KR20140107742A - Ultra fine fiber filter and manufacturing method of the same - Google Patents

Abstract

The present invention relates to an ultra-fine fiber filter for collecting dust in order to effectively filter fine dust or foreign substances included in the air, and to a manufacturing method thereof. The present invention provides an ultra-fine fiber filter for collecting dust, which is formed by weaving multiple multi-filaments in a net form, wherein the multi-filaments are formed by twisting 24-48 strains of mono-filaments to 50-100 denier. Accordingly, the ultra-fine filter for collecting dust of the present invention has less pressure loss and an excellent dust collecting performance, and therefore, can effectively filter fine dust or foreign substances in comparison with existing PP mesh pre-filters. Furthermore, the ultra-fine filter for collecting dust of the present invention can filter more air volume at the same strength, which allows usage of a relatively small scale blowing motor, thereby obtaining effects of reducing electricity consumption, reducing noise, reducing manufacturing costs, etc.

Description

Technical Field [0001] The present invention relates to a microfiber filter for dust collection and a manufacturing method thereof,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microfibre filter for dust collection and a method of manufacturing the same, and more particularly, to a microfibre filter for dust collection and a method of fabricating the same for efficiently filtering fine dust and foreign matter contained in air.

The increase of air pollution due to industrial development and urbanization involves serious pollution of indoor and outdoor air. Various kinds of filters are used and developed to purify polluted air.

Among the commonly used filters, the dust filter is used for collecting and filtering dust and foreign substances contained in the air and is applied as a pre-filter for pre-treatment and a bag filter for post-treatment in air conditioner, air purifier, industrial air conditioner and the like.

PP (polypropylene) mesh prefilters are mainly used as conventional pre-treatment dust collecting filters.

Conventional PP mesh prefilters are made of polypropylene mesh using monofilaments and have advantages of low pressure loss during dust collection, excellent durability, and long service life and are widely used in various applications.

However, the conventional PP mesh pre-filter is disadvantageous in that the filter performance is poor compared to the pressure loss (pressure loss) generated at the time of dust collection, and the dust collecting efficiency is lowered.

The present invention provides a microfibre filter for dust collection and a method for manufacturing the microfibre filter, which are designed to remedy the above-mentioned problems, and that can effectively filter fine dust or foreign matter contained in air with less pressure loss during dust collection and excellent dust collection performance. It has its purpose.

According to an aspect of the present invention, there is provided a dust collecting microfibre device comprising: a plurality of multifilaments meshed in a net shape; and the multifilament is formed of 50 to 100 deniers by twisting 24 to 48 monofilaments. Filter.

Preferably, each of the monofilaments forming the multifilament is a microfiber of a PET material, and has a cross-sectional structure in which an outer PET material is coated on the inner surface of the PET material.

Preferably, the inner PET material may be a material having a melting point of 140 to 230 ° C, and the outer low melting point PET material may be a material having a melting point of 90 to 120 ° C.

For example, the inner PET material may be selected from the group consisting of solid-phase-polymerized PET and SD PET, and the outer low-melting-point PET material may be a low melting fiber.

The present invention also provides a process for producing multifilaments of 50 to 100 denier by twisting 24 to 48 monofilaments; And weaving a filter by weaving a plurality of multifilaments into a net shape. The method of manufacturing a microfiber filter for dust collection according to claim 1,

In the above filter manufacturing method, a plurality of multifilaments are weaved into a net shape to woven the filter, and then the surface of the filter in a woven state is heated to attach the multifilaments that are in contact with each other. And the temperature is 90 to 150 ° C.

The micro dust filter for dust collection according to the present invention has a smaller pressure loss and excellent dust collection performance than conventional PP mesh prefilters and can effectively filter fine dust and foreign matter contained in the air, It is possible to use a relatively small size blowing motor which can reduce power consumption, reduce noise, and reduce cost.

Fig. 1 is a photograph showing the microfine filter fabricated according to the present invention at 200 magnifications
2 is a cross-sectional view of a monofilament used in the microfiber filter according to the present invention;
Fig. 3 is an enlarged view of the microfiber filter according to the present invention compared with a conventional PP mesh prefilter
4 is a graph showing the results of dropping activated carbon on the microfine filter according to the present invention and the conventional PP mesh prefilter
5 is a graph showing the result of measurement of the dust collection efficiency by applying the weight method to each of the microfine filter according to the present invention and the conventional PP mesh prefilter
6 is a graph showing the results of measuring the pressure loss of the microfine filter according to the present invention and the conventional PP mesh prefilter according to the surface speed

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

The micro-filter according to the present invention is a dust-collecting pre-filter having a small pressure loss (pressure loss) and an excellent dust collecting efficiency as compared with a conventional PP mesh pre-filter and is formed so as to effectively filter fine dust such as yellow dust as well as fine dust.

The microfiber filter is fabricated into a dense mesh structure using ultra-fine microfibers in order to realize low pressure hand and high efficiency compared to the conventional art.

Such a microfine filter is woven by weaving a plurality of multifilament yarns into weft yarns with wefts and warp yarns, and the multifilament yarns are formed by twisting a plurality of monofilaments.

FIG. 1 is a photograph of a microfiber filter fabricated according to the present invention magnified at a magnification of 200, in which multifilament yarns used as weft yarns and multifilament yarns used as warp yarns are woven in a mesh form, and each multifilament has a plurality of strands of monofilament Has a twisted shape.

Specifically, as the multifilament, 24 to 48 monofilaments are formed to have a denier of 50 to 100, and 24 to 48 monofilaments are simultaneously radiated (drawn) from a spinning nozzle to perform a mechanical operation Continue the speaker process. Or 24 to 48 monofilaments at the same time as the yarn process is also progress.

For example, as the multifilament, 24 twisted monofilaments twisted to 50 denier twist yarns, or twenty-six twisted monofilaments twisted to 75 deniers, or 48 twisted mono filaments, A twisted yarn made of filament twisted at 100 denier can be used.

As the thickness of the multifilament increases, the strength of the filter increases. However, since the pressure loss increases during manufacture of the filter device such as the air cleaner, the multifilament is appropriately manufactured within the above range.

In order to prevent the filter from being loosened when the MESH type microfiber filter is woven using a plurality of multifilaments as described above, each multifilament is woven with a weft and a warp and then subjected to a heat treatment process (tentative process) Heating the filter surface in a woven state to attach multifilaments that are in contact with (touching) each other.

That is, when the surface of the filter is heated by a post-process after the multifilament is woven to woven the microfilament, the surface of the multifilament woven between the weft and the warp is fused so that the multifilaments are attached to each other So that the filter can be prevented from being released.

By thus preventing the filter from being loosened, the multifilament weaving state is maintained, so that it is possible to cut the cold knife at the time of manufacturing the filter, thereby improving the ease of fabrication, and improving the production speed and productivity.

For this purpose, microfilaments made of polyethylene terephthalate (PET) are used as the monofilaments forming the multifilaments in order to melt and bond the multifilaments during the heat treatment process after the weaving process.

In particular, as shown in FIG. 2, the monofilament has a cross-sectional structure in which a low melting point PET is coated on the outer surface (surface) of the inner PET material so as to cause melting phenomenon only on the surface of the multifilament during the heat treatment process What you have is used.

In this case, the melting point (melting point) of the inner PET material is 140 to 230 ° C and the melting point of the outer low melting point PET material is 90 to 120 ° C. Specifically, for example, (SemiDul) PET or the like can be used. As an external low melting point PET material, a low melting fiber or the like can be used.

In addition, the heating temperature is suitably in the range of 90 to 150 ° C. in the heat treatment step. If the temperature is out of the above-mentioned range, the internal PET material may be melted or the adhesiveness between the multifilaments may be insufficient.

The microfiber filter fabricated in this way is densely formed to effectively filter fine particles such as yellow dust as well as fine dust, thereby improving the dust collecting efficiency and reducing the pressure loss compared to the conventional PP mesh prefilter.

Therefore, when the microfiber filter has the same strength as that of the conventional PP mesh prefilter, a relatively small pressure loss is generated, so that a greater amount of air can be provided to the device when the microfiber filter is mounted on an apparatus such as an air purifier.

Therefore, it is possible to use a relatively low-capacity blowing motor in order to obtain the same air volume as that of the conventional PP mesh pre-filter, and it is possible to reduce power consumption, reduce noise, and reduce costs have.

When such a microfine filter is mounted on a device such as an air cleaner with a pretreatment filter, it is advantageous to have a larger specific area.

Hereinafter, preferred embodiments of the present invention will be described in order to facilitate understanding of the present invention, but the present invention is not limited thereto.

Example

Twenty four monofilaments having a cross-sectional structure coated with a low-melting fiber on the inner surface of the SD PET material were simultaneously spun, and the monofilaments were spun to produce a multifilament.

The fabricated multifilaments were woven using a weft and a warp, and then heat treated at 110 ℃ to fabricate a microfiber filter.

Comparative Example

A PP mesh prefilter having the same strength as that of the microfiber filter fabricated in the above example was woven using a monofilament made of polypropylene as the weft and the warp.

Experimental Example

20 meshes of activated carbon were dropped on each of the microfine filter of the above-mentioned example and the PP mesh pre-filter of the comparative example, and the state of passing through each filter was confirmed. The results are shown in FIG.

The microfiber filter of the above-described embodiment and the PP mesh prefilter of the comparative example were fabricated to have the same strength, but as shown in FIG. 3, it was confirmed that the microfiber filter had a much denser structure than the PP mesh prefilter.

As shown in FIG. 4, the micro fiber filter of the above-described example was loaded on the filter without the activated carbon passing through the filter, while the PP mesh pre-filter of the comparative example showed that about 90% or more of the activated carbon was passed down through the filter .

As a result of measuring the dust collecting efficiency by applying the weight method to each of the microfine filter of the above embodiment and the PP mesh prefilter of the comparative example, it was confirmed that the dust collecting efficiency of the microfine filter was superior to that of the PP mesh prefilter I could.

As a result of measuring the pressure loss (pressure loss) of the microfine filter of the above-described example and the PP mesh prefilter of the comparative example according to the surface speed, the pressure loss of the microfine filter was smaller than that of the PP mesh prefilter .

Claims (8)

Wherein the multifilament is formed by weaving a plurality of multifilaments in a net shape, and the multifilament is formed of 50 to 100 deniers by twisting 24 to 48 monofilaments.
The method according to claim 1,
Wherein each of the monofilaments forming the multifilament is a microfiber of PET material and has a cross sectional structure in which a surface of an inner PET material is coated with an outer low melting point PET material.
The method of claim 2,
Wherein the inner PET material has a melting point of 140 to 230 ° C and the outer low melting point PET material has a melting point of 90 to 120 ° C.
The method of claim 2,
Wherein the inner PET material is selected from the group consisting of solid-state polymerized PET and SD PET, and the outer low melting point PET material is a low melting fiber.
A process of producing multifilaments of 50 to 100 denier by twisting 24 to 48 monofilaments;
A process of weaving a filter by weaving a plurality of multifilaments in a net shape;
Wherein the microfibers are formed of a metal.
The method of claim 5,
And a heat treatment step of heating the filter surface in a woven state to attach the multifilaments contacting each other after the filter is woven.
The method of claim 5,
Wherein each of the monofilaments forming the multifilament is a microfiber of a PET material and has a cross-sectional structure in which an outer PET material is coated on the inner surface of the PET material.
The method of claim 6,
Wherein the heating temperature of the heat treatment step is 90 to 150 占 폚.

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