KR102062520B1 - Dry ice cleaning machine - Google Patents

Abstract

The present invention relates to a dry ice cleaning machine. The dry ice cleaning machine of the present invention allows dry ice particles for cleaning to pass through a feeding screw unit, a blowing unit and a centrifugal propulsion unit step by step and to be dispersed uniformly and continuously without aggregation, thereby aiming at improved cleaning efficiency. To this end, the dry ice cleaning machine of the present invention comprises: a cleaning machine body (10); a feeding screw unit (20); a blowing unit (30); and a centrifugal propulsion unit (40).

Description

Dry ice cleaning machine

The present invention relates to a dry ice cleaner, and more particularly, the cleaning dry ice particles are continuously and uniformly dispersed and moved without aggregation between the particles while passing through the feeding screw unit, the blowing unit, and the centrifugal propulsion unit to improve the cleaning efficiency. It relates to a dry ice washer to plan.

In general, the dry ice cleaner is a high speed spray of hard dry ice particles harmless to industrial facilities and the environment to remove foreign matters. Since the amount and speed of dry ice sprayed can be controlled to some extent, the machine is made of various materials such as ceramics, synthetic resins, rare metals, fiberglass, rubber, plastics, steel, and electronic parts, die casting mold cleaning, reactor internal cleaning, tires It can remove foreign substances attached to the surface of various products such as mold cleaning.

The dry ice particles sublimate into harmless gases upon impact on the surface, removing only foreign substances and leaving no secondary contaminants or moisture without damaging the cleaning surface. Therefore, food processing, confectionery, rubber, plastics, pharmaceuticals, Widely used in all industrial fields such as automobile manufacturing, aircraft maintenance, aerospace, electric and electronics, semiconductor industry, petrochemical, steelmaking, printing, casting industry, etc., demand for high performance dry ice cleaner is increasing as demand is steadily increasing. to be.

Accordingly, in Patent Publication No. 10-2019-0093336 disclosed in the prior art, in a dry ice washing machine for spraying dry ice pellets at high speed to clean the surface of equipment, molds, etc., a pneumatic generator using conventional mechanical power such as a motor Instead, amplify and accelerate a small amount of compressed air using the Coanda effect, and transfer and spray dry ice pellets using the compressed and amplified compressed air to generate pneumatic pressure using mechanical power such as a motor. Dry ice washer without device can be configured to reduce the size, weight and construction cost of the dry ice washer, has improved the mobility to effectively use the dry ice washer in the industrial field has been announced.

However, the above conventional technology is a technique for spraying dry ice pellets at high speed using an air booster using a Coanda effect without a pneumatic generator using a mechanical power such as a motor, or the like, since dry ice pellets are supplied intermittently. It is difficult to evenly clean the surface of the object to be cleaned because it is a supply cleaning method in which some parts of the water are properly cleaned and some parts are not properly cleaned and the cleaning dry ice is supplied and then cut off. There was a point and the cleaning efficiency was also poor.

KR 10-2019-0093336 B1 (2019.08.09.)

Accordingly, the present invention has been conceived to solve the above problems, the cleaning dry ice particles are passed through the feeding screw unit, blowing unit and centrifugal propulsion unit step by step uniformly and continuously dispersed dispersing between the particles, cleaning efficiency Its purpose is to provide a dry ice cleaner for improvement.

According to an aspect of the present invention, in a dry ice scrubber that is uniformly and continuously dispersed and moved without aggregation between particles to improve cleaning efficiency, the dry ice scrubber includes a storage hopper 12 for filling dry ice particles therein. A scrubber body 10 provided with a cleaning gun 14 for spraying dry ice particles to the outside; and a screw sleeve 22 communicating with the storage hopper 12 inside the scrubber body 10. A feeding screw unit 20 including a screw 24 rotatably installed therein to propel dry ice particles filled in the storage hopper 12 into the supply path 22a formed in the screw sleeve 22. And blowing dry air particles propelled from the feeding screw unit 20 into the supply path 22a by compressed air. The blowing unit 30 is provided with a device to distribute the particles transfer with mixing with the compressed air; And a centrifugal propulsion unit 40 for applying the centrifugal thrust force to be discharged by advancing in the direction of the cleaning gun 14 while mixing the dry ice particles dispersed and supplied from the blowing unit 30 with compressed air.

According to the above configuration and operation, the present invention allows the cleaning dry ice particles to be uniformly dispersed and continuously moved without aggregation between the particles while passing through the feeding screw unit, the blowing unit and the centrifugal propulsion unit in a stepwise manner, There is a significant effect in ensuring a uniform, clean and complete cleaning of the workpiece.

1 is a block diagram showing a dry ice cleaner as a whole according to an embodiment of the present invention.
2 is a block diagram showing a feeding screw unit of a dry ice cleaner according to an embodiment of the present invention.
Figure 3 is a block diagram showing a feeding screw unit of a dry ice cleaner according to another embodiment of the present invention.
Figure 4 is a block diagram showing a blowing unit of a dry ice cleaner according to an embodiment of the present invention.
Figure 5 is a block diagram showing a centrifugal propulsion unit of a dry ice cleaner according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

The present invention relates to a dry ice cleaner, in which the dry ice particles for cleaning are continuously and uniformly dispersed and dispersed without aggregation between the particles while passing through the feeding screw unit, the blowing unit and the centrifugal propulsion unit in order to improve the cleaning efficiency. It consists of a main configuration including the cleaner body 10, the feeding screw unit 20, the blowing unit 30, the centrifugal propulsion unit 40.

The cleaner body 10 according to the present invention has a storage hopper 12 for filling dry ice particles therein, and a cleaning gun 14 for spraying dry ice particles on the outside. As shown in FIG. 1, the dry ice cleaner according to the present invention feeds the dry ice cleaning particles to the cleaner body 10 having the storage hopper 12 filling the dry ice therein through the cleaning gun 14. Unit 20, blowing unit 30, centrifugal propulsion unit 40 is provided.

Here, the cleaner body 10 is formed in a box shape having a space portion therein, the upper end of the cleaner body 10 is formed with an opening opening and closing by the door. The upper end of the cleaner body 10 is provided with a door that one side is rotated to open and close through the hinge portion, the opening that is in communication with the upper end of the cleaner body 10 is opened and closed as the door is opened and closed.

In addition, a storage hopper 12 is provided inside the cleaner body 10, and the interior of the storage hopper 12 communicates with an inlet of the cleaner body 10. As the door is opened and closed, the upper portion of the storage hopper 12 is opened and closed. The storage hopper 12 is filled with dry ice particles (pellets). The inside of the storage hopper 12 (inside the bottom side) is provided with a dry ice filling support panel, the dry ice filling support panel is formed with a dry ice outlet hole at regular intervals along the circumferential direction with respect to the center, the dry ice Dry ice cleaning particles are supplied to the feeding screw unit 20 to be described later through each outlet hole of the filling support panel.

In addition, the feeding screw unit 20 according to the present invention is rotatably installed in the screw sleeve 22 communicated with the storage hopper 12 in the cleaner body 10 is filled in the storage hopper 12 And a screw 24 for propelling the dried ice particles into the supply path 22a formed in the screw sleeve 22. The screw sleeve 22 is disposed in the horizontal direction orthogonal to the discharge portion of the lower end of the storage hopper 12 which is installed in the washing machine body 10 in an upright direction, and the discharge portion of the storage hopper 12 and its The interior is in communication.

The screw 24 is rotatably embedded in the screw sleeve 22, and a motor is installed at the proximal end of the screw 24. The discharge portion of the storage hopper 12 communicates with the upper circumference of the end side adjacent to the motor of the screw sleeve 22 so that the dry ice cleaning particles filled in the storage hopper 12 enter the screw sleeve 22. As the screw 24 rotates, dry ice cleaning particles are advanced to the tip end side of the screw sleeve 22. At this time, the feeding end is provided in the vertical direction on the lower peripheral portion of the front end side of the screw sleeve 22 and is connected to the blowing unit 30 to be described later.

In FIG. 2, the screw sleeve 22 includes a pair of fixed sleeves 22-1, a rotating sleeve 22-2 in which both ends are rotatably supported by the fixed sleeve 22-1, and rotated. It consists of the drive part 22-3 which rotates the sleeve 22-2. As such, the dry ice particles are rotated by the rotary sleeve 22-2 while the screws 24 are linearly moved on the inner circumferential surface of the screw sleeve 22 by the rotational force. There is an advantage in that it is separated and distributed independently.

At this time, the uneven portion 22-2a is formed on the inner circumferential surface of the rotary sleeve 22-2. The uneven portion 22-2a is provided to independently separate the dry ice particles by the rotational movement in the opposite direction with the screw 24.

In FIG. 3, a plurality of through holes 50 are formed in the rotary sleeve 22-2 and inserted into the through holes 50 to move outwardly of the rotary sleeve 22-2 by the elastic body 51 a. This action, the mill pin 51 is provided at the end of the cam roller 51b is provided, and is installed in any one section corresponding to the rotational movement path of the mill pin 51, the mill pin (sliding motion with the cam roller 51b) The cam rail 52 which presses 51 to the inner side of the rotating sleeve 22-2 is provided.

Accordingly, when the mill pin 51 moves in the outer direction of the rotary sleeve 22-2, the through hole 50 is formed as a recessed groove in the inner direction of the rotary sleeve 22-2, so that the dry ice particles are accommodated. Dry ice particles are pulverized by mutually reverse rotational motion with), and the cam pin 52 moves through the inside of the rotary sleeve 22-2 when the mill pin 51 is moved inwardly of the rotary sleeve 22-2. Dry ice particles accommodated in 50 are provided to be removed. As such, the dry ice particles caught in the through hole 50 are removed while the rotary sleeve 22-2 is rotated, thereby improving dry ice particle separation and grinding efficiency by the through hole 50.

In addition, the blowing unit 30 according to the present invention blows dry ice particles propelled from the feeding screw unit 20 to the supply path 22a with compressed air so that the dry ice particles are dispersed and conveyed while mixing the dry ice particles with the compressed air. It is provided.

In FIG. 4, the blowing unit 30 includes a blowing pipe 32 provided to move dry ice particles moved by the feeding screw unit 20 in a direction opposite to the feeding direction of the feeding screw unit 20, and a blowing unit. An air nozzle (34) installed at the inlet side of the pipe (32) for injecting compressed air to the outlet side, and a flow path (36a) is formed to supply compressed air to the air nozzle (34) side, and is installed and compressed in the flow path (36a). It is installed on the wave generator 36 made of a vane 36b that repeatedly opens and closes the flow path 36a while being rotated by air movement force, and is rotated on the vane 36b of the wave generator 36 to rotate during rotation. It consists of an eccentric weight 38 to generate.

Compressed air passing through the flow path 36a passes through the vane 36b to supply the air nozzle 34 to the air nozzle 34. At this time, the vane 36b is rotated to repeatedly open and close the flow path 36a. Since the air is outputted as strong, weak, strong, or weak, dry ice dispersion efficiency is improved, and in particular, the eccentric weight 38 installed on the rotor shaft 36b rotating shaft generates vibrations during rotation, so that the dry ice particles are blown into the blowing tube 32. Sticking to the inner circumference is prevented.

In addition, the centrifugal propulsion unit 40 according to the present invention is provided to apply the centrifugal propulsion force to be discharged by advancing in the direction of the cleaning gun 14 while mixing the dry ice particles distributed from the blowing unit 30 with compressed air. do.

In FIG. 5, the centrifugal propulsion unit 40 includes a mixing propulsion chamber 42 including a propulsion nozzle 42a for mixing and spraying dry ice particles moved by the blowing unit 30 together with compressed air. It is rotatably connected to the propulsion chamber 42, the diameter is expanded toward the dry ice conveying direction to form a conical tube 44 for dispersing and transporting dry ice particles by centrifugal force, and the drive unit 45 for rotating the conical tube 44 And a propulsion tube 46 connected to the outlet of the conical tube 44 to transfer dry ice particles mixed with compressed air while being dispersed by centrifugal force.

Here, the dry ice particles moved into the centrifugal propulsion unit 40 are moved in all directions in a large diameter in a state in which the dry ice particles are evenly adhered to the inner circumferential surface of the conical tube 44 by the centrifugal force in the conical tube 44. The propulsion nozzle 42a extends to the end of the conical tube 44 to mix and spray dry ice particles and compressed air.

 In addition, since the dry ice particles are moved by the conical tube 44, the mixing efficiency with the compressed air injected through the propulsion nozzle 42a is improved.

The terms "comprise", "comprise" or "have" described above mean that the corresponding component may be included unless specifically stated otherwise, and thus, other components are not excluded. It should be construed that it may further include other components. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Terms used generally, such as terms defined in a dictionary, should be interpreted to coincide with the contextual meaning of the related art, and shall not be interpreted in an ideal or excessively formal sense unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Therefore, since the embodiments described above are provided to completely inform the scope of the invention to those skilled in the art, it should be understood that they are exemplary in all respects and not limited. The invention is only defined by the scope of the claims.

In other words, while the technical idea of the dry ice cleaner of the present invention has been described with the accompanying drawings, it is intended that the best embodiments of the present invention will be described by way of example and not limitation of the present invention. It should be understood that any person having the present invention may have various modifications and imitations without departing from the scope of the technical idea of the present invention.

10: cleaner body 20: feeding screw unit
30: blowing unit 40: centrifugal propulsion unit

Claims (1)

In the dry ice cleaner, which disperses and moves uniformly and continuously without agglomeration between particles, to improve cleaning efficiency.
The dry ice cleaner is provided with a storage hopper 12 for filling dry ice particles therein, and a cleaner body 10 having a cleaning gun 14 for spraying dry ice particles on the outside thereof;
Rotatably installed in the screw sleeve 22 communicated with the storage hopper 12 in the cleaner body 10 to form dry ice particles filled in the storage hopper 12 in the screw sleeve 22. A feeding screw unit 20 including a screw 24 for pushing to be supplied to the supply path 22a; and
A blowing unit (30) provided to blow dry dry ice particles propelled from the feeding screw unit (20) to the supply path (22a) with compressed air to mix and disperse dry ice particles with compressed air; And
And a centrifugal propulsion unit 40 for applying the centrifugal thrust force for advancing and discharging the dry ice particles dispersed and supplied from the blowing unit 30 in the direction of the cleaning gun 14 while mixing with compressed air.
The screw sleeve 22 includes a pair of fixed sleeves 22-1, a rotating sleeve 22-2 at which both ends are rotatably supported by the fixed sleeve 22-1, and the rotating sleeve ( 22-2) is configured to include a drive unit 22-3,
The moving force is applied to the plurality of through holes 50 formed in the rotary sleeve 22-2 by the elastic body 51a in the outward direction of the rotary sleeve 22-2, and the cam roller 51b is applied to the end thereof. Milpin 51 is provided,
Cam rail 52 is installed in any one section corresponding to the rotational movement path of the mill pin 51 to press the mill pin 51 in the direction of the inner side of the rotary sleeve 22-2 by sliding the cam roller 51b. Is equipped,
When the mill pin 51 moves in an outward direction of the rotating sleeve 22-2, a through hole 50 is formed as an intaglio groove in the inward direction of the rotating sleeve 22-2 so that dry ice particles are accommodated in the screw 24. Dry ice particles are pulverized by mutually reverse rotational motion with each other, and the cam pin 52 moves through the inside of the rotating sleeve 22-2 when the mill pin 51 moves inwardly of the rotating sleeve 22-2. 50 is provided to remove the dry ice particles contained in,
The centrifugal propulsion unit 40 includes a mixing propulsion chamber 42 and a mixing propulsion chamber 42 including a propulsion nozzle 42a for mixing and spraying dry ice particles moved by the blowing unit 30 together with compressed air. Rotatably connected to the conical tube, the diameter of which extends toward the dry ice conveying direction, the conical tube 44 dispersing and transporting the dry ice particles by centrifugal force, the driving unit 45 rotating the conical tube 44, and the conical It is connected to the outlet of the pipe 44 is made of a propulsion pipe 46 for transporting dry ice particles mixed with compressed air while being dispersed by centrifugal force,
The uneven portion 22-2a is formed on the inner circumferential surface of the rotary sleeve 22-2,
The blowing unit 30, the blowing pipe 32 is provided to move the dry ice particles moved by the feeding screw unit 20 in the opposite direction to the feeding direction of the feeding screw unit 20, and the blowing pipe 32 Dry ice scrubber, characterized in that it comprises an air nozzle (34) installed on the inlet side for injecting compressed air to the outlet side.

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