KR20230048657A - A dust collector for laser processing easy to control dust collecting capacity - Google Patents

Abstract

The present invention relates to a laser processing dust collector with easy control of dust collection capacity, which comprises: a housing provided with an exhaust port at a lower end; a bag filter seated on a first locking unit; and a composite filter module with a shape of an outer surface corresponding to an inner surface of the housing.

Description

A dust collector for laser processing easy to control dust collecting capacity}

The present invention relates to a dust collector for laser processing, and more particularly, to a dust collector for filtering vapors generated during laser processing.

A laser beam is monochromatic light with a very high density and can be made into a beam with excellent parallelism using an appropriate optical system or condensed to a wavelength of light. It is used in a wide range of industries, such as speed measurement, laser communication, laser recording, display devices, and laser medical care. In addition, it is used as a technology to process the surface of an object by converting the energy of a laser beam into thermal energy. , metals, etc., the range of utilization is widening in accessories and fancy fields without restrictions.

A side effect of material processing using such a laser is the generation of harmful substances in the air. The generation of harmful substances is due to thermal decomposition and oxidation due to strong thermal effects at the laser processing point. A mixture of hazardous substances forms so-called laser smoke in the form of dust, suspended solids, aerosols and gases. The amount and composition of the laser smoke differs for each process, but laser smoke is primarily a hazardous substance.

Therefore, it is necessary to install dust collectors to extract and remove these laser fumes to keep the air fresh in the workshop and ensure the quality of laser processing.

On the other hand, the performance of the dust collector required according to the processing scale such as the size of the laser processing device and the amount of processing may vary, and it is necessary to have a dust collector with a capacity suitable for this, but a dust collector of a certain capacity is provided once in the laser processing device If it is impossible to change the capacity, for example, when trying to increase the capacity of the dust collector according to the change in the amount of processing requested, it is a reality that the existing dust collector must be removed and a new dust collector with a larger capacity must be reinstalled.

1 is a perspective view showing a conventional dust collector for laser processing.

Referring to FIG. 1, a conventional dust collector 10 for laser processing is provided with a plurality of filter cartridges 11, and after filtering the surface of the filter 11, the filtered air is discharged through a ventilation device 12 and compressed air 13 is backwashed. Although the separated dust is collected in the dust collection container 14, it is difficult to effectively remove the laser smoke composed of various materials only with a plurality of filter cartridges 11, and the housing 15 and the filter cartridge 11 Laser smoke may leak through cracks, etc., and smoke that is not actually purified may be discharged. If the dust collector capacity needs to be increased, the existing small-capacity dust collector must be removed and a new large-capacity dust collector must be installed.

[Prior patent literature]

- Korean Patent Publication No. 2017-0133931 (2017.12.06.)

An object of the present invention is to provide a dust collector for laser processing that can effectively remove various harmful substances of laser smoke generated during material processing using a laser, and prevents unpurified smoke from being generated due to smoke leakage.

In addition, it is intended to provide a dust collector for laser processing in which the capacity of the dust collector can be easily adjusted according to the change in the amount of laser processing.

In order to solve the above problems, the present invention provides a housing having an intake port through which laser smoke generated from a laser processing device flows into the upper end and an exhaust port through which the sucked laser smoke is filtered and discharged; a bag filter having an inner frame and an outer frame, wherein the outer frame is seated in a first hooking portion protruding from an upper inner side of the housing; and a composite filter module having an outer surface corresponding to the inner surface of the housing and a lower end seated on a second hooking part protruding inside the middle part of the housing, wherein the filtrate passing through the bag filter continuously passes. A HEPA filter and an activated carbon filter are provided, the HEPA filter is seated on the third hooking part protruding inside the middle part, and the first perforated net is seated on the fourth hooking part protruding inside the bottom part, so that the activated carbon filter A dust collector for laser processing including a composite filter module filled between the HEPA filter and the first perforated network, wherein the housing is divided into upper, middle, and lower parts, and is separated and combined into an upper housing, an intermediate housing, and a lower housing. As, separated and coupled by a coupling device installed on the outer surface between the upper housing, the middle housing and the lower housing, the upper housing is provided with the bag filter, the middle housing is provided with the composite filter module, The lower housing is provided with a discharge fan and a drive motor along with the exhaust port, and the upper housing with the bag filter and the middle housing with the composite filter module are stacked in two or more. Provides a multilayer dust collector for laser processing .

In addition, the lower housing has a rim with a flat surface formed on the upper portion, and each of the upper housing and the middle housing has a rim with a flat surface formed on the upper portion, and the lower rim is formed with a groove having a right angle cross section as a whole, , The groove of the upper housing is seated and adhered to the upper rim of the stop housing or another upper housing, and the groove of the stop housing is seated and adhered to the upper rim of the lower housing or another stop housing. A layered dust collector for laser processing is provided.

In addition, a layered dust collector for laser processing is provided, wherein a second perforated network is seated on the third hanging portion, and the HEPA filter is provided on the second perforated network.

In addition, the composite filter module provides a multilayer dust collector for laser processing, characterized in that a fixing bar connected to the inside is formed around the upper circumference of the HEPA filter.

In addition, the composite filter module provides a laminated dust collector for laser processing, characterized in that the material is wood.

In addition, the wood provides a laminated dust collector for laser processing, characterized in that the medium density fiberboard (MDF).

In addition, it provides a laminated dust collector for laser processing, characterized in that the curable polyurethane solution is impregnated and hardened at the contact portion between the composite filter module and the HEPA filter.

In addition, it provides a laminated dust collector for laser processing, characterized in that the gasket is attached to the lower end seated on the second holding portion.

According to the present invention, as a dust collector for removing various harmful substances of laser smoke generated during material processing using a laser, the laser smoke passes through a bag filter, a HEPA filter, and an activated carbon filter in order to remove harmful substances with a simple combination of filters. can be effectively removed, and the HEPA filter and the activated carbon filter are modularized so that all filtrate passed through the HEPA filter passes through the activated carbon filter as it is, so that unpurified smoke is not generated due to smoke leakage.

In addition, the material of the composite filter module is made of wood, the part where the module and the HEPA filter are in contact is impregnated with a curable polyurethane solution, and a gasket is attached to the lower part of the module to provide a dust collector with a structure that can completely block leaking smoke. can

In addition, it is a structure that is separated and combined into upper, middle, and lower housings, so that two or more upper housings with a bag filter and two or more middle housings with a composite filter module can be closely stacked, so that the dust collector capacity is increased according to the change in laser processing amount. It is possible to provide a layered dust collector for laser processing that is easy to control.

1 is a perspective view showing a conventional dust collector for laser processing.
2 is a perspective view showing the appearance of a dust collector for laser processing according to an embodiment of the present invention.
3 is an internal cross-sectional view of a dust collector for laser processing according to an embodiment of the present invention.
Figure 4 is a multilayer dust collector for laser processing according to an embodiment of the present invention, a perspective view showing the appearance of a dust collector in which an upper housing and two middle housings are stacked, respectively.
5 is a stacked dust collector for laser processing according to an embodiment of the present invention, which is an internal cross-sectional view of a dust collector in which two top housings and two middle housings are stacked.
6 is a perspective view showing a composite filter module equipped with a handle according to an embodiment of the present invention.
7 is a perspective view illustrating a state in which a gasket is attached to a lower portion of a composite filter module according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted. In order to clearly describe the present invention in the drawings, parts irrelevant to the description have been omitted, similar reference numerals have been assigned to similar parts throughout the specification, and directions of detailed configurations shown in the dust collector will be described based on the drawings. . Also, throughout the specification, when a part "includes" a certain component, it means that it may further include other components, not excluding other components, unless otherwise stated.

Figure 2 is a perspective view showing the appearance of a multilayer dust collector for laser processing according to an embodiment of the present invention, Figure 3 is an internal cross-sectional view of the multilayer dust collector for laser processing according to an embodiment of the present invention.

2 and 3, the laminated dust collector 100 for laser processing according to an embodiment of the present invention is provided with a housing 110, a bag filter 120, a HEPA filter 131 and an activated carbon filter 132. A composite filter module 130 is included.

The housing 110 serves to seal the laser smoke from leaking to the outside while placing the filters that actually serve as filtration of the dust collector 100 for laser processing of the present invention, and the laser smoke generated from the laser processing device. An inlet 111 through which the inlet is introduced is provided at the top, and an exhaust port 112 through which the inhaled laser smoke is filtered and discharged is provided at the bottom.

In one embodiment of the present invention, the inlet 111 may be formed on the cover 113 on top of the housing 110.

In the present invention, the housing 110 is divided into upper, middle, and lower parts, and is separated and combined into an upper housing 110a, a middle housing 110b, and a lower housing 110c, and the upper housing 110a, the middle The housing 110b and the lower housing 110c are separated and coupled by the coupling device 140 installed on the outer surface, the upper housing 110a is provided with the bag filter 120, and the middle housing 110b is provided with the bag filter 120. The complex filter module 130 is provided, and the discharge fan 114 and the driving motor 115 are provided along with the exhaust port 112 in the lower housing 110c.

The coupling device 140 is not particularly limited in its form as long as it is installed on the outer surfaces of the upper housing 110a, the middle housing 110b, and the lower housing 110c to firmly fix the upper and lower housings, for example Ordinary latch type coupling devices such as draw latches may be used.

Figure 4 is a multilayer dust collector for laser processing according to an embodiment of the present invention, a perspective view showing the appearance of a dust collector in which an upper housing and two middle housings are stacked, respectively, Figure 5 is a multilayer dust collector for laser processing according to an embodiment of the present invention As a dust collector, it is an internal cross-sectional view of a dust collector in which two upper housings and two middle housings are stacked.

4 and 5, in the present invention, as the top housing 110a, the middle housing 110b, and the bottom housing 110c are separated and combined, the upper housing provided with the bag filter 120 ( 110a) and the intermediate housing 110b equipped with the composite filter module 130 enable close stacking of two or more, and accordingly, the capacity of the dust collector can be easily adjusted according to the change in the amount of laser processing.

Here, a structure in which the upper and lower housings are easily adhered to each other while implementing a stacked structure of each housing is disclosed. That is, according to an embodiment of the present invention, the lower housing 110c has an upper portion of the rim 110c-1 having a flat surface, and the upper housing 110a and the middle housing 110b have an upper portion, respectively. Frames 110a-1 and 110b-1 having a flat surface are formed on the lower rim, and grooves 110a-2 and 110b-2 having a right angle cross section are formed on the lower rim, and the groove 110a-2 of the upper housing is formed. 2) to be seated and in close contact with the upper rim 110b-1 of the middle housing or the upper rim 110a-1 of another upper housing, and the groove 110b-2 of the middle housing is the upper part of the lower housing It may be seated and closely attached to the rim 110c-1 or the upper rim 110b-1 of another stop housing. Meanwhile, in FIGS. 3 and 5, it is shown that a gap is formed in a portion where a groove or a protrusion to be described later is seated, but this is exaggerated for reference numerals, and the corresponding portion is formed in close contact.

In addition, the lower end of the upper housing 110a is provided with a protrusion 110a-3 inside the groove 110a-2, and when the upper housing 110a is stacked on the middle housing 110b, the protrusion 110a- 3) When the lower end is in close contact with the upper edge surface of the composite filter module 130 and the upper housing 110a is stacked on another upper housing 110a, the lower end of the protrusion 110a-3 is the outer frame (122) It is closely attached to the upper edge surface 122-1 so that the inside of the housing can be completely sealed.

In addition, the cover 113 also has a groove 113-1 with a right angle cross section formed on the lower edge as a whole, and a protrusion 113-2 is provided at the lower end inside the groove 113-1, so that the protrusion 113 -2) The lower end may be brought into close contact with the upper edge surface 122-1 of the outer frame.

A first hooking part 116 and a second hooking part 117 protruding inward are formed on the upper part of the upper housing 110a and the lower part of the middle housing 110b, respectively, so that the bag filter 120 and the composite filter The module 130 is seated and a detailed description will be given later.

The intake port 111 may be connected by a tube between the outlets of the laser processing device so as to serve as a flow path for laser smoke generated in the laser processing device, for example, and the exhaust port 112 may also be connected by a tube. Of course, it can be discharged as it is.

In the present invention, the filters that play a substantial filtration role are made of a bag filter 120, a HEPA filter 131, and an activated carbon filter 132 in order, and only a combination of the three types of filters is used to remove harmful substances from the laser smoke generated from the laser processing device. can be completely removed.

The bag filter 120 serves to primarily filter and store coarse dust from laser smoke, and has an inner frame 121 and an outer frame 122, and the inlet of the bag filter 120 is the inner frame. (121) in a fixed form. A plurality of bag filters 120 may be modularized, and the bag filters 120 may be fixed to each of the plurality of inner frames 121 provided between the rectangular outer frames 122 , for example, in a modular form. In the bag filter 120, the outer frame 122 is seated on the first hooking part 116 protruding from the upper inner side of the upper housing 110a.

The first hooking part 116 is formed in the form of a bar extending along the upper inner side of the upper housing 110a, and preferably can be formed inside the upper housing 110a.

The material of the bag filter 120 is not particularly limited as long as it is a material capable of filtering relatively large particles of the initially introduced laser smoke, but it is preferably a non-woven fabric material, more preferably a glass fiber non-woven fabric (nonwoven glass microfiber) can be

Since the bag filter 120 is seated on the first hooking part 116 of the upper housing 110a in a form fixed to the inner frame 121 and the outer frame 122, when the filter is replaced, the upper part of the upper housing 110a Filter replacement is possible by a simple method of detaching the outer frame 122 after detaching the cover 113 .

The HEPA filter 131 serves to purify the air by filtering out ultrafine particles, organic solvents, harmful smoke, etc. among the filtrate that has passed through the bag filter 120, and is located above the composite filter module 130 described later. do.

A HEPA filter is a high-performance filter that filters particulates in the air, and is a filter capable of removing 99.97% or more of particulate matter having a particle size of 0.3 μm or more. In the present invention, a bag filter (120 ), most ultra-fine particles, organic solvents, harmful substances, etc. can be sufficiently filtered for the smoke from which substances with relatively large particle sizes have been filtered out of the laser smoke.

The HEPA filter 131 is not limited in its shape as long as it satisfies the required filter performance, but has a thickness of 0.5 to 1 mm in terms of particulate removal efficiency in laser smoke through maximization of the surface area and forms a layer with a certain height. It is preferable that it is folded in a zigzag pattern.

The material of the HEPA filter 131 is not particularly limited, but a filter made of a glass fiber material may be preferably used.

The activated carbon filter 132 serves to filter the filtrate that has passed through the HEPA filter 131 into clean air through deodorization, discoloration, and sterilization, and is located at the bottom of the composite filter module 130 described later. .

Activated carbon is a carbonaceous material with strong adsorption. It is an adsorbent developed with fine pores of molecular size through an activation process that burns carbonaceous raw materials such as coconut husk, wood, lignite, and anthracite. It is a powdery or granular porous material with strong adsorption. Inside the furnace, it has a surface area of about 500 to 1,500 m2 per 1 g.

The form of the activated carbon 132 is crushed, powdery, shaped, fibrous, etc., but in the present invention, the filtrate that has undergone primary filtration by the bag filter 120 and secondary filtration by the HEPA filter 131 is targeted In addition, in consideration of deterioration in filtration performance and deterioration in filter life due to the dispersion of activated carbon by the suction pressure of the motor 115 of the lower housing 110c, irregularly shaped crushed activated carbon having a particle size of 5 to 200 mesh is preferable. can be used

The activated carbon 132 may be provided by filling the lower portion of the composite filter module 130 having a pre-designed height.

In the present invention, the HEPA filter 131 and the activated carbon filter 132 are provided in the composite filter module 130, installed together, and replaced together after use. As a result of repeated evaluation of the filter performance by allowing the filtrate that passed through the bag filter 120 to continuously pass through the HEPA filter 131 and the activated carbon filter 132 of the preferred material for laser smoke collection, significant filter performance was obtained. It is a configuration derived from the result of confirming that the durability and service life of the HEPA filter 131 and the activated carbon filter 132 are approximately similar within the limit of maintenance. In addition, when the HEPA filter 131 and the activated carbon filter 132 are mounted separately, the bag filter 120 ) There was a problem leading to deterioration in filtration performance, such as the inflow of the filtrate that passed through the HEPA filter 131 into the activated carbon filter 132, and the composite filter module 130 was derived to solve this problem. It is a structure.

Therefore, in the present invention, the composite filter module 130 has an outer surface corresponding to the inner surface of the housing 100, and the lower end is seated on the second hooking part 117 protruding from the inside of the stop housing 110b. A bag filter 131 and an activated carbon filter 132 are provided inside the module 130 as a form. That is, a HEPA filter 131 and an activated carbon filter 132 through which filtrate passed through the bag filter 120 continuously passes are provided, and the HEPA filter 131 protrudes from the inside of the middle portion of the composite filter module 130 The first perforated net 135 is seated on the third hooking part 133 and on the fourth hooking part 134 protruding inside the lower end of the composite filter module 130, so that the activated carbon filter 132 is a HEPA filter. It is filled between the 131 and the first perforated network 135.

The second hooking part 117 is formed in the form of a bar extending long along the inside of the lower part of the middle housing 110b, and preferably can be formed inside the middle housing 110b.

The third hooking part 133 and the fourth hooking part 134 protrude inside the middle part and the bottom part of the composite filter module 130 and are formed in a bar shape extending along the inside, respectively, and each HEPA filter ( 131) is seated and the first perforated net 135 is seated so that the activated carbon filter 132 is filled.

The first perforated net 135 is preferably a thin plate-shaped net material made of a metal material, and is perforated at regular intervals to a size that does not allow activated carbon to pass through, so that purified air can move while being filled with activated carbon.

Here, since the activated carbon 132 may pass through the first perforated net 135 depending on the size, the activated carbon 132 may be filled with the filter paper 136 placed on the first perforated net 135.

In one embodiment of the present invention, the second perforated network 137 may be seated on the third hanging part 133, and the HEPA filter 131 may be provided on the second perforated network 137.

The second perforated net 137 may have the same material and shape as the first perforated net 135, and the second perforated net 137 is seated on the third hanging part 133, so that when the laser smoke collection is operated, As the HEPA filter 131 and the activated carbon filter 132 are arranged adjacently in the module 130, the activated carbon 132 is in contact with the HEPA filter 131 located at the top due to vortex, vibration, etc. in a high pressure environment. of durability and performance degradation can be prevented.

In one embodiment of the present invention, the complex filter module 130 may have a fixing bar 138 connected to an inner side of the upper circumference of the HEPA filter 131 .

The fixing bar 138 is provided in a form in contact with the composite filter module 130 around the upper circumference of the HEPA filter 131, and is fixed inside the composite filter module 130 with, for example, a piece, so that the HEPA filter 131 is to make it fixed. Accordingly, it is possible to prevent smooth filtration from being disturbed due to vibration of the HEPA filter 131, which is a relatively light material, in a high pressure environment during laser smoke collection operation.

Meanwhile, when replacing the composite filter module 130, as shown in FIG. 6, a handle 139-1 may be provided at the top of the module 130 or at the top of the fixing bar 138 to enable easy replacement.

In one embodiment of the present invention, the composite filter module 130 may be made of wood, preferably medium density fiberboard (MDF).

The MDF is a wood processed by heat and pressure by mixing sawdust and an adhesive, and is a plate material molded and hot-pressed with a synthetic resin adhesive after grinding the wood to extract fibers. Such MDF has the advantage of having a smooth surface, high density, excellent workability and robustness, and thus less shrinkage, distortion, and expansion.

In the present invention, in consideration of the advantages of MDF, by adopting wood, preferably MDF, as the material of the composite filter module 130, the durability degradation of the filter module 130 is minimized, and manufacturing according to the dust collector standard is easy to improve the design freedom. It can be made, and furthermore, it is particularly suitable for preventing the deterioration of filtration performance described below.

In one embodiment of the present invention, the part where the composite filter module 130 and the HEPA filter 131 come into contact may be impregnated and cured with a curable polyurethane solution, and the composite filter module ( 130) By adopting wood materials such as MDF, the effect of preventing deterioration in filtering performance is maximized, and at the same time, the problem of deformation due to moisture, which is a disadvantage of wood materials such as MDF, can be solved.

That is, although the HEPA filter 131 and the activated carbon filter 132 are provided in one module 130, some of the filtrate that has passed through the bag filter 120 is transferred to the inside of the composite filter module 130 and the HEPA filter 130. Although it may flow into the activated carbon filter 132 through the gap between the filters 131, the curable polyurethane solution is excellent in impregnating the HEPA filter 131 made of wood and glass fibers due to its characteristics, leading to solid curing. By increasing the airtightness and completely blocking the inflow of the filtrate through the gap between the composite filter module 130 and the HEPA filter 131, the effect of preventing deterioration in filtration performance may be maximized.

In addition, even if a wood material such as MDF is deformed by moisture and there is a possibility that the gap between the composite filter module 130 and the HEPA filter 131 is further widened, the deformation by moisture has not been prevented due to impregnation and curing of the curable polyurethane solution. can be prevented in

As such, even if the HEPA filter 131 and the activated carbon filter 132 are combined into one module 130, the filtrate passing through the bag filter 120 flows into the gap between the housing 110 and the composite filter module 130. It could be. In anticipation of this problem, in one embodiment of the present invention, as shown in FIG. 7 , a gasket 139 may be attached to a lower end seated on the second hanging part 117 .

The material of the gasket 139 is not particularly limited as long as it can block the inflow of gas components, and for example, a gasket made of urethane or silicon may be used.

The gasket 139 is attached to the lower end of the composite filter module 130 in the form of an elongated bar and is seated on the second hanging part 117 so that the filtrate passing through the bag filter 120 and the housing 110 The possibility of inflow into the gap between the composite filter modules 130 can be completely blocked.

In the above, preferred embodiments of the present invention have been described in detail with reference to the drawings. The description of the present invention is for illustrative purposes, and those skilled in the art will understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning, scope and equivalent concept of the claims are included in the scope of the present invention. should be interpreted

100: dust collector for laser processing 110: housing
110a: upper housing 110a-1: upper rim of the upper housing
110a-2: lower concave of the upper housing 110a-3: lower projection of the upper housing
110b: middle housing 110b-1: upper rim of the middle housing
110b-2: lower groove of the stop housing 110c: lower housing
110c-1: upper rim of lower housing
111: intake 112: exhaust
113: cover 113-1: lower groove of cover
113-2: lower protrusion of cover 114: discharge fan
115: drive motor 116: first hooking part
117: second hanging part 120: bag filter
121: inner frame 122: outer frame
122-1: outer frame upper edge surface 130: composite filter module
131: HEPA filter 132: activated carbon filter
133: third hooking part 134: fourth hooking part
135: first perforated net 136: filter paper
137: second perforated network 138: fixed bar
139: gasket 139-1: handle
140: coupling device

Claims (8)

A housing having an intake port through which laser smoke generated from the laser processing device is introduced at an upper end and an exhaust port through which the inhaled laser smoke is filtered and discharged is provided at a lower end;
a bag filter having an inner frame and an outer frame, wherein the outer frame is seated in a first hooking portion protruding from an upper inner side of the housing; and
A composite filter module having an outer surface corresponding to the inner surface of the housing and having a lower end seated on a second hooking part protruding inside the middle part of the housing, wherein the filtrate passing through the bag filter is continuously passed A HEPA filter and an activated carbon filter are provided, the HEPA filter is seated on the third hooking part protruding inside the middle part, and the first perforated net is seated on the fourth hooking part protruding inside the bottom part, so that the activated carbon filter a composite filter module filled between the HEPA filter and the first perforated network;
A dust collector for laser processing comprising a,
The housing is divided into upper, middle, and lower parts, and is separated and combined into an upper housing, an intermediate housing, and a lower housing, and is separated and coupled by a coupling device installed on the outer surface between the upper housing, the intermediate housing, and the lower housing. , the upper housing is provided with the bag filter, the middle housing is provided with the complex filter module, and the lower housing is provided with a discharge fan and a drive motor together with the exhaust outlet,
Laminated dust collector for laser processing, characterized in that two or more of the upper housing provided with the bag filter and the middle housing provided with the composite filter module are stacked. According to claim 1,
The lower housing is formed with a rim having a flat surface at the top,
Each of the upper housing and the middle housing has a rim having a flat surface formed on the upper portion, and a groove having a right angle cross section is formed on the lower rim as a whole,
The groove of the upper housing is seated and closely attached to the upper rim of the middle housing or another upper housing,
Laminated dust collector for laser processing, characterized in that the groove of the stop housing is seated and in close contact with the upper rim of the lower housing or another stop housing. According to claim 1,
A layered dust collector for laser processing, characterized in that a second perforated net is seated on the third hanging part, and the HEPA filter is provided on the second perforated net. According to claim 1,
The composite filter module is a multilayer dust collector for laser processing, characterized in that a fixing bar connected to the inside is formed around the upper circumference of the HEPA filter. According to claim 1,
The composite filter module is a laminated dust collector for laser processing, characterized in that the material is wood. According to claim 5,
The wood is a laminated dust collector for laser processing, characterized in that the medium density fiberboard (MDF). According to claim 5,
Laminated dust collector for laser processing, characterized in that a curable polyurethane solution is impregnated and hardened in a portion where the composite filter module and the HEPA filter come into contact. According to claim 5,
Laminated dust collector for laser processing, characterized in that a gasket is attached to the lower end seated on the second holding portion.

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