KR20200036547A - Apparatus for cleaning dust on fin filter - Google Patents

Abstract

The present invention relates to an apparatus for cleaning dust on a fin filter which allows the fin filter for filtering fine metal powder to be reused by easily and rapidly cleaning and removing dust on the fin filter without physical damage such as pore destruction in order to prevent fine metal powder, unreacted substances generated during a chemical vacuum process such as chemical vapor deposition (CVD), from being introduced to a vacuum pump. The present invention may provide the apparatus for cleaning dust on the fin filter including: a filter mounting part which has a cylindrical shape with an openable/closable lid, removes dust stuck on the fin filter by inserting the fin filter to which dust is coagulated, closing and fixing the lid to rotate the fin filter and spraying compressed air, removes coagulated dust by pounding the fin filter with a punch performing a linear motion, and sucks and removes dust isolated from the fin filter; a control part to control an operation of the filter mounting part; and an air mass part to mount the filter mounting part and the control part at an upper portion thereof. Accordingly, it is possible to clean and remove dust coagulated on the filter without physical damage such as tearing of the fin filter or pore destruction, and to prevent the dust from spreading in all directions during the removing procedure.

Description

Apparatus for cleaning dust on fin filter}

The present invention relates to an apparatus for removing dust from a filter, and in particular, a fine for preventing the inflow of a vacuum pump of fine metal powder, which is an unreacted material generated in a chemical vacuum process such as a chemical vapor deposition (CVD) process. It relates to a dust removing device of a wing-type porous filter that enables the filter to be reused by removing the dust caught in the filter easily and quickly without physical damage such as pore destruction of the metal-type filter for the filter.

The CVD method is a method of forming a thin film on a substrate in a gas phase reaction by supplying external energy while supplying the raw material gas to the substrate to be coated, and the gaseous raw material gas in a reactor blocked from the outside through a solid state through heterogeneous chemical reaction Since it is deposited as a low vacuum of about several mTorr to several tens of Torr, a vacuum pump is essentially used.

CVD equipment is mainly used for the formation of thin film layers of several tens of nm for the purpose of depositing thin films in the semiconductor field. At this time, there is less problem of dust caused by unreacted materials, but hundreds for the deposition of thick-film (several mm) materials such as ZnS. In the case of time growth, a filter for dust manure must be used in CVD equipment.

In particular, the growth of bulk materials using a CVD method usually proceeds with a chemical reaction for a long time at a high temperature. At this time, unreacted gas that has not reacted in the reactor is discharged to the exhaust. In this process, unreacted gas solidifies into a fine powder and flows into the vacuum pump in the exhaust section where the temperature is relatively low and the space is rapidly narrowed. In this case, the life of the vacuum pump is significantly reduced and the ideal reaction atmosphere cannot be induced. And the desired result cannot be obtained. Therefore, a porous filter is used to filter the fine powder flowing into the vacuum pump, and in particular, a wing-type porous filter (Fin Filter) as shown in FIG. 1A is mainly used to widen the surface area.

The wing-type porous filter has pores of several to several tens of um, and is folded in the shape of a wing, and is composed of a cloth material, so there are many restrictions to remove dust without physical impact, and since it is used in a vacuum atmosphere, it is cleaned with distilled water or chemicals. There are also many restrictions.

Therefore, although the wing-type porous filter was expensive and was disposed of after being used for one-time disposal, it could only lead to a weakening of the cost competitiveness due to purchase of consumable products, so there is a way to improve the cost competitiveness by recycling the wing-type porous filter. Is required.

The conventional method of cleaning the vane-type porous filter is a method of directly blowing out large particles by hand and blowing using an air gun, as shown in FIG. 1B. In this case, the fine powder embedded in the pores of the filter is not easily removed, so the efficiency of the filter is very low when reused, and dust is blown away during the removal of the fine powder to contaminate the surrounding environment. In addition, there is a problem in that manpower loss occurs because an operator has to work directly with an air gun.

KR 20-0258515 Y1 (2001.12.11.) KR 10-1377268 B1 (2014.03.17.) KR 10-1819336 B1 (2018.01.10.) KR 10-2017-0022542 A (2017.03.02.)

Accordingly, the present inventor puts emphasis on solving the limitations and problems of the conventional method of cleaning the wing-type porous filter by comprehensively taking into account the above-mentioned matters, and air blowing and physical force of the fine powder embedded in the pores of the filter. As a result of continuous research, efforts have been made to develop a dust removal device with a new structure that can be efficiently removed and not pollute the surrounding environment upon removal, but also can be implemented in an automated manner to reduce manpower loss. The present invention was created.

Therefore, the technical problem and object to be solved by the present invention is to remove the dust stuck in the pores of the filter by using air blowing and physical force, and the wing-type porous filter that can prevent dust from spreading in all directions during the removal process It is to provide a dust removal device.

In addition, another technical problem and object to be solved by the present invention is to remove the dust of the wing-type porous filter, it is possible to cleanly remove the dust adhered to the filter without physical damage such as tearing or destruction of the pore-type porous filter. It is to provide a dust removal device of the wing-type porous filter.

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

The dust removal device of the wing-type porous filter according to the present invention for achieving the above object is a cylindrical shape having a lid that can be opened and closed, after inserting the wing-shaped porous filter with dust adhered therein and closing and fixing the lid, By rotating the wing-type porous filter and spraying compressed air, the dust in the pores of the wing-type porous filter is separated, and by tapping the wing-shaped porous filter with a linearly moving punch, the deposited dust is separated, and the wing-shaped A filter mounting portion for sucking and removing dust separated from the porous filter; A control unit for controlling the operation of the filter mounting unit; And a base end portion for mounting the filter mounting portion and the control unit on the upper portion, so that the filter mounting portion is fitted to the hollow portion of the wing-type porous filter on a disc in close contact with the bottom of the wing-type porous filter at the bottom of the inside. It has a lower fixing portion formed with a circular protrusion, and fixes the wing-type porous filter inserted into the lower fixing portion, rotates the lower fixing portion by a motor, and inserts and fixed to the lower fixing portion. A rotary drive unit for rotating the porous filter at a constant speed, and is vertically fixed to the inside of the filter mounting unit through the central portion of the lower fixing part of the rotary drive unit, and has a central axis to prevent conduction when the wing-type porous filter rotates. The compressed air supplied from the outside through a shaft to be formed and a plurality of nozzles mounted on the outer circumferential surface of the shaft And an air blower to spray dust from the inside of the wing-type porous filter to the outside to remove dust stuck in the pores, and a reciprocation of the pneumatic cylinder using a punch mounted at the end of the drive shaft of the pneumatic cylinder passing through the side of the filter mounting part. When exercising, the punch module for tapping the outside of the wing-type porous filter and the intake hole formed by penetrating one side of the inner bottom surface of the filter mounting portion is connected to one end and the other end is connected to an external dust collector It is composed of, it characterized in that it comprises a dust collecting port to inhale the dust separated from the wing-type porous filter and discharged to the outside.

In addition, in the dust removal device of the wing-type porous filter according to the present invention, the filter mounting portion is formed to protrude circularly on the bottom surface of the lid so as to fit into the hollow portion of the wing-shaped porous filter when the lid is closed, and the wing to be inserted It characterized in that it further comprises an upper fixing portion for fixing the top of the type porous filter.

In addition, in the dust removing device of the vane-type porous filter according to the present invention, the control unit drives the motor of the rotary drive unit to rotate the vane-type porous filter and stop the motor to stop rotation of the vane-type porous filter. And, by driving the pneumatic cylinder of the punch module is characterized in that to stop the blow of the wing-type porous filter by hitting the outside of the wing-type porous filter and stop the pneumatic cylinder when the wing-type porous filter rotates. .

In addition, in the dust removal device of the vane-type porous filter according to the present invention, the control unit changes the driving cycle of the pneumatic cylinder according to the rotational speed of the vane-type porous filter, so that when the vane-type porous filter rotates, It is characterized in that the external hitting portion of the wing-type porous filter is changed.

In addition, in the dust removal device of the vane-type porous filter according to the present invention, the control unit drives an external compressed air supply device to inject compressed air into the vane-type porous filter and stops the compressed air supply device. It is characterized in that the injection of compressed air is stopped, the external dust collector is driven to inhale dust separated from the wing-type porous filter, and the dust collector is stopped to stop inhalation of dust.

In addition, in the dust removal device of the wing-type porous filter according to the present invention, the control unit detects that the wing-type porous filter is inserted and fixed by the filter mounting part by any one of the upper fixing part and the lower fixing part. If it is, it characterized in that it automatically drives the rotary drive, the air blower, the punch module and the dust collecting port.

As described above, the present invention can easily and quickly cleanly reuse the filter by removing dust stuck in the pores of the filter using air blowing and physical force.

In addition, the present invention can prevent environmental pollution by preventing dust from spreading in all directions during the dust removal process of the filter, and is very economical because a separate device for preventing environmental pollution is not required.

In addition, in the present invention, in removing the dust of the wing-type porous filter, since it is possible to cleanly remove dust adhering to the filter without physical damage such as tearing or destruction of the pore-type porous filter, production cost can be lowered and product competitiveness Can be increased.

In addition, since the present invention can automatically perform dust removal of the filter, it is possible to reduce the manpower required for dust removal of the filter, and accordingly, the economic effect is large.

1a and 1b is a photograph showing a wing-type porous filter and a conventional cleaning method,
Figure 2 is an embodiment of the dust removal device of the wing-type porous filter according to the present invention,
Figure 3 is a picture of the internal structure of the filter mounting portion of the dust removing device of the wing-type porous filter according to the present invention,
Figure 4 is a cross-sectional view of the filter mounting portion of Figure 3,
5 is a cross-sectional view of the punch module,
6A and 6B are photographs of the wing-type porous filter before and after dust removal.

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

Prior to this, terms to be described later are defined in consideration of the functions in the present invention, which clearly indicates that they should be interpreted in terms of concepts consistent with the technical spirit of the present invention and commonly recognized or commonly recognized in the art.

In addition, if it is determined that a detailed description of known functions or configurations related to the present invention may obscure the subject matter of the present invention, the detailed description will be omitted.

Here, the attached drawings are exaggerated or simplified for a convenience and clarity of description and understanding of the structure and operation of the technology, and it is revealed that each component does not exactly match the actual size and shape.

In addition, in the present specification, and / or the term means a combination of a plurality of related described items or any of the plurality of related listed items, and when a part includes a certain component, this is a particularly contrary description. It does not mean that other components are excluded as long as there is no other component.

That is, it means that a feature, number, step, operation, component, part, or combination thereof specified in the present specification exists, and one or more other features or number, step operation component, part, or combination thereof. It should be understood that it does not exclude the possibility of the existence or addition of things.

And terms such as top, bottom, top, bottom, or top, bottom, top, and bottom are used for convenience to distinguish the relative positions of each component. For example, the upper side of the drawing may be named and referred to as the upper side and the lower side as the lower side.

When an element is said to be "connected" or "connected" to another component, it is understood that other components may be directly connected to or connected to the other component, but other components may exist in the middle. Should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle.

In addition, the meaning of the term "unit" means a unit or module type that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software.

Figure 2 is an embodiment of the dust removing device of the wing-type porous filter according to the present invention, Figure 3 is a picture of the internal structure of the filter mounting portion of the dust removing device of the wing-type porous filter according to the present invention, Figure 4 is Figure 3 It is a cross-sectional view of the filter mounting portion, Figure 5 is a cross-sectional view of the punch module.

Hereinafter, with reference to FIGS. 2 to 4, the dust removing device of the wing-type porous filter according to the present invention will be described in detail. 2 to 4, the dust removal device of the wing-type porous filter according to the present invention is largely composed of a filter mounting portion 100, a control unit 200 and a base end portion 300.

The filter mounting portion 100 is a cylindrical shape having a lid that can be opened and closed, after inserting and fixing the wing-type porous filter 10 with dust adhered therein and closing the lid 101, the wing-type porous filter 10 is fixed. By rotating and spraying compressed air, the dust stuck in the pores of the wing-shaped porous filter 10 is separated from the filter, and the blade-shaped porous filter 10 is pounded with a linearly moving punch to separate the adhered dust from the filter, Remove the separated dust by suction.

The filter mounting part 100 is composed of an air blower 110, a punch module 120, a shaft 130, a rotation driving part 140 and a dust collecting port 150.

The rotary driving part 140 is provided with a lower fixing part 141 on which a circular protrusion is formed so as to fit into the hollow part of the wing-type porous filter 10 on a disc in close contact with the bottom surface of the wing-type porous filter 10. The wing-type porous filter 10 inserted into the top portion 141 is fixed, and the lower fixed portion 141 is rotated by a motor 143 to rotate the inserted and fixed wing-shaped porous filter 10 at a constant speed. Order. At this time, the motor 143 may be directly connected to the lower fixing portion 141 and rotated, or the lower fixing portion 141 may be rotated by a power transmission means such as a chain or belt connected to a sprocket, gear or roller. have. The motor 140 is preferably mounted on the base end 300 for maintenance such as cleaning inside the filter mounting portion 100. The number of revolutions of the motor 143 for rotation of the wing-type porous filter 10 may be, for example, 30, 60, 90, 100 rpm, and the like.

The shaft 130 is vertically fixed to the inside of the filter mounting portion 100 through the central portion of the lower fixing portion 141 of the rotary drive unit 140, so as to prevent conduction when the wing-type porous filter 10 rotates It becomes the central axis. The lower end of the shaft 130 is preferably fixed by a coupling means such as a bolt located inside the base end 300 in order to function as a solid central axis.

The air blower 110 is injected into the pores by injecting compressed air supplied from the outside from the inside of the wing-type porous filter 10 through a plurality of nozzles 111 mounted on the outer circumferential surface of the shaft 130 Remove the dust. The compressed air supplied from the outside is connected to a supply line 113 connected to a compressed air supply device, such as an external compressor, to the shaft 130, and the shaft 130 receives compressed air through the hollow through the nozzle 111. Supply. At this time, the nozzle 111 may be manufactured in a slit shape to increase the air injection angle. The air pressure of compressed air for air blowing of the wing-type porous filter 10 may be, for example, 1, 3, 5, 10 psi.

The punch module 120 uses a punch 123 mounted at the end of the drive shaft of the pneumatic cylinder 121 penetrating the side surface of the filter mounting portion 100 during the reciprocating motion of the pneumatic cylinder 121, thereby providing a winged porous filter 10 Tap the outside of) to shake off the condensed dust. At this time, in order to increase the dust removal efficiency, it is preferable that the punching cycle of the pneumatic cylinder 121 can be changed under the control of the control unit 200. The punch 123 may be made of a synthetic resin material in a cylindrical shape, but the size and It is preferably provided so that it can be replaced by changing the shape and material. The punching period for punching the wing-type porous filter 10 may be 0.5, 1.0, 1.5, 2.0 seconds, etc. per second.

The dust collecting port 150 is composed of an intake line 153 connected to one end of the filter mounting portion 100 and an intake hole 151 formed through one side of the inner bottom surface, and the other end connected to an external dust collector. The dust separated from the type porous filter 10 is sucked and discharged to the outside.

In addition, the filter mounting portion 110 is a circular protrusion formed on the bottom surface of the lid 101 so as to fit into the hollow portion of the wing-type porous filter 10 when the lid 101 is closed, the wing-type porous filter 10 inserted An upper fixing portion 103 for fixing the upper portion of the may be further provided. At this time, the upper fixing part 103 is preferably coupled by a lid 101 and a bearing so that the fixed filter 10 can rotate together when rotating.

The control unit 200 controls the operation of the filter mounting unit 100. In particular, the control unit 200 controls the rotation and stop of the wing-type porous filter 100 by controlling the driving of the motor 143 of the rotation driving unit 140, and the pneumatic cylinder 121 of the punch module 120 ) To control the driving so that when the blade-shaped porous filter 10 rotates by the motor 143, the punch 123 strikes the outside of the blade-shaped porous filter 10 or stops the blow.

At this time, the control unit 200 changes the driving cycle of the pneumatic cylinder 121 of the punch module 120 according to the rotational speed of the wing-type porous filter 10, so that when the wing-type porous filter 10 rotates, the wing It is possible to make the external hitting portion of the type porous filter 10 change.

In addition, the control unit 200 controls an external compressed air supply device such as a compressor to inject and stop compressed air in the wing-type porous filter 10, and controls an external dust collector to control the wing-type porous filter ( 10) to inhale and stop the dust separated from, and detect that the wing-type porous filter 10 is inserted and fixed in the filter mounting portion 100 by the lower fixing portion 141 or the upper fixing portion 103 , It is possible to automatically drive the rotary drive unit 140, the air blower 110, the punch module 120 and the dust collecting port 150.

The dust removal device of the wing-type porous filter according to the present invention configured as described above is equipped with a filter on the filter mounting unit 100 and operates a control unit by turning on a switch for a wing-type porous filter whose function as a filter is reduced due to dust adhesion. When the compressed air supplied from an external compressor or the like is sprayed from a plurality of nozzles under the control of the control unit to remove dust stuck in the pores of the filter, by applying physical force to the filter by punching by the pneumatic cylinder 121 Dust is removed according to the law of inertia. At this time, since the filter is rotated by the rotation driving unit 140, dust is removed from the front of the filter, and dust is removed from the filter by inhaling and discharging the dust separated from the filter through a dust collecting port 150 connected to an external dust collector. Prevents dust from spreading in all directions.

Figures 6a and 6b is a picture of the blade-like porous filter before and after dust removal, in the dust removal device of the wing-type porous filter according to the present invention, the condition of the rotation speed of the motor 60rpm, air pressure 5psi, punching cycle 0.5 seconds, driving time 60 minutes Below, for a filter having a weight of 8.9 kg before dust removal, a filter having a weight ratio of 1.019 compared to a new filter having a weight of 2.7 kg as a 2.75 kg after dust removal was obtained, which confirms that the filter is sufficiently recyclable.

As described above, the wing-type porous filter according to the present invention can easily and quickly cleanly reuse the filter by removing dust stuck in the pores of the filter using air blowing and physical force, and dust is removed during the dust removal process of the filter. It is possible to prevent environmental pollution by preventing it from spreading in all directions, and there is no need for a separate device for preventing environmental pollution.

In addition, the vane-type porous filter according to the present invention can remove dust adhering to the filter without physical damage such as tearing or destruction of pores in the vane-type porous filter. It can be lowered and the product competitiveness can be increased, and dust removal of the filter can be performed automatically, so that the manpower required for dust removal of the filter can be reduced, thereby providing economical effects.

On the other hand, in the detailed description of the present invention, it has been specifically described with reference to preferred embodiments referred to by the accompanying drawings, but of course, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the claims to be described later, but also by the scope and equivalents of the claims.

100: filter mounting portion 101: lid
103: upper part fixing part 110: air blower
111: nozzle 113: compressed air supply line
120: punching module 121: pneumatic cylinder
123: punch 130: shaft
140: rotating drive unit 141: lower fixing
143: motor 150: dust collecting port
151: intake hole 153: intake line
200: control unit 300: proximal end

Claims (6)

As a cylindrical shape with a lid that can be opened and closed, dust-adhesive wing-shaped porous filters are inserted inside and closed and fixed, and then the wing-shaped porous filters are rotated and compressed air is injected to the pores of the wing-shaped porous filters. A filter mounting unit for separating the entangled dust, tapping the wing-shaped porous filter with a linearly moving punch to separate the adhered dust, and suctioning and removing the separated dust from the wing-shaped porous filter;
A control unit for controlling the operation of the filter mounting unit; And
Consists of a; the filter mounting portion and the base portion for mounting the control portion on top,
The filter mounting portion,
A lower fixing part having a circular protrusion formed to fit into a hollow portion of the wing-type porous filter on a disk in close contact with a bottom surface of the wing-type porous filter at the bottom of the inside, and the wing-type porosity inserted into the lower fixing part A rotating driving unit for fixing the filter, rotating the lower fixing portion by a motor, and rotating the vane porous filter inserted and fixed in the lower fixing portion at a constant speed,
A shaft that penetrates through the central portion of the lower fixing part of the rotary driving part and is vertically fixed to the inside of the filter mounting part, and serves as a central axis to prevent conduction when the wing-type porous filter rotates;
And through a plurality of nozzles mounted on the outer circumferential surface of the shaft, the air blower to remove the dust stuck in the pores by spraying the compressed air supplied from the outside from the inside of the wing-type porous filter to the outside,
A punch module for tapping the outside of the wing-type porous filter to shake off the adhered dust during reciprocation of the pneumatic cylinder by using a punch mounted at the end of the drive shaft of the pneumatic cylinder passing through the side of the filter mounting part,
Consists of an intake line connected to the intake hole formed through one side of the inner bottom surface of the filter mounting portion and the other end connected to an external dust collector, to inhale and discharge dust separated from the vane porous filter to the outside. Dust removal device for a vane-type porous filter comprising a dust collecting port.
According to claim 1, The filter mounting portion,
When the lid is closed, it is formed to protrude in a circular shape on the bottom surface of the lid so as to fit into the hollow portion of the wing-type porous filter, and further comprising an upper fixing part for fixing the upper portion of the inserted wing-shaped porous filter. Dust removal device for porous filters.
According to claim 1, The control unit,
Driving the motor of the rotary drive to rotate the vane porous filter and stop the motor to stop rotation of the vane porous filter,
Wing-type characterized in that to stop the blow of the wing-type porous filter by hitting the outside of the wing-type porous filter and stopping the pneumatic cylinder when the wing-type porous filter rotates by driving the pneumatic cylinder of the punch module. Dust removal device for porous filters.
The method of claim 3, wherein the control unit,
Wing-type porous filter characterized in that by changing the driving cycle of the pneumatic cylinder in accordance with the rotational speed of the wing-type porous filter, the outer blow part of the wing-type porous filter is changed when the wing-type porous filter rotates. Dust removal device.
The method of claim 3, wherein the control unit,
By driving an external compressed air supply device to inject compressed air into the wing-type porous filter and stop the compressed air supply device to stop the injection of the compressed air,
Dust removal device for the wing-type porous filter, characterized in that by driving an external dust collector to inhale dust separated from the wing-type porous filter and to stop the dust collection by stopping the dust collector.
According to claim 2, The control unit,
When it detects that the wing-type porous filter is inserted and fixed by the one of the upper fixing part and the lower fixing part, the rotary drive part, the air blower, the punch module and the dust collecting port are automatically detected. Dust removal device of the wing-type porous filter, characterized in that to drive.

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