerically displaying a particle diameter of the ground dry ice.

The dry cleaning machine capable of controlling dry ice particles comprises: a dry ice particle adjusting device that adjusts the particle size of the dry ice; and a spraying part provided in the body part and spraying dry ice collected in the collecting tank of the fixing member to the outside.

And, the injection part includes:

an air compressor which supplies compressed air to the internal space of the body part to discharge the ground dry ice; a supply pipe connected to the main body and configured to transfer dry ice discharged by an air compressor; a jet body part connected to the supply pipe and receiving the supplied dry ice; a spray nozzle connected to the spray body part and spraying dry ice; first and second detachable parts which make the supply pipe and the injection nozzle combined with or separated from the injection body part respectively.

Further, an on/off switch for controlling the operation of the air supply portion is formed in the ejection body portion.

And, a control module that controls the grinder and the air compressor.

And the control module enables the air compressor to operate firstly in a set time period when the injection part inputs a start signal so as to discharge the foreign matters and the moisture in the collecting tank through the injection nozzle, and enables the air compressor to operate in the set time period when the injection part inputs an end signal so as to discharge the foreign matters and the moisture in the collecting tank through the injection nozzle.

Further, the dry ice container includes a forming portion that forms a plurality of mountain portions and valley portions intersecting each other on an outer surface of the dry ice.

The forming section includes:

an upper mold in which first receiving grooves for receiving lower portions of dry ice are formed at regular intervals in a longitudinal direction, wherein a plurality of first pressing projections are formed in the first receiving grooves so as to be spaced apart from each other, the first pressing projections being formed by pressing dry ice so that mountain portions and valley portions are formed; a lower mold disposed above the upper mold, wherein an upper portion of the dry ice received in the first receiving groove is received in a second receiving groove formed at a predetermined interval in a longitudinal direction, and a plurality of second pressing projections formed in the second receiving groove by pressing the dry ice so that a peak portion and a trough portion are formed to be spaced apart from each other; a lifting driving part which enables the lower die to descend so that the first pressurizing protrusion and the second pressurizing protrusion pressurize the dry ice; a rotation plate which is opposite to the main body and is used for placing the formed dry ice on the rotation plate; a vertical rotation guide shaft, the shaft of which is fixed on one side of the bottom surface of the rotation plate; and a rotation driving part which enables the rotation plate to rotate along the vertical direction so as to throw the dry ice of the rotation plate into the body part.

According to the dry ice particle adjusting device and the dry cleaning machine capable of controlling dry ice particles of the present invention, by adjusting the particle size of dry ice and spraying the dry ice particles onto the object to be cleaned, the cleaning force can be easily adjusted, thereby preventing damage to the surface of the object to be cleaned and effectively cleaning a portion having a high requirement for cleaning density.

Drawings

Fig. 1 is a perspective view showing a dry ice particle adjusting apparatus according to the present invention.

Fig. 2 is a plan view showing a state in which a grinding part applied to the dry ice particle adjustment device according to the present invention is provided inside a body part.

Fig. 3 is an exploded perspective view illustrating a dry ice particle adjusting apparatus according to the present invention.

Fig. 4 and 5 are perspective views showing a state of connection between the grinding part and the regulating part, which is applied to the dry ice particle regulating device according to the present invention.

Fig. 6 is a block diagram showing the connection relationship of the control module, the motor, and the air compressor in the dry ice cleaning machine according to the present invention.

Fig. 7 is a perspective view illustrating a dry cleaning machine capable of controlling dry ice particles according to the present invention.

Fig. 8 is a perspective view showing first and second detachable portions of a dry cleaner which is applied to the controllable dry ice particles according to the present invention.

Fig. 9 is a perspective view showing the operation of the first and second detaching portions of the dry cleaner suitable for controlling dry ice particles according to the present invention.

Fig. 10 is a sectional view showing an upper mold, a lower mold, and a lifting driving part applied to a dry cleaner capable of controlling dry ice particles according to the present invention.

Fig. 11 and 12 are views showing operation states of a spin plate, a spin guide shaft, and a spin driving unit applied to a dry cleaner capable of controlling dry ice particles according to the present invention.

Description of the reference symbols

1: dry ice particle adjustment device 10: body part

10 a: the housing space 11: cover for portable electronic device

12: bottom surface 12 a: nozzle hole

13: RPM adjusting portion 14: pressure regulating part

15: first additional detachment portion 16: second additional detachable part

20: polishing section 21: grinding machine

211: rotation shaft 22: supporting part

23: the rotating guide plate 30: regulating part

31: rotation control section 311: rotary handle

312: the interval adjustment lever 32: rotating shaft

33: fixing member 33 a: guide surface

33 b: exit-entrance groove 33 c: collecting tank

331: inclined surface 34: protective component

35: the housing 40: display unit

50: the control module 100: dry cleaning machine

110: the air compressor 111: air tube

120: ejection portion 121: supply pipe

122: the ejection body portion 123: spray nozzle

1231: connection pipe 124: first detachable part

1241. 1251: body portions 1242, 1252: pressure ball

1243,1253: lead-in 1244, 1254: operation part

125: second detachment portion 130: forming section

131: upper mold 131 a: first containing groove

1311: first pressing projection 132 lower mold

132 a: second housing groove 1321: second pressing projection

133: elevation drive unit 134: rotating plate

135: rotating the guide shaft 136: rotary driving part

Detailed Description

The advantages and features of the present invention, as well as the means for achieving the same, will be apparent from the following detailed description of the embodiments with reference to the accompanying drawings.

However, the present invention is not limited to the embodiments described below, and can be realized in different forms, and the embodiments are only perfected to explain the scope of the invention to those having ordinary knowledge in the art to which the present invention pertains, and the present invention is defined only 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 having ordinary knowledge in the art to which the present invention pertains can easily carry out the embodiments. However, the present invention can be realized in various forms, and is not limited to the embodiments described herein. Like parts are given the same reference numerals throughout the specification.

Fig. 1 is a perspective view showing a dry ice particle adjusting device according to the present invention, fig. 2 is a plan view showing a state in which a grinding part applied to the dry ice particle adjusting device according to the present invention is disposed inside a body part, fig. 3 is an exploded perspective view showing the dry ice particle adjusting device according to the present invention, fig. 4 and 5 are perspective views showing a state in which the grinding part and the adjusting part applied to the dry ice particle adjusting device according to the present invention are combined, and fig. 6 is a block diagram showing a connection relationship of a control module, a motor, and an air compressor in a dry ice cleaning machine according to the present invention.

The dry ice particle adjustment device 1 according to the present invention may include a body part 10, a grinding part 20, and an adjustment part 30.

The main body 10 is formed in a substantially polygonal box shape or a circular box shape, and has an inlet formed on the upper surface thereof, into which pellet-shaped dry ice D is put.

Further, an accommodating space 10a for accommodating dry ice D is formed inside the main body 10, an exposure hole 12a is formed in a central portion of the bottom surface 12 of the accommodating space 10a, and the exposure hole 12a exposes a polishing portion 20 described later while allowing the dry ice D to pass therethrough.

The bottom surface 12 is formed in a shape whose width gradually decreases from the upper portion toward the lower portion where the exposure hole 12a is formed. Therefore, the dry ice D falling on the bottom surface 12 descends along the inclined path of the bottom surface 12 and is supplied to the grinding section 20.

Further, a discharge port is formed at the lower side of the main body 10, and the discharge port can discharge the dry ice D, the particle size of which is adjusted by the grinding part 20, to the outside.

A lid 11 for opening and closing the input button is hinged to the upper side of the main body 10.

Further, on the outer surface of the main body 10 are provided: a dial-type RPM (Revolutions Per Minute) adjusting unit 134 that adjusts the RPM of a driving unit that rotates the grinder 21, which will be described later, to adjust the amount of dry ice D sprayed; and a dial-up control type pressure adjusting unit 14 for adjusting the pressure of the air compressor 110 to adjust the speed of spraying the dry ice D.

The grinding unit 20 adjusts the particle size of the dry ice D, and includes a grinder 21 and a support 22 disposed opposite to each other in the internal space of the main body 10.

The grinder 21 is rotated in situ by the power of a motor (not shown), and a serrated blade (not shown) that continuously grinds the dry ice D along the edge face is continuously formed at certain intervals.

The grinder 21 is formed with a hollow portion, and a rotating shaft 211 is provided to penetrate the hollow portion.

Both sides of the rotating shaft 211 protrude to the outside of the grinder 21 and are fixed between a pair of rotating guide plates 23.

The support portion 22 is disposed on a fixing member 33, which will be described later, so as to be spaced from the grinder 21 with an adjustable distance.

The support portion 22 is spaced apart from the grinder 21 at a prescribed interval so that the dry ice D can pass through.

In other words, the dry ice D falling through the exposure hole 12a is ground by the grinder 21 in a state of being supported by the support portion 22, so that the particle diameter is changed.

At this time, the support portion 22 is formed as a polygonal body so as to generate surface friction of the dry ice D. A through hole 22a is formed eccentrically in the support portion 22, and a rotating shaft 32 described later is inserted through the through hole 22 a.

The adjusting portion 30 is configured to adjust the interval between the grinder 21 and the supporting portion 22 so that the particle size of the dry ice D can be selectively adjusted.

In other words, the adjustment unit 30 moves the support 22 forward or backward with respect to the grinder 21 to adjust the interval and determine the particle diameter of the dry ice D matching the interval.

For this, the adjusting part 30 may include a rotation shaft 32, a rotation control member 31, a fixing member 33, and a shielding member 34.

The rotating shaft 32 is eccentrically disposed on the support portion 22 by penetrating the through hole provided in the support portion 22 as described above.

The rotating shaft 32 rotates in accordance with the operation of a rotation control member 31 described later, thereby adjusting the distance between the support portion 22 and the grinder 21.

The rotation control part 31 is a structure for providing power for moving the grinder 21, and may include a rotation handle 311 and a spacing adjustment lever 312.

The rotation knob 311 is exposed to the outside of the body portion 10 so as to be controllable by an operator.

The rotation knob 311 may be formed in a circular shape, and a plurality of valleys and peaks preventing the sliding of the finger are continuously formed to cross along the edge thereof.

The interval adjustment lever 312 may be formed in a circular rod shape having a certain length and diameter, and buried in the inner space of the case 35.

The housing 35 is disposed in a space provided below the bottom surface 12 of the main body 10, and is spaced apart from the grinder 21 and the support portion 22 by a predetermined interval.

At this time, a portion of the rotating shaft 32 is introduced into the inner space of the housing 35 so as to be opposite to the interval adjusting lever 312.

And, gears (not shown) engaged with each other are installed at the outer circumference of the interval adjustment rod 312 and the outer circumference of the rotation shaft 32, respectively.

Therefore, the interval adjustment lever 312 can be rotated in a forward direction or a reverse direction by rotating the handle 311 outside the body 10, and the rotating shaft 32 and the support portion 22 are rotated in the rotating direction of the interval adjustment lever 312, so that the support portion 22 approaches or separates from the grinder 21.

Therefore, the distance between the grinder 21 and the support portion 22 is adjusted by rotating the handle 311 in the forward direction or the reverse direction to rotate the distance adjustment lever 312, and then the dry ice D is poured and molded into a desired particle size.

The fixing member 33 is disposed in an internal space separately provided below the bottom surface 12 of the main body 10 and faces the grinder 21.

An inclined surface 331 for dropping the dry ice D passing through the exposure hole 12a is formed on the upper surface of the fixing member 33.

Further, an outlet groove 33b into which the support portion 22 can be inserted and removed is formed at an approximately central portion in the height direction of the fixing member 33, and a collecting groove 33c for collecting dry ice D having a particle diameter changed by the grinder 21 and the support portion 22 is formed in the bottom surface in the longitudinal direction.

At this time, the support portion 22 is movable forward or backward with respect to the grinder 21 in a state of being accommodated in the entrance groove 33b, and moves in a direction of being drawn out from the entrance groove 33b when moving forward, and moves in a direction of being drawn into the entrance groove 33b when moving backward.

Also, a connection hole (not shown) connected to the catch tank 33c is formed in the body portion 10, and a spray portion 120 of the dry cleaner 100, which can control dry ice particles, which will be described later, is connected to the connection hole.

A guide surface 33a formed in an inclined direction and guiding the dry ice D in the direction of the catch tank 33c is formed between the entrance/exit tank 33b and the catch tank 33 c.

The guard member 34 is disposed opposite to the fixing member 33 to protect the grinder 21.

A receiving groove (not shown) for receiving a part of the grinder 21 may be formed at a surface of the shielding member 34 opposite to the fixing member 33.

Further, a display unit 40 is provided on the outer surface of the main body 10, and the display unit 40 is operated in conjunction with the rotation of the interval adjustment lever 312, and indicates the particle diameter of the dry ice D to be ground by a numeral.

The display unit 40 includes a 3-digit or 4-digit number (including a decimal point).

The numerals of the display unit 40 indicate the particle size of the dry ice D ground in accordance with the different intervals between the grinder 21 and the support 22 as the interval adjustment lever 312 is rotated in the forward or reverse direction.

The configuration and operation principle of the display unit 40 are common techniques, and therefore, detailed description thereof is omitted.

The dry cleaner 100 capable of controlling dry ice particles according to the present invention will be explained.

Fig. 7 is a perspective view showing a dry cleaner capable of controlling dry ice particles according to the present invention, fig. 8 is a perspective view showing first and second detaching portions of the dry cleaner capable of controlling dry ice particles according to the present invention, and fig. 9 is a perspective view showing operations of the first and second detaching portions of the dry cleaner capable of controlling dry ice particles according to the present invention.

The dry cleaner 100 capable of controlling dry ice particles according to the present invention may include: the aforementioned dry ice particle adjustment device 1, the blasting portion 120, and the control module 50 are described below, wherein the blasting portion 120 includes an air compressor that supplies compressed air to the catch tank 33c of the fixing member 33, and blows dry ice onto the object to be cleaned.

The injection unit 120 includes, in addition to the air compressor 110: a supply pipe 121 that penetrates the main body 10 and the moving plate 34, is fixed to the other end portion of the fixed member 33 at the collecting tank 33c, and receives and transfers the dry ice D in the collecting tank 33c when the air compressor 110 is operated; a jet body part 122 connected to the supply pipe 121 and formed therein with a passing hole through which the dry ice D supplied from the supply pipe 121 passes; a spray nozzle 123 provided with a connection pipe 1231 connected to the spray body part 122 so that dry ice D can be sprayed; first and second detachable portions 124 and 125, respectively, which allow the supply pipe 121 and the connection pipe 1231 to be coupled to or separated from the injection main body 122.

First, the air compressor 110 supplies compressed air which becomes the initial power when the dry ice D is sprayed, and includes an air pipe 111 which penetrates the main body 10 and the moving plate 34 and is fixed to one side end portion of the catch tank 33c of the fixed member 33, and supplies the compressed air to the catch tank 33c, thereby spraying the ground dry ice D to the object to be cleaned through the spray nozzle 123.

Here, the injection body part 122 is provided with an on/off switch S for controlling the operation of the air compressor 110.

In other words, if the on/off switch is pressed once, the air compressor 110 continues to operate, so that the dry ice D in the collecting tank 33c can be continuously sprayed, and if the on/off switch is pressed again, the operation of the air compressor 110 is stopped, which can reduce the fatigue of the operator and provide convenience in use.

The first and second detaching portions 124 and 125 are used to couple or separate the supply pipe 121 and the connection pipe 1231 to or from the injection part body 122 in one touch (one touch) type, and may include: main bodies 1341 and 1251 fixed to the inlet side and the outlet side of the passage hole of the injection main body 122, respectively, formed in a cylindrical shape, the inside of which is connected to the passage hole of the injection main body 122, and having a plurality of pressure balls 1242 and 1252 formed at the inner periphery thereof so as to be spaced apart from each other; drawing portions 1243,1253 which are fixed to end portions of the supply pipe 121 and the connection pipe 1231, respectively, are formed in a cylindrical shape, are connected to the through hole of the injection body portion 122 inside, are attached to the inside of the body portions 1341, 1251, and are pressurized against the pressurizing balls 1242, 1252 from the outside thereof; the operation portions 1244 and 1254 are attached to the outer surfaces of the main bodies 1341 and 1251, respectively, and can move forward and backward with respect to the jet body portion 122.

The pressure balls 1242 and 1252 are inserted into the body portions 1341 and 1251, are movable toward the inner space or outside of the body portions 1341 and 1251, are elastically supported by a spring (not shown), and are controlled to be operated by the forward and backward movement of the operation portions 1244 and 1254.

Further, the operation portions 1244, 1254 are elastically supported by a spring (not shown), so as to automatically advance and return to the original position when artificially retreated.

In other words, after the operating portions 1244 and 1254 are grasped and the pressure balls 1242 and 1252 are retracted and disengaged, the introduction portions 1243 and 1253 are inserted into the main body portions 1341 and 1251, and then if the operating portions 1244 and 1254 are loosened to return to their original positions, the pressure balls 1242 and 1252 press the outer surfaces of the introduction portions 1243 and 1253 to be fixed, and the supply pipe 121 and the connection pipe 1231 can be easily coupled to and separated from the injection main body portion 122 in one touch by the first and second detachable portions 124 and 125. Accordingly, when abnormality or deterioration occurs in the supply pipe 121 and the connection pipe 1231, replacement with a new product can be easily and quickly performed.

In this case, the first and second additional detachable portions 15 and 16 having the same structure as the first and second detachable portions 124 and 125 may be provided outside the main body portion 10.

At this time, the lower side of the supply pipe 121 is fixed by the first additional disassembly part 15, and one side of the air pipe 111 is fixed by the second additional disassembly part 16.

Also, a fixing pipe (not shown) fixed to the collecting groove 33c instead of the supply pipe 121 and the air pipe 111 may be provided at the first additional dissembling portion 15 and the second additional disassembling portion 16.

Accordingly, the compressed air of the air compressor 110 is supplied to the collecting tank 33c through the air pipe 111, the second additional disassembly part 16, the fixed pipe, whereby the dry ice D is supplied to the spray nozzle 123 through the fixed pipe of the first additional disassembly part 15, the supply pipe 121, the spray body part 122, the connection pipe 1231.

The control module 50 operates the air compressor 110 for a set period of time as the start signal is input from the injection part as the on/off switch S is pressed by the operator, thereby discharging the foreign substances and moisture existing in the collection tank 33c through the injection nozzle 123.

Then, the control module 50 operates the motor for rotating the grinder 21, and if the dry ice D is immediately put into the storage space 10a of the main body 10, only the clean compressed air and the dry ice are sprayed to the object to be washed.

Further, as the operator presses the on/off switch S again, the control module 50 stops the operation of the motor when the injection part 30 inputs the termination signal, so that the air compressor 110 is operated for a set time period, thereby discharging the foreign substances and moisture existing in the collection tank 33c through the injection nozzle 123.

Next, the forming part 130 applied to the dry cleaner 100 capable of controlling dry ice particles according to the present invention will be described with reference to fig. 10 to 12.

Fig. 10 is a sectional view showing an upper mold, a lower mold, and a lifting driving part applied to a dry cleaner capable of controlling dry ice particles according to the present invention, and fig. 11 and 12 are views showing operation states of a turning plate, a turning guide shaft, and a turning driving part applied to the dry cleaner capable of controlling dry ice particles according to the present invention.

The forming part 130 may include an upper mold 131, a lower mold 132, a lifting driving part 133, a rotation plate 134, a rotation guide shaft 135, and a rotation driving part 136, in which a plurality of peak parts D1 and valley parts D2 are formed on an edge surface of the dry ice D to intersect with each other.

In this case, in the present embodiment, the dry ice D formed by the forming portion 130 is not ground by the grinder 21 and the support portion 22, but is directly collected by the collecting groove 33c and then sprayed to the object to be cleaned by the spraying portion 120.

In other words, the present embodiment is configured to selectively use either the dry ice D whose particle diameter is adjusted by the grinder 21 and the support portion 22 or the dry ice D formed by the forming portion 130.

Specifically, the first storage groove 131a is formed in a semicircular shape having an open top surface along the longitudinal direction of the upper mold 131, and is formed at a constant interval to store the lower portion of the dry ice D, and the dry ice D is pressurized in the first storage groove 131a such that the plurality of first pressurizing protrusions 1311 formed by the peak portions D1 and the trough portions D2 are formed at a constant interval.

The lower mold 132 is disposed above the upper mold 131, the second receiving groove 132a is formed in a semicircular shape having an open bottom along the longitudinal direction thereof to face the first receiving groove 131a, receives the upper portion of the dry ice D received in the first receiving groove 131a and is formed at a constant interval, and the second receiving groove 132a is formed with a plurality of second pressing projections 1321 formed at a constant interval by pressing the dry ice D so that the mountain portions D1 and the trough portions D2 are formed.

At this time, the first and second pressing protrusions 1311 and 1321 may be formed in a semicircular shape or a quadrangular shape such that the mountain portion D1 is formed in a curved or quadrangular shape, and an example of forming in a semicircular shape is shown in the drawings.

The elevation driving part 133 may be provided as a hydraulic cylinder such that the lower mold 132 is lowered so that the first and second pressurizing protrusions 1311 and 1321 pressurize the dry ice D.

At this time, the elevation driving unit 133 is lowered so that the upper mold 131 is in close contact with or close to the lower mold 132.

In other words, in the dry ice D, the portions pressurized by the first and second pressurizing protrusions 1311 and 1321 are formed with the notched ridge portions D1, and the portions not pressurized by the first and second pressurizing protrusions 1311 and 1321 are formed with the ridge portions D1.

After the formation of the dry ice D, the upper mold 131 is raised by the elevation driving unit 133 to take out the dry ice D stored in the first storage groove 131a, and then moved to the turning plate 134.

The turning plate 134 is opposed to the main body 10 and is located at a position higher than the inlet, and the formed dry ice D is placed thereon.

The vertical rotation guide shaft 135 is axially fixed to a bottom surface of the rotation plate 134, and the rotation plate 134 is rotatable in a vertical direction.

The rotation driving part 136 may be formed as a hydraulic cylinder, and a piston is fixed to the other side of the bottom surface of the rotation plate 134 so that the rotation plate 134 can be rotated in the up and down directions.

In other words, if hydraulic pressure is injected into the rotation driving part 136, the piston is raised, and thereby the rotation plate 134 is rotated in the up and down direction, so that the dry ice D placed thereon is automatically thrown into the inner space of the body part 10.

At this time, the grinder 21 and the support portion 22 are disposed at a distance greater than the particle size of the dry ice D formed by the forming portion 130, and the formed dry ice D directly falls to the collection tank 33c without contacting the grinder 21 and the support portion 22, and then is sprayed to the object to be cleaned in the above-described manner, thereby removing the foreign substance layer.

In particular, when a plurality of grooves smaller than the dry ice D are formed by applying impact to the object to be cleaned, the dry ice D may not contact the foreign substance layer stored in the groove, and thus the foreign substance layer may not be removed, but the dry ice cleaning machine 1 according to the present invention intensively sprays the formed dry ice D to the groove portion of the object to be cleaned, thereby removing the foreign substance layer.

In other words, if the dry ice D formed is sprayed to the groove of the object to be cleaned, the mountain portion D1 of the dry ice D is drawn into the groove of the object to be cleaned and comes into contact with the foreign substance layer stored on the surface of the groove.

Therefore, when the groove is formed in the object to be cleaned, first, unformed dry ice D is put into the main body 10, and the foreign matter layer hidden in the portion where the groove is not formed is removed, and then, the formed dry ice D is put into the main body 10 and is intensively sprayed to the groove portion of the object to be cleaned, thereby perfectly cleaning the entire object to be cleaned.

Of course, when the object to be cleaned has no groove, the object to be cleaned may be cleaned only by using the dry ice D formed by the grinder 21 and the grinding portion 20.

It is to be understood that a person having ordinary skill in the art to which the present invention pertains may adopt other specific forms without changing the technical spirit or essential features of the present invention. Therefore, the above-described embodiments are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the scope of the claims to be described later than the detailed description above, and all modifications and variations derived from the meaning and scope of the claims and equivalent concepts thereof should be construed as being included in the scope of the present invention.

Claims (8)

1. A dry ice particle conditioning device comprising:

a body part, wherein an inlet for inputting dry ice is formed at the upper side of the body part, and a discharge port for discharging the dry ice is formed at the lower side of the body part;

a grinding part including a grinder disposed in the inner space of the body part and grinding dry ice, and a support part disposed opposite to the grinder and supporting the dry ice;

an adjusting part which enables the supporting part to move forwards or backwards relative to the grinding machine in order to adjust the grinding range of the dry ice;

the adjustment part includes:

a rotating shaft eccentrically fixed to the support portion;

a rotation control member including a rotation handle disposed outside the main body and a spacing adjustment lever coupled to the rotation handle and rotating the rotation shaft in the same direction while rotating in a forward direction or a reverse direction to adjust a spacing between the support portion and the grinding machine;

a fixing member facing the grinding machine, having an inlet groove for the support part to enter and exit in a height direction, having an inclined surface for allowing dry ice to fall thereon, and having a collecting groove for collecting the dry ice falling between the grinding machine and the support part on a bottom surface;

and a protective member disposed opposite to the fixing member to protect the grinder.

2. A dry ice particle regulating device according to claim 1,

the support part is formed as a polygonal body so as to make the dry ice generate surface friction.

3. A dry ice particle adjustment device according to claim 1, further comprising:

and a display part which is arranged on the outer surface of the main body part, operates in linkage when the interval adjusting rod rotates, and indicates the particle diameter of the ground dry ice by using a numeral.

4. A dry cleaner capable of controlling dry ice particles, comprising:

a dry ice particle regulating device according to any one of claims 1, 2 and 3, which regulates a particle size of dry ice;

and a spraying part provided in the body part and spraying dry ice collected in the collecting tank of the fixing member to the outside.

5. The dry cleaner of controllable dry ice particles of claim 4, the blast portion comprising:

an air compressor which supplies compressed air to the internal space of the body part to discharge the ground dry ice;

a supply pipe connected to the main body and configured to transfer dry ice discharged by an air compressor;

a jet body part connected to the supply pipe and receiving the supplied dry ice;

a spray nozzle connected to the spray body part and spraying dry ice;

first and second detachable parts which make the supply pipe and the injection nozzle combined with or separated from the injection body part respectively.

6. A dry cleaner for controlling dry ice particles as claimed in claim 5,

an on/off switch for controlling the operation of the air supply part is also formed at the injection main body part.

7. A dry cleaner for controlling dry ice particles as claimed in claim 6,

also comprises a control module for controlling the grinder and the air compressor,

and the control module enables the air compressor to operate firstly in a set time period when the injection part inputs a start signal so as to discharge the foreign matters and the moisture in the collecting tank through the injection nozzle, and enables the air compressor to operate in the set time period when the injection part inputs an end signal so as to discharge the foreign matters and the moisture in the collecting tank through the injection nozzle.

8. The dry cleaner of controllable dry ice particles of claim 4, further comprising:

a forming part that forms a plurality of mountain parts and valley parts intersecting each other on an outer surface of the dry ice,

the forming section includes:

an upper mold in which first receiving grooves for receiving lower portions of dry ice are formed at regular intervals in a longitudinal direction, wherein a plurality of first pressing projections are formed in the first receiving grooves so as to be spaced apart from each other, the first pressing projections being formed by pressing dry ice so that mountain portions and valley portions are formed;

a lower mold disposed above the upper mold, wherein an upper portion of the dry ice received in a first receiving groove is received in a second receiving groove formed at a predetermined interval in a longitudinal direction, and a plurality of second pressing projections formed in the second receiving groove by pressing the dry ice so that a peak portion and a trough portion are formed to be spaced apart from each other;

a lifting driving part which enables the lower die to descend so that the first pressurizing protrusion and the second pressurizing protrusion pressurize the dry ice;

a rotation plate which is opposite to the main body and is used for placing the formed dry ice on the rotation plate;

a vertical rotation guide shaft, the shaft of which is fixed on one side of the bottom surface of the rotation plate;

and a rotation driving part which enables the rotation plate to rotate along the upper direction so as to throw the dry ice of the rotation plate into the body part.

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