KR101691588B1 - Shell filter system - Google Patents

Abstract

The present invention relates to a shell filter system comprising: a filter casing having a casing body, a heating chamber, an inlet and an outlet; a first HEPA filter having a first HEPA filter body, a ventilation part and a first through-hole; a first shell filter having the first shell filter body and a plurality of buffer members; a spacer board having a spacer body, a plurality of through-holes and a plurality of buffer members; and a second HEPA filter having a second HEPA filter body and a second through-hole. Accordingly, the shell filter system can mass-produce a shell filter using shells, and can improve collection efficiency of volatile organic compounds such as benzene, toluene, chloroform, acetone, etc. by assembling a plurality of HEPA filters and shell filters.

Description

{Shell filter system}

The present invention relates to a shell filter system.

As shown in FIG. 6, Korean Patent No. 0371501 (registered on Apr. 24, 2003, entitled: Waste Gas Purification Biofilter) has a waste gas inlet formed at a lower side of one side and a lower gas inlet A filter box having a leachate outlet formed therein and having a plurality of purge gas outlets formed on an upper surface thereof; A two-layer upper and lower filter layers each consisting of a porous plate provided in two stages inside the box and a filler inoculated with decomposing microorganisms loaded on each porous plate; A lid positioned at an upper portion of the box; And a plurality of nozzles located under the porous plate of the upper lid and the upper filter layer, wherein the porous shell powder is contained as a microorganism carrier in either the filter layer or the upper and lower filter layers of the upper and lower filter layers, Which is characterized in that a white bug fungus is contained in the exhaust gas purifying filter.

Such prior art claims that the use of the biofilter can purify the waste gas more efficiently, facilitate the installation of the filter box, the filling of the filter material and the filter replacement, and the ease of transportation, while the manufacturing method Which is complicated and low in efficiency.

An object of the present invention, which is created to solve the above-mentioned problems, is to provide an adsorption filter using a closed loop through a simple treatment process, and to provide a low-priced closed-loop filter system having an excellent adsorption rate.

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An object of the present invention is to provide a heating apparatus for a heating furnace, which comprises a casing body provided with an opening at an upper portion thereof and provided with a screen on the front thereof, a heating chamber provided on a lower surface of the casing body, A filter casing having an inlet communicated with one side of the heating pipe and a discharge port provided on one side of the heating chamber and communicating with the other side of the heating pipe; A first gas permeable body formed in the center of the first hemaffil filter body and having a rectangular band groove formed in the periphery of the gas permeable body; A first HEPA filter having a first through-hole formed in the first HEPA filter body; A first shell filter body inserted into an upper opening of the filter casing and having a rectangular plate shape provided on a rear surface of the first hepafar filter and a plurality of buffer members provided on a front edge of the first shell filter body; A shell filter; A plurality of air holes formed in the spacer body and inserted through openings formed in an upper portion of the filter casing, the spacer body being provided on a rear surface of the first shell filter; A spacer plate having a member; And a second through hole inserted through an upper opening of the filter casing, the second through hole being formed in the shape of a square band groove, the second through hole being formed on the rear surface of the spacer plate, The second HEPA filter having the second HEPA filter.

Preferably, a second shell filter body in the form of a rectangular plate, which is inserted through the upper opening of the filter casing so as to be interposed between the spacer plate of the present invention and the second hepafar filter, And a second shell filter composed of a plurality of buffer members provided on the front edge of the second shell filter.

More preferably, the cushioning members of the present invention are provided with a double-sided tape, a PET film provided on the upper surface of the double-sided tape, a polyethylene film provided on the upper surface of the PET film, and an upper surface of the polyethylene film And a rubber plate material having a plurality of dimples formed on an upper surface thereof.

Preferably, the present invention further comprises a plurality of thermally conductive pads provided on a front edge of the second HEPA filter body, wherein the thermally conductive pad is composed of a double-sided tape and a copper foil provided on an upper surface of the double- do.

As described above, the present invention can mass-produce a shell filter using a shell, and can improve the collection efficiency of volatile organic compounds such as benzene, toluene, chloroform, and acetone by assembling a plurality of HAPPA filters and a shell filter .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a process diagram showing a method for producing a volatile organic compound adsorption filter using the shell of the present invention. FIG.
2 is a perspective view showing a shell filter system using a shell according to the present invention.
3 is an exploded perspective view showing the filters of Fig.
4 is an enlarged cross-sectional view showing the buffer member.
5 is a cross-sectional enlarged view showing the heat conduction member.
6 is a front view showing a conventional biofilter for purification of waste gas.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

Referring to FIG. 1, the volatile organic compound adsorption filter using the shell according to the present invention, which uses a shell, removes organic substances or contaminants remaining on the inside and outside of the shell, crushes it through an acid treatment or a heating reaction process, A detailed description thereof is as follows.

Selection step

It is preferable to use shells of various sizes as shown in Table 1 in the selection step of the present invention.

Referring to Table 1, the selection criteria of the shell used in the present embodiment are 31 to 40 mm, 45 to 60 mm, 65 to 100 mm and 110 to 150 mm long (or diameter) , And the fracture rate and the contamination rate are preferably 30% or less depending on the size or diameter.

The present example also shows that the shell length is 70 to 100 parts by weight, the shell length is 45 to 60 mm, the shell length is 20 to 30 parts, and the shell length is 65 And 40 to 60 parts by weight. Here, in the present embodiment, the reason why the content ratio is determined is that the shorter the shell length, the higher the hardness, the larger the particle size (powder), the larger the shell length, the lower the hardness and the smaller the particle size (powder) This is because it is possible to easily form a large number of pores in the molding by mixing powder.

Washing step

15 to 20 parts by weight of gravel having a particle size of 10 to 15 mm are mixed with 100 parts by weight of the selected shell, washed in the ultrasonic washing machine filled with washing water and then washed 3 to 5 times. Here, in order to strongly clean the shell, it is preferable to use a dishwasher having a capacity of 2 KW generator equipped with 40 to 50 vibration elements having a capacity of 50 W vibrating element.

Heating step

After filling the washed shell with the washing vessel, the washing water is boiled for 10 to 30 minutes in order to remove organic matter and contaminants remaining in the shell, and is then washed out and washed with hot air at 130 to 180 ° C.

Methanol treatment step

After the hot air-dried shell is filled in a sealed container filled with methanol, after 8 to 10 hours, the sealed container is opened to dry naturally. Here, the methanol treatment of this embodiment is intended to remove fine organic matter and contaminants that may remain in the shell.

In addition, the methanol treatment may be repeated 2 to 5 times depending on the degree and amount of microorganisms or contaminants remaining on the shell.

Reaction step

The prepared shell is charged into a vacuum crucible and then heated to 800 to 1,000 DEG C, followed by cooling to a particle size of 20 to 100 mu m.

Here, the high purity calcium carbonate can be produced by chemical reaction using hydrochloric acid and ammonia water at a high concentration in the shell, however, since the manufacturing process is complicated and mass production is not easy, Lt; / RTI >

Molding step

5 to 10 parts by weight of water is mixed with 100 parts by weight of shell powder in a molding mold heated to 60 to 70 ° C and molded at a pressure of 130 to 300 kgf / cm 2 to prepare a volatile organic compound adsorption filter using a shell. It should be noted that the temperature or pressure of the mold can be applied differently depending on the purpose of use.

2 to 5, a closed-type filter system 100 according to the present invention includes a filter casing 10, a first HEPA filter 20, a first shell filter 30, a spacer plate 40, 2 shell filter 50 and a second hepafar filter 70.

The filter casing 10 is provided with a casing body 11 provided with an opening 11a at an upper portion thereof and provided with a screen 13 on an opened front thereof and a casing body 11 provided on a lower surface of the casing body 11, An inlet Pi which is provided on one side of the heating chamber 15 and communicates with one side of the heating pipe 17 and a heating chamber 15 which is provided on one side of the heating chamber 15, And a discharge port (Po) communicated with the other side of the pipe (17).

Here, the heating chamber 15 in which the heating pipe 17 is installed is provided so that the heating medium supplied from the heating medium boiler (not shown) flows through the inlet Pi and circulates to the heating medium boiler through the discharge port Po, To dry the various filters 20, 30, 40, 50, and 70 built into the body 11.

The first HEPA filter 20 includes a first HEPA filter body 21 of a plate shape, a ventilation part 23 formed at the center of the first HEPA filter body 21, And at least one first through-hole (25).

The reason why the vent hole 23 is formed in the center of the first HEPA filter body 21 is that the volatile organic compound is filtered by the first shell filter 30.

A plurality of first through holes 25 are formed in a rectangular band groove shape having the same center and are provided to disperse the air introduced into the first hepafar filter 20. [

The first shell filter 30 comprises a first shell filter body 31 in the form of a rectangular plate and a plurality of buffer members 35 provided at the front edge of the first shell filter body 31.

Here, the first shell filter body 31 is manufactured by the above-described method of manufacturing a volatile organic compound adsorption filter using shell, and a detailed description thereof will be omitted.

The cushioning member 35 is provided to prevent damage to the first shell filter 30 which is in close contact with the first HEPA filter 20 and has a double-sided adhesive tape Adh provided on the front surface of the first shell filter body 31 A PET film F1 provided on the upper surface of the double-sided tape Adh; a polyethylene film F2 provided on the upper surface of the PET film F1; And a rubber plate material F3 having a plurality of dimples DP formed on its surface.

Here, the dimple DP is provided to easily disperse the external force even if the first shell filter 30 is excessively brought into close contact with the first HEPA filter 20.

The spacer plate 40 has a spacer body 41, a plurality of vent holes 43 formed in the spacer body 41 and a plurality of buffer members 45 provided at the front edge of the spacer body 41. [ Lt; / RTI >

Here, since the buffer member 45 provided in the spacer plate 40 has the same configuration and function as those of the buffer member 35 of the first shell filter 30 described above, detailed description and illustration thereof will be omitted.

The second shell filter 50 includes a second shell filter body 51 having a rectangular plate shape and a plurality of buffer members 55 provided at the front edge of the second shell filter body 51, (30), the detailed description thereof will be omitted.

The second HEPA filter 70 includes a plate-like second HEPA filter body 71, at least one second through-hole 73 formed in the second HEPA filter body 71, a second HEPA filter body 71 And a plurality of heat conductive pads 75 provided on the front edge of the heat conductive pad 75.

Here, the thermal conductive pad 75 is formed of a silver foil-containing double-faced tape (Ag-Adh) provided on the front surface of the second hepafar filter body 71 and a copper foil (Ag-Adh) provided on the upper surface of the silver- CP). It is to be noted in advance that the double-sided tape containing silver powder (Ag-Adh) is a double-sided tape having good thermal conductivity and that the above-described double-sided tape (Adh) can be used.

The first shell filter 20, the first shell filter 30, the spacer plate 40, the second shell filter 50, and the second hepafar filter 20 are connected through the upper opening 11a of the filter casing 10, (70) are sequentially inserted and assembled, and each of the pillars is separated by the buffer member (35) (45) (55) and the heat conductive pad (75).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: Filter casing
20, 70: HEPA filter
30: 1st shell filter
31: first shell filter body 35: buffer member
100: shell filter system

Claims (5)

delete A heating chamber provided on a lower surface of the casing body and having a heating pipe therein; a heating chamber provided on one side of the heating chamber, A filter casing having an inlet communicated with one side and a discharge port provided on one side of the heating chamber and communicating with the other side of the heating pipe;
A first gas permeable body formed in the center of the first hemaffil filter body and having a rectangular band groove formed in the periphery of the gas permeable body; A first HEPA filter having a first through-hole formed in the first HEPA filter body;
A first shell filter body inserted into an upper opening of the filter casing and having a rectangular plate shape provided on a rear surface of the first hepafar filter and a plurality of buffer members provided on a front edge of the first shell filter body; A shell filter;
A plurality of air holes formed in the spacer body and inserted through openings formed in an upper portion of the filter casing, the spacer body being provided on a rear surface of the first shell filter; A spacer plate having a member;
And a second through hole inserted through an upper opening of the filter casing, the second through hole being formed in the shape of a square band groove, the second through hole being formed on the rear surface of the spacer plate, And a second HAPA filter.
3. The method of claim 2,
A second shell filter body in the form of a rectangular plate inserted through the upper opening of the filter casing so as to be interposed between the speaker plate and the second hepafar filter; Further comprising a second shell filter made of a cushioning member.
The method according to claim 2 or 3,
Wherein the buffering members comprise a double-sided tape, a PET film provided on an upper surface of the double-sided tape, a polyethylene film provided on an upper surface of the PET film, and a plurality of dimples provided on an upper surface of the polyethylene film And a rubber plate material.
3. The method of claim 2,
Further comprising a plurality of thermally conductive pads provided on a front edge of the second HEPA filter body, wherein the thermally conductive pad comprises a double-sided tape and a copper foil provided on an upper surface of the double-sided tape.

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