KR100847756B1 - System for collecting stench and oil mist - Google Patents

Abstract

A system for collecting odor and oil mist generated during the treatment of waste rolling oil is provided to reduce additional costs for replacing and repairing a drive unit, etc., create a pleasant and environmentally friendly atmosphere in a workplace and a surrounding place, separate large particles through a demister, enable the dust collecting part to be used continuously without frequent maintenance, and easily maintain, repair, and exchange a chemical media-filling housing. A system for collecting odor and oil mist generated during the treatment of waste rolling oil comprises: a housing(10) including an inlet(12) and an outlet(14), and a continuous passage for connecting the inlet and the outlet; a pre-treatment filter(20) arranged in rear of the inlet of the housing; a dust collecting part(30) including an ionizer(32), a collecting cell(34), and an automatic cleaning system arranged in rear of the pre-treatment filter to collect oil mist; a chemical media housing module(40) arranged in rear of the dust collecting part to adsorb harmful substances and remove mixed odor; a post-treatment filter(50) arranged in rear of the chemical media housing module; an exhaust fan(60) installed in rear of the post-treatment filter; and a damper(70) installed on the outlet. Further, the collecting cell contains a body and a dust collecting plate for dividing the body.

Description

Odor and Oil Mist Collection System during Waste Rolled Oil Processing {SYSTEM FOR COLLECTING STENCH AND OIL MIST}

The present invention relates to a system for collecting malodor and oil mist generated during waste rolling oil treatment, in particular, vegetable oils and cooling water, which are rolling oils used for cooling coils during cold rolling, must be separated from oil and water for treatment after use. When the waste rolled oil is heated to about 70 ~ 80 ℃ in the waste rolled oil storage tank, the waste water is settled to the bottom of the storage tank and the waste oil is separated into a scum having a low specific gravity and floated on the upper part of the storage tank. After the treatment, the wastewater is moved to a wastewater treatment plant and treated according to environmental standards.

During the heating process for oil and oil separation, a large amount of oil mist, various harmful gases, corrosive gases, and acid gases are generated in the waste rolling oil storage tank, and the oil mist is attached to buildings and machines near the waste oil storage tank. In addition, it is attached to the impeller of the driving equipment such as the compressor, etc., causing eccentricity in the center of gravity and acting as a cause of failure of the driving equipment, thereby increasing the additional cost and reducing the productivity for the replacement of such driving equipment. Problems and high concentrations of volatile organic solvent (VOCs) gas, hydrogen sulfide (H ₂ S) gas and mixed odors are harmful to the human body and cause unpleasant and allergic conditions. To fundamentally eliminate the problem of deterioration,

By introducing a fine dust collector including a high-performance ionizer and a collecting cell to remove oil mist, it reduces additional economic losses for replacement and repair of drive equipment,

In addition, to collect various harmful gases, corrosive gases and acid gases, chemical media housings are installed in three stage modules to oxidize, neutralize, absorb and adsorb by properties (acid gas, alkali gas, neutral gas). By eliminating gas, corrosive gas and acid gas, it is possible to guarantee a pleasant and eco-friendly atmosphere in the workplace and surrounding areas.

Furthermore, a demister for pretreatment filter is installed at the front of the dust collector to separate the large particles to support the system so that the odor and oil mist collection system can be operated unattended continuously with maintenance free throughout the year. An automatic cleaning system that periodically sprays emulsifiers on the lecturing cell is attached for continuous use without frequent maintenance of the dust collector.

In addition, the present invention relates to a odor and oil mist collection system generated during the processing of waste rolling oil, which can modularize the housing filled with chemical media to ensure ease of maintenance, repair and replacement.

Until now, oil mist, various harmful gases, corrosive gases, and acid gases were all uniformly regulated to regulate the emission of air, and as the economic growth of the industry has advanced, odor pollution is treated as a serious sensory pollution. As various complaints related to odor caused by harmful gas, corrosive gas and acid gas continue to increase, Gumi established the odor prevention law as the earliest in the case of Gumi, and managed odors in neighboring Japan, the United States, and Singapore for more than 20 years. Korea has been enacting legislation for the odors that were managed under the law since 2005, and since 2006, they are paying more attention to proactively dealing with odor pollution.

In particular, among the odor-causing substances generated in the workplace adjacent to the waste rolling oil treatment facility used for cooling the coil during cold rolling and the surrounding environment, SOx, NOx, formaldehyde, HS ₂ , O ₃ , VOCs, various food spoilage, single cell spores The main cause is the gas caused by the extinction of bacteria (odor bacteria), and the immediate symptoms caused by these substances are headaches and nausea,

In addition, oil mist generated from waste oil treatment facilities and various oils and dusts containing various heavy metals (Cr, Ni, Cu, Pb, and Mn) are also pointed out as main or auxiliary causes of various diseases including respiratory diseases. Efforts have been made in developing technologies to remove these contaminants.

Conventional air purifying apparatus for this purpose is registered utility model No. 20-0413052 (registered on March 28, 2006) registered by Utility Model Rights No. "Air Purifier" is a fine water droplets that are dispersed air contaminated with various substances Water is sprayed onto a multi-layer water tank so that fine water droplets can be formed to purify the air and to purify the air, and the contaminated air passes through the water to recover the purified air by mixing and absorbing water droplets. Air purifier is disclosed,

Such air purifiers have limitations to completely remove and collect harmful substances and oil mists that cause malodors, and thus, there is an urgent need for development of odor and oil mist collecting systems using more advanced technology.

The present invention has been made to solve the above problems,

In particular, the vegetable oil and the cooling water, which are the rolling oil used for cooling the coil during cold rolling, should be separated into oil and water for the treatment after use.In this case, when the waste rolled oil is heated to about 70 to 80 ° C. in a separate waste oil storage tank, the waste water is The sediment is deposited to the bottom and the waste oil is separated into a scum which has a low specific gravity and is suspended in the upper part of the reservoir. At this time, the scum is processed through a heating process in an incinerator, and the waste water is moved to a wastewater treatment plant and treated according to environmental standards. During the heating process for oil-water separation, a large amount of oil mist, various harmful gases, corrosive gases and acid gases are generated in the waste rolling oil storage tank, and the oil mist is attached to buildings and machines near the waste oil storage tank. In addition, it is attached to the impeller of the driving equipment such as the compressor, etc., causing eccentricity in the center of gravity and acting as a cause of failure of the driving equipment, thereby increasing the additional cost and reducing the productivity for the replacement of such driving equipment. Problems and the high concentration of volatile organic solvents (VOCs) gas, hydrogen sulfide (H ₂ S) gas and mixed odors are harmful to the human body and cause unpleasant feelings and allergies. To fundamentally eliminate the problem of degrading

By introducing a fine dust collector including a high-performance ionizer and a collecting cell to remove oil mist, it reduces additional economic losses for replacement and repair of drive equipment,

In addition, to collect various harmful gases, corrosive gases and acid gases, chemical media housings are installed in three stage modules to oxidize, neutralize, absorb and adsorb by properties (acid gas, alkali gas, neutral gas). It is an object of the present invention to provide a odor and oil mist collection system generated during the treatment of waste rolling oil which can ensure the composition of a pleasant and environmentally friendly atmosphere in the workplace and surrounding places by removing gas, corrosive gas and acid gas.

Furthermore, a demister for pretreatment filter is installed at the front of the dust collector to separate the large particles to support the system so that the odor and oil mist collection system can be operated unattended continuously with maintenance free throughout the year. Another object of the present invention is to provide an odor and oil mist collection system generated during the treatment of waste rolling oil which can be continuously used without frequent maintenance of the dust collector by attaching an automatic cleaning system for periodically spraying an emulsifier on the lecting cell.

In addition, it is another object of the present invention to provide a system for collecting malodor and oil mist generated during the processing of waste rolling oil that can be modularized the housing filled with the chemical media to ensure ease of maintenance, repair and replacement.

Odor and oil mist collection system generated during the treatment of waste rolling oil according to the present invention,

An enclosure having an inlet and an outlet and a continuous passage connecting the inlet and the outlet; A pretreatment filter arranged behind the enclosure inlet; A dust collecting unit arranged behind the pretreatment filter and including an ionizer, a collecting cell, and an automatic cleaning system for collecting oil mist; It is arranged behind the dust collection unit, the chemical media housing module for the adsorption of harmful substances and deodorization of the complex odor; A post-treatment filter arranged behind the chemical median housing module; An exhaust fan provided behind the post-treatment filter; And a damper provided at the discharge port.

The dust collecting part collecting cell may include a body and a dust collecting plate partitioning the body, wherein the dust collecting plate is formed in an uneven shape.

In addition, the chemical media housing module includes two support panels on both sides formed on two or more pairs of inclined guide portions facing each other in a zigzag form; A plurality of porous panels inserted and fixed to the guide part of the support panel; A first cover covering the fabric of the pair of porous panels; And a second cover covering a near end of the porous panel pair and connecting two adjacent accommodation spaces among the accommodation spaces formed between the pair of porous panels, the second cover having a closing member for the input hole. It is made, including

The inner two panels of the pair of processing panels interconnected with the receiving space are spaced apart from each other, and adjacent ends of the two panels are connected by a connecting member.

More preferably, adjacent ends of two inner panels of the porous panel pair to which the accommodation spaces are interconnected are in contact with each other.

Furthermore, an outer edge of the support panel is formed, and the first and second covers are positioned between the edge and the porous panel.

Preferably, the first and second cover and the support panel is characterized in that the reinforcement by the combination of the female member and the male member provided in each.

In addition, the guide portion of the support panel is formed by a strip, the strip is formed with a projection, the porous panel is characterized in that the fitting hole is formed is coupled to the projection,

Preferably, the projection of the strip is characterized in that the wedge shape to ensure the ease of coupling of the porous panel.

By the odor and oil mist collection system generated in the treatment of waste rolling oil according to the present invention, vegetable oil and cooling water, which are rolling oils used for cooling of coils, in particular during cold rolling, should be oil-water-separated for post-treatment. When the waste rolled oil is heated to about 70 ~ 80 ℃ in the waste rolled oil storage tank, the waste water is settled to the bottom of the storage tank and the waste oil is separated into a scum having a low specific gravity and floated on the upper part of the storage tank. After the treatment, the wastewater is moved to a wastewater treatment plant and treated according to environmental standards.

During the heating process for oil-water separation, a large amount of oil mist, various harmful gases, corrosive gases and acid gases are generated in the waste rolling oil storage tank, and the oil mist is attached to buildings and machines near the waste oil storage tank. In addition, it is attached to the impeller of the driving equipment such as the compressor, etc., causing eccentricity in the center of gravity and acting as a cause of failure of the driving equipment, thereby increasing the additional cost and reducing the productivity for the replacement of such driving equipment. Problems and high concentrations of volatile organic solvent (VOCs) gas, hydrogen disulfide (H ₂ S) gas, and mixed odors are harmful to the human body and cause unpleasant and allergic conditions. To fundamentally eliminate the problem of deterioration,

By eliminating oil mist by introducing fine dust collector including high-performance ionizer and collecting cell, it is possible to reduce additional economic loss for replacement and repair of driving equipment, and to remove various harmful gases, corrosive gases and acid gases. Chemical media for oxidizing, neutralizing, absorbing and adsorbing by properties (acidic acid, alkali gas, neutral gas) is installed as a three-stage module to remove various harmful, corrosive and acidic gases. Demister for pre-treatment filter in front of dust collector to support the system to ensure a pleasant and eco-friendly atmosphere, and furthermore, to support the system for continuous operation of the odor and oil mist collection system year-round with minimum maintenance. (demister) is installed to separate large particles and emulsifying the collecting cell It is expected to be equipped with an automatic cleaning system that automatically sprays miracles so that it can be used continuously without frequent maintenance of the dust collecting unit, and the housing that is filled with chemical media can be modularized to ensure ease of maintenance, repair and replacement.

Furthermore, various types of harmful gases, corrosive gases and acid gases generated in the workplace adjacent to the waste rolling oil treatment facility used for cooling the coil during cold rolling, and the surrounding environment are removed by properties (acid gas, alkali gas, neutral gas). The housing module filled with various types of chemical media in the shape of pellets can be used as a unit to stack and arrange various combinations of housing modules required according to the environmental conditions in the workplace and the density of harmful substances. In addition, the accommodating spaces filled with various chemical media in the shape of pellets are interconnected to secure an expanded accommodating space and to reduce materials, and the two inner panels of the porous panel pair are spaced apart from each other and connected by a connecting member. Adjacent ends of the two panels can be brought into direct contact with each other. It is possible to increase the precision to ensure a reliable coupling force to each component of the housing module, and at the same time to increase the ease of assembly when assembling each component constituting the housing module, so that it is easy to assemble and maintain the robustness after assembling, and When the filling member is opened and closed, the coupling member connected to the opening / closing protrusion and the opening / closing protrusion formed with plate-shaped bent portions elastically supporting both ends of each opening is formed at both ends of the closing member which is opened and closed when filling and refilling the pellet-shaped chemical media. It is expected to facilitate the filling and replacement of chemical media.

Hereinafter, with reference to the accompanying drawings, the odor and oil mist collection system generated during the processing of the waste rolling oil according to the present invention,

In each of the drawings, the same reference numerals, in particular, the tens and ones digits, or the same digits, tens, ones, and alphabets refer to members having the same function, and unless otherwise specified, each reference in the drawings. The member referred to may be regarded as a member conforming to these criteria.

In addition, in describing the odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention, if the approximate direction is specified with reference to FIG. 1, the inside and the outside of the enclosure 10 may be determined, and the inflow and outflow of outside air may be determined. Set the inlet 12 side forward and the outlet 14 side rearward along the path.

1 is a perspective view showing a odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention,

Figure 2 is a schematic cross-sectional view showing a odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention,

3 is an exploded view showing a housing module for the chemical media according to the present invention;

Figure 4 is a perspective view showing a first cover of the chemical media housing module according to the present invention,

Figure 5 is a perspective view showing a second cover of the chemical media housing module according to the present invention,

6 to 8 are a perspective view and a coupling diagram showing the coupling of the support panel and the porous panel by the connecting member of the chemical media housing module according to the present invention,

9 to 11 are a perspective view and a coupling diagram showing the coupling of the support panel and the porous panel not by the connecting member of the chemical media housing module according to the present invention,

12 to 14 is a perspective view and a combination view showing another coupling example of the support panel and the porous panel not by the connection member of the housing module for the chemical media according to the present invention;

Figure 15 is a perspective view showing a holder laminated with a chemical media housing module according to the present invention.

As illustrated in FIGS. 1 to 3, the odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention is

An enclosure 10 having an inlet 12 and an outlet 14, and a continuous passage P connecting the inlet 12 and the outlet 14; A pretreatment filter (20) arranged behind the enclosure (10) inlet (12); Dust collectors arranged respectively behind the pretreatment filter 20 and including an ionizer 32 for collecting oil mist, a collecting cell 34 and an automatic cleaning system (not shown). 30); It is arranged at the rear of the dust collecting unit 30, the chemical media housing module 40 for adsorption of harmful substances and deodorization of the compound odor; A post-processing filter 50 arranged behind the chemical medial housing module 40; An exhaust fan 60 provided in the room after the post-treatment filter 50; And a damper 70 provided at the outlet 14.

In the present specification, the odor and oil mist collecting system includes odors, oils and various types of harmful gases, corrosive gases, acidic gases, etc. generated from waste rolled oil treatment plants, wastewater treatment plants, food waste treatment and recycling plants, sludge treatment plants, and the like. It is a concept that includes a collection system and equipment that can be installed in every place that occurs.

1 and 2, in the odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention, the housing 10 is

Drying process of rolling oil and vegetable oil used for cold rolling as waste oil is heated to a certain temperature in the oil-water separation tank and separated into water and scum, and the water is treated in waste water treatment plant and scum is incinerated. The inlet 12 through which the odor and oil mist generated in the air flows in and the outlet 14 through which the purified air is supplied through the odor and oil mist collecting system of the present invention are arranged in front and rear, respectively.

The enclosure 10 is formed with a continuous passage P connecting the inlet 12 and the outlet 14.

It is preferable that the inlet 12 of the enclosure 10 is provided with a sieve 12a having a suction hole of a degree provided in a conventional air conditioner inlet so as to filter out large foreign matters and to wash with water if necessary.

The exhaust fan 60 is provided in front of the discharge port 14 of the enclosure 10, and the exhaust fan 60 reflects a sufficient static pressure to create a hydraulic pressure of about 25 Pa in the partition installed in the separation tank to produce a bad smell or oil. The mist can be prevented from spreading to the outside and affecting people and various driving devices in advance, and the air purified by the exhaust fan 60 is damper arranged at the outlet 14 of the enclosure 10. (70) is discharged through, and in this case, the exhaust volume can be adjusted by the exhaust fan (60) and the damper (10), the damper (70) is also arranged in the inlet (12) as necessary for the intake air volume control Can be.

The continuous passage P connecting the inlet 12 and the outlet 14 of the enclosure 10 has a pretreatment filter 20, ionizer 32, collecting cell 34 and automatic cleaning which will be described below. A dust collecting unit 30 including a system (not shown), a plurality of chemical media housing modules 40, a post-treatment filter 50, an exhaust fan 60, and a damper 70.

The partition D for the above components is formed to accommodate them more efficiently.

The dust collecting unit 30 includes a pretreatment filter 20, an ionizer 32, a collecting cell 34, and an automatic cleaning system (not shown) arranged on the side of the enclosure 10, respectively. ), A plurality of chemical media housing module 40, the post-treatment filter 50, the exhaust fan 60 and the damper 70, the door (D) is formed for easy and convenient replacement, repair and repair And

The door 16 has a door lock (16a) is provided with a handle (16b) on one side,

The hinge 16c is connected to the other side to open and close the door 16 of the enclosure 10.

In addition, an analog or digital pressure gauge 18a is provided at the outside of the enclosure 10, that is, at one side of the door 16 to determine whether the pressure inside the enclosure 10 is within a normal range. (10) a dust collecting part 30 including a pretreatment filter 20, an ionizer 32, a collecting cell 34, and an automatic cleaning system (not shown), each arranged inside, a plurality of chemical media housing modules ( 40), the control unit 18 is provided to check whether the replacement, maintenance and repair of the after-treatment filter 50, exhaust fan 60 and damper 70, and the like,

In addition, the control unit 18 enables automated filtering and sensing of chemical media exchange cycles through more precise intake and discharge air pollution sensoring, and an alarm function to notify the time of chemical media exchange and abnormal signals. It can be introduced in consideration of various control modes such as introduction.

1 and 2, in the malodorous and oil mist collecting system generated during the treatment of waste condensed milk according to the present invention, the pretreatment filter 20 and the aftertreatment filter 50 are

A pre-filter 20 which is a macro filter (not shown) arranged adjacent to the rear of the enclosure 10 inlet 12 and a meso filter (not shown) arranged immediately after it;

In addition, a post-treatment filter 50, which is a micro filter (not shown), is arranged at the rear of the chemical median housing module 40.

Therefore, the pretreatment filter 20 is a filter having a collection efficiency of more than 90% colorimetric method, the macro filter (not shown) removes particulate matter and foreign matter contained in the outside air, the meso filter (not shown) to the air in the workplace Remove the floating dust, etc.

More preferably, a demister is installed in front of the dust collecting part 30 for the pretreatment filter 20 so that the large particles can be separated, so that the unmanned operation can be continued year round with minimal maintenance.

In addition, various dusts and heavy metal substances which should not be introduced into the workplace into a micro filter (not shown) having a collection efficiency of about 0.3 μm, which is about 0.3 μm, which is the post-treatment filter 50, and fine dust generated from media. The HEPA (High Efficiency Particulate Arrestor) filter may be employed if necessary.

1 and 2, in the odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention, the dust collecting part 30 is

It comprises an ionizer (32), an automatic cleaning system (not shown), and a collecting cell (34), which are arranged behind the pretreatment filter 20 to collect oil mist,

The dust collector 30, the ionizer 32 is

The main body 32a is preferably made of aluminum, and the discharge wire 32b for neutralizing and discharging the charged electrostatic particles contained in the workplace by discharging a high voltage uses tungsten wire having elastic strength and corrosion resistance. ,

Both ends of the discharge line are made of special terminals, and the horizontal support 32c and the spring 32d are connected to each other. In case of emergency, it can be replaced immediately for quick maintenance and repair.

In addition, the dust collecting unit 30, the collecting cell 34

To collect the oil mist more than 99.9% to protect the housing housing for the chemical media, and to adhere to the drive device such as a compressor (compressor) or fan in the workplace to block the cause of the failure of the device,

The collecting cell 34 comprises a body 34a and a dust collecting plate 34b for partitioning the body,

The dust collecting plate 34b is formed in a concave-convex shape to further increase the collection efficiency by adjusting the air flow, and also serves to prevent the dust collected from flying away.

Furthermore, the automatic cleaning system 36 is arranged in front of the dust collecting part 30 and the collecting cell 34.

The automatic cleaning system (not shown) is arranged in front of the collecting cell 34 and is automatically sprayed to the collecting cell 34 by ejecting water or an emulsifier to the collecting cell 34 at a jet pressure having a predetermined pressure or more. Systemized to clean various dusts, such as the oil mist is collected, to eliminate the inconvenience to maintain frequently the dust collecting part 30 including the collecting cell 34 in the prior art for separate maintenance and management It is possible to continuously drive the odor and oil mist collection systems of the present inventors without operation.

1 and 2, in the odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention, the chemical median housing module 40 is

Arranged immediately after the collector 30, the collecting cell 34, the housing module is filled with a chemical media for organic compound adsorption and deodorization of complex odors,

Looking at the types of the odor cause and the oil mist briefly before looking at the kind of pellet-shaped chemical media filled in the chemical media housing module 40,

1.Acid Vaper: H ₂ S, HCl, SOx, NOx

2. Alkaline gas (base): NH ₃ , amine gas, etc.

3. VOC gases (Volatile Organic Compounds): thinner, toluene, benzene, MEK, xylene, styrene, etc.

4. Corrosion gas of organic matter: It can be classified into various kinds of food decay, gas from single cell spores (odorous bacteria)

As chemical media for the adsorption of harmful substances that can be removed through the above-mentioned 99.9% or more of the gaseous harmful substances or by neutralization or oxidation, and the deodorization of complex odors,

First of all, chemical media for adsorption of harmful substances are mixed or impregnated with special additives to remove specific gas in the chemical matrix. Activated carbon is used as a base material, and zelite or silica is used as a mixture. It is preferable to use activated alumina (Al ₂ O ₃ ), which has a much stronger oxidation power than

In this case, the harmful and corrosive gases to be removed are roughly classified into acidic and alkaline gases.

If you want to remove the acid gas, in the case of strong acid, the neutralization reaction is mainly used to remove,

Strong by the case of the weak acid gas _{(NO, SO, NO 2,} SO 2 , and so on) the neutralization reaction is the reaction was speeds late addition efficiency is reduced because the primary reaction permanganate potassium (KMnO ₄₎ and active alumina (Al ₂ O ₃₎ The removal of gases by oxidizing power and auxiliary neutralization reaction ensures the reaction rate and efficiency,

Alkaline gases such as ammonia (NH ₃ ) and amine series are removed by neutralization using phosphate (H ₃ PO ₄ ).

Next, as chemical media for deodorization of complex odors, to remove 99% or more of sulfur compounds as well as complex odors through adsorption or neutralization and oxidation reactions.

In the first stage, chemical media containing calper permanganate (KMnO ₄ ), activated alumina (Al ₂ O ₃ ), and potassium hydroxide (KOH) are acidic gases (H ₂ S, HCl, O ₃ , SOx, NOx, aldehydes, etc.). Remove it,

In the second stage, mineral activated carbon is used to remove volatile organic compound (VOC) gas and gases that cause various odors generated from organic matter.

Accordingly, the chemical mediation housing module 40 is modularized into three stages by the characteristics of the noxious gas, that is, the acid gas 40a, the alkaline gas 40b, and the neutral gas (VOCs) 40c. Absorption and adsorption can be used to induce more efficient filtration.

Furthermore, the air filtered in the housing for the chemical median 40 further passes through a sterilization heater (not shown) arranged adjacent to the outlet 14 of the enclosure 10 so as to further eliminate odor causing substances. Is possible,

In particular, the sterilization heater (not shown) is preferably arranged behind the exhaust fan 60 to prevent damage to the fan by heat, and can also function as an auxiliary heat source in winter.

Hereinafter, the chemical media housing module 40 for filling the pellet-shaped chemical media as described above in more detail,

As shown in Figures 3 to 14 the chemical medial housing module 40 is

Two support panels 410 on both sides of the inclined guide portion 412 formed on two or more pairs of zigzag faces;

A plurality of porous panels 420 inserted into and fixed to the guide part 412 of the support panel 410;

A first cover 430 covering the fabric of the pair of porous panels 420; And

An inlet 442 is formed to cover the proximal end of the pair of porous panels 420, and connect two adjacent accommodation spaces S among the accommodation spaces S formed between the pair of porous panels 420. And a second cover 440 having a closing member 444 for the inlet 442.

Hereinafter, in the present specification, the housing module for chemical media refers to one unit, which may be used by stacking in multiple layers in consideration of the size and processing capacity of the collection system, and filled with different types of chemical media. The housing modules can be arranged in sequence,

Moreover, the specific direction reference mentioned above is still valid as it is.

As shown in FIG. 3, in the odor and oil mist collecting system generated during waste rolling oil treatment according to the present invention, the support panel 410 is for maintaining a skeleton of the chemical media housing module 40.

On both sides of each of the support panels 410, the inclined guide portion 412 is formed on the opposite surface in the form of two pairs or more zigzag,

The guide part 412 is formed to be inclined toward the front or the rear so that one end is adjacent, the other end is formed to be reversely opened so that the porous panel 420 is inserted and fixed.

In addition, the guide part 412 is formed with a strip 414 into which the porous panel 420 is inserted and fixed, and the strip 414 is formed in the shape of a segment to reduce the material inside or outside, or both. It is desirable to be,

In addition, a plurality of support pieces 414a are arranged at both sides of the strip 414 at regular intervals, and a taper is formed at an upper end of the support piece 414a so that the strip 414 is inserted and fixed to the porous panel 420. Will be guided correctly to

In addition, protrusions 414b are formed between the support pieces 414a arranged along the strip 414, and both sides of the porous panel 420 are inserted into fitting holes 420a formed corresponding to the protrusions 414b. To support the fixing of the support panel 410 and the porous panel 420 to ensure the firmness of the coupling,

Further, when the porous panel 420 is inserted into the strip 414 in the protrusion 414b of the strip 414, the protrusion 414b of the strip 414 is formed in the protrusion 414b of the porous panel 420. Make sure to fit the fitting hole (420a) without difficulty,

In addition, when the wedge-shaped protrusion 414b is coupled to the fitting hole 420a, one side (or both sides) of the tapered portions 420b are adjacent to the fitting hole 420a for easy coupling. Formed on,

In addition, it is possible to prevent the porous panel 420 from being separated from the inclined portion 412 strip 414 after the coupling.

As shown in FIG. 3, in the odor and oil mist collecting system generated during waste rolling oil treatment according to the present invention, the porous panel 420 is

The support panel 410 is inserted into and fixed to the guide part 412, and two porous panels 420 are inserted into and fixed to the pair of guide parts 412, so that at least four or more porous panels are supported to the support panel 410. 420 is arranged.

Therefore, an accommodation space S corresponding to the separation distance of the strip 414 of the guide portion 412 is formed between the porous panels 420 inserted into and fixed to the pair of guide portions 412. In the space S, a space in which the chemical media C is filled is formed.

3 and 4, in the odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention, the first cover 430 is

Covering the fabric of the pair of porous panels 420,

The first cover 430 connects an end portion of the porous panel 420 inserted into and fixed to the guide part 412,

In this case, the first cover 430 is formed so that the outer space formed by inserting and fixing the guide part 412 and the porous panel 420 forms an inlet part I or an outlet part O. The pair of porous panels 420 fixed to the pair of guide parts 412 may be formed to cover each.

In addition, the first cover 430 has a bent portion 430a formed at an upper end and a lower end thereof to surround the end of the porous panel 420, and close the porous panel 420 adjacent to each of the bent portions 430a. The receiving groove 430b for inserting and fixing is formed along the length direction, and the receiving protrusion 430c is preferably formed at a predetermined interval on the upper end of the receiving groove 430b to reduce material (but in this case, In the case where the receiving protrusion 430c is formed, the receiving groove 430b may be omitted in the molding process for manufacturing convenience and material saving.),

Receiving ribs 430d are formed in the upper or lower bent portion 430a or both of the receiving protrusions 430c to support the porous panel 420 being inserted and fixed, and the bent portion 430a. It is desirable to be molded to reduce the thickness of the material to reduce the material (but in this case, the receiving rib 440d can also be omitted in the molding process for the same reason as the receiving groove 440b).

3 and 5, in the odor and oil mist collecting system generated during the treatment of waste cold rolling according to the present invention, the second cover 440 is

An inlet 442 is formed to cover the proximal end of the pair of porous panels 420, and connect two adjacent accommodation spaces S among the accommodation spaces S formed between the pair of porous panels 420. Has a closing member 444 for the inlet 442,

The second cover 440 is formed such that each of the porous panels 420 inserted into and fixed to the two pairs of guide parts 412 covers adjacent ends thereof.

The second cover 440 has bent portions 440a formed at upper and lower ends thereof to surround the ends of the porous panel 420 and to insert the porous panels 420 adjacent to the respective bent portions 440a. Receiving groove 440b for fixing is formed along the longitudinal direction, the receiving projection 440c is preferably formed at a predetermined interval on the upper end of the receiving groove 440b to reduce the material (but in this case When the protrusion 440c is formed, the receiving groove 440b may be omitted in the molding process for the convenience of manufacturing and the reduction of the material.

Receiving ribs 440d are formed in the upper or lower bent portion 440a, or both in correspondence with the receiving protrusion 440c to support the porous panel 420 being inserted and fixed, and the bent portion 440a. It is preferable to be molded to reduce the thickness of the material to reduce the material. (In this case, however, the receiving rib 440d may also be omitted in the molding process for the same reason as the receiving groove 440b. Shown.)

In addition, the inlet 442 is formed in a plurality on the outer surface of the second cover 440 and connects two adjacent receiving spaces S between the receiving spaces S formed between the pair of porous panels 420. ,

Through the inlet 442 is filled with various kinds of chemical media (C),

Therefore, the closing member 444 is provided to block the inlet 442 in order to prevent the filled various kinds of chemical media (C) to the outside.

Furthermore, as shown in FIGS. 3 and 5, the inner side of the closing member 444 has a coupling protrusion 444a which is coupled to correspond to the inlet 442 formed in plurality, protruding from the upper portion of the inlet 442. And coupled to the bottom,

In this case, at the end of the coupling protrusion 444a, a locking step 444b provided with a taper is formed to prevent separation after coupling with ease of coupling.

In addition, the engaging hole 442a is protruded from both ends of the inner surface of the inlet 442,

In addition, on both sides of the inner side of the closing member 444, an opening and closing protrusion 444c having a plate-shaped bent portion 444d coupled to the engaging hole 442a of the inlet 442 and supporting the elastic member 444c is formed to form a chemical media (C). The filling and replacement of the inlet 442 is formed so that it can be easily opened and closed.

And the coupling tip connected to the end of the opening and closing projections (444c) bent portion (444d) in order to prevent the inconvenience of opening by using other auxiliary equipment to open the closing member 444 coupled to the inlet 442 ( 444e) is exposed to the outside of the inlet 442,

By pressing each of the coupling tips 444e, the closing member 444 is easily separated from the locking hole 442a of the inlet 442 so that the inlet 442 can be opened.

6 to 8, the inner two panels of the pair of porous panels 420 to which the accommodation space S is interconnected are spaced apart from each other, and adjacent ends of the two panels are connected by a connecting member 446. Connected,

The connecting member 446 is arranged behind the second cover 440 and connects adjacent ends of two inner panels of the porous panel 420 pair,

In addition, bending portions 446a are formed at upper and lower ends of the connection member 446 to surround the ends of the porous panels 420, and to insert and fix the porous panels 420 adjacent to each of the bending portions 446a. The receiving groove 446b is formed along the longitudinal direction, and the receiving protrusion 446c is preferably formed at a predetermined interval on the top of the receiving groove 446b to reduce material (but in this case, the receiving protrusion ( When 446c) is formed, the receiving groove 446b is found to be omitted in the molding process for manufacturing convenience and material saving.),

Receiving ribs 446d are formed in the upper or lower bent portion 446a or both in correspondence with the receiving protrusion 446c to support the porous panel 420 being inserted and fixed, and the bent portion 446a. It is desirable to be molded to reduce the thickness of the material to save the material.

9 to 14 by connecting adjacent ends of two inner panels of the pair of porous panels 420 without the connecting member 446,

As shown in FIGS. 9 to 11, adjacent ends of two inner panels of the pair of porous panels 420 in which the accommodation spaces S are interconnected are formed to be in contact with each other (of course, the support panel corresponding thereto). Ends of the guide portion 412 of the 410 is also formed to abut each other.),

12 and 14, adjacent ends of two inner panels of the pair of porous panels 420 connected to the receiving space S are formed to be in contact with each other.

Adjacent ends of the inner two panels of the pair of porous panels 420 are bent to abut each other (of course, the ends of the guide portions 412 of the supporting panel 410 are formed to be spaced apart from each other).

The two panels are connected without the connecting member 446. In this case, as shown in FIGS. 9 to 14, the two panels are integrally formed, or the two panels are connected to each other but not shown in the accompanying drawings. By sealing it can prevent the outside air is discharged directly to the outside without passing through the receiving space (S),

In addition, it is expected that the connection member 446 may be unnecessary, thereby increasing productivity by reducing material costs and production processes.

As shown in FIG. 6, an edge 416 is formed at an outer side of the support panel 410, and the first and second covers 430 and 440 are formed at the edge 416 and the porous panel 420. ) Is located between

The first and second covers 430, 440, the edge 416, and the porous panel 420 are coupled to support mutual coupling so that the housing for the chemical median housing module 40 is more firmly maintained. Can be guaranteed.

As shown in FIG. 3, the first and second covers 430 and 440 and the support panel 410 are reinforced by the combination of the female member 448 and the male member 418 provided therein.

The female member 448 protrudes with coupling holes formed at both inner ends of the first and second covers 430 and 440, and the male member 418 is provided with the female member 448 inside the support panel 410. It is formed in a projection shape at the corresponding position of the) is coupled to each, thereby ensuring that the coupling of the first and second cover 430, 440 and the support panel 410 is further reinforced,

In addition, the female member 448 is preferably formed at both ends of the inner side of the connection member 446. The male member 418 is also disposed at the corresponding position of the female member 448 in the support panel 410. This can be formed to achieve the same effect.

Furthermore, as shown in FIGS. 4 and 5, insertion holes 430e and 440e are formed at both ends of the first and second covers 430 and 440, respectively, and the edge of the support panel 410 is provided. 416, a wedge-shaped insertion protrusion 416a corresponding to the insertion holes 430e and 440e is formed at an upper portion, and further, the insertion protrusion 416a is located near the insertion holes 430e and 440e. Tapered portions (430f) (440f) are formed to facilitate the coupling when the coupling is easy to ensure the coupling, and can prevent the chemical media housing module 40 from being separated after the coupling.

On the other hand, the chemical media housing module 40 means one unit as described above, and can be used by stacking a plurality according to environmental conditions for installing the same. For this purpose, each support panel 410 has a fixing groove ( 419) is formed to stack the housing module for each chemical media and can be connected and fixed with a fixing bar (not shown) to fix the fixing groove (419),

In addition, the housing module filled with different types of chemical media can be configured to properly purify and collect various acid and corrosive gases and oil mist contained in the air in the workplace by properly placing the holder (H) stacked sequentially.

In addition, the space formed by the porous panel zigzag-inserted and fixed to the housing for the chemical media can serve as an inlet or outlet regardless of the front-rear direction, thereby providing convenience that can be used regardless of the direction. .

In the above description of the odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention with reference to the accompanying drawings, the present invention has been described with a particular shape and direction, but various modifications and changes can be made by those skilled in the art. Modifications and variations should be construed as being included in the scope of the present invention.

1 is a perspective view showing a odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention,

Figure 2 is a schematic cross-sectional view showing a odor and oil mist collecting system generated during the treatment of waste rolling oil according to the present invention,

3 is an exploded view showing a housing module for the chemical media according to the present invention;

Figure 4 is a perspective view showing a first cover of the chemical media housing module according to the present invention,

Figure 5 is a perspective view showing a second cover of the chemical media housing module according to the present invention,

6 to 8 are a perspective view and a coupling diagram showing the coupling of the support panel and the porous panel by the connecting member of the chemical media housing module according to the present invention,

9 to 11 are a perspective view and a coupling diagram showing the coupling of the support panel and the porous panel not by the connecting member of the chemical media housing module according to the present invention,

12 to 14 is a perspective view and a combination view showing another coupling example of the support panel and the porous panel not by the connection member of the housing module for the chemical media according to the present invention;

Figure 15 is a perspective view showing a holder laminated with a chemical media housing module according to the present invention.

<Explanation of Signs of Major Parts of Drawings>

C: chemical media D: compartment

P: passage S: accommodation space

H: Holder with laminated housing module for chemical media

10: enclosure 12: inlet

14 outlet 16 door

16a: door lock 16b: handle

16c: hinge 18: control unit

18a: pressure gauge 20: pretreatment filter

30: dust collector 32: ionizer

32a: main body 32b: discharge line

32c: support 32d: spring

34: collecting cell 34a: body

34b: dust collecting plate

40: housing module for chemical media

40a: Housing module for acid gas

40b: Housing module for alkaline gas

40c: housing module for neutral gas (VOCs)

50: post-processing filter 60: exhaust fan

70: damper 410: support panel

412: guide portion 414: strip

414a: support piece 414b: protrusion

416: rim 416a: insertion protrusion

418: male member 420: porous panel

420a: fitting hole 430: first cover

440: 2nd cover 430a, 440a: bend part

430b, 440b: receiving groove 430c, 440c: receiving projection

430d, 440d: Receiving rib 430e, 440e: Insertion hole

442: inlet 442a: hook hole

444: closing member 444a: engaging projection

444b: locking jaw 444c: opening and closing protrusion

444d: bend 444e: coupling tip

446 connection member 448 arm member

Claims (9)

An enclosure having an inlet and an outlet and a continuous passage connecting the inlet and the outlet; A pretreatment filter arranged behind the enclosure inlet; A dust collecting unit arranged behind the pretreatment filter and including an ionizer, a collecting cell, and an automatic cleaning system for collecting oil mist; It is arranged behind the dust collection unit, the chemical media housing module for the adsorption of harmful substances and deodorization of the complex odor; A post-treatment filter arranged behind the chemical median housing module; An exhaust fan provided behind the post-treatment filter; And Odor and oil mist collection system generated during the processing of the waste rolling oil made comprising; a damper provided in the discharge port. The method of claim 1, wherein the dust collector collecting cell Body, It comprises a dust collecting plate for partitioning the body, The dust collecting plate is formed in an uneven shape odor and oil mist collection system generated during the treatment of waste rolling oil. The housing module of claim 1, wherein Two support panels on both sides formed on two or more pairs of inclined guide parts facing each other in a zigzag form; A plurality of porous panels inserted and fixed to the guide part of the support panel; A first cover covering the fabric of the pair of porous panels; And A second cover covering a proximal end of the pair of porous panels and connecting two adjacent accommodation spaces among the accommodation spaces formed between the pair of porous panels, the second cover having a closing member for the insertion hole; Odor and oil mist collection system generated during the treatment of waste rolling oil, including. The method of claim 3, wherein The inner two panels of the processing panel pair interconnected with the receiving space are spaced apart from each other, Adjacent ends of the two panels are connected by connecting members. Odor and oil mist collection system generated during the processing of waste rolling oil. The method of claim 3, wherein Odor and oil mist collection system generated during the processing of the waste rolling oil, characterized in that the adjacent ends of the two inner panels of the porous panel pair is connected to each other the receiving space. The method according to any one of claims 3 to 5, Odor is formed on the outer periphery of the support panel, the first and second cover odor and oil mist collection system generated during the processing of waste rolling oil, characterized in that located between the edge and the porous panel. The method of claim 6, The first and second covers and the support panel are odor and oil mist collection system generated during the treatment of waste rolling oil, characterized in that the reinforcement by the combination of the female member and the male member provided in each. The method according to any one of claims 3 to 5, The guide portion of the support panel is formed by a strip, the strip is formed with a projection, The porous panel is a bad smell and oil mist collection system generated during the processing of the waste rolling oil, characterized in that the fitting hole is formed is coupled to the projection. The method of claim 8, The projection of the strip is wedge-shaped odor and oil mist collection system generated during the processing of the waste rolling oil, characterized in that to ensure the ease of bonding of the porous panel.

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