KR200266999Y1 - A carbonizing treating appartus for waste matter - Google Patents

Abstract

The present invention relates to a carbonization apparatus using a far-infrared heater,

The object of the present invention is to provide a method and apparatus for reducing the temperature rise time required for carbonization according to a direct heating method using a far infrared ray cartridge heater and to prevent unnecessary power loss by shortening the temperature rise time, Another object of the present invention is to provide a device for rapidly cooling a carbonization vessel by a heat cooling apparatus and capable of easily carrying out a discharge operation of a carbide, The present invention provides a carbonization apparatus using a far infrared ray heater that effectively prevents various harmful gases and odors generated during carbonization through the means, thereby preventing serious air pollution problems.

Therefore, as a concrete means of the present invention for achieving the above object,

A main body case having a structure in which an opening and closing door is formed on one side, a far infrared ray heater and a carbonization container are provided inside, and an inner wall surface is made of a heat insulating brick;

A catalytic heater, a catalyst foreign substance removing heater, a first catalyst, a second catalyst, a third catalyst, a fourth catalyst, a fifth catalyst, and a catalyst automatic temperature sensor A shroud segment which is a catalytic thermal insulation of the tubular structure;

An air tank in which a plurality of gas convection preventing plates are provided in the inside of the air tank,

An auxiliary filtration device having a basic activated carbon, an acidic activated carbon, and a neutral activated carbon as a structure for heating the air tank and the piping;

A vacuum pump having a bubble generating tube on one side thereof and having an additional connection with an ozone generator having a separate structure;

A water tank for introducing a bubble generating tube of the vacuum pump, the water tank having a gas discharge hole at an upper side thereof;

This is accomplished by having the electronic control panel device as the control means for controlling the series of component operating relationships.

Description

[0001] CARBONIZING TREATING APPARATUS FOR WASTE MATTER [0002]

The present invention relates to a carbonization apparatus using far-infrared rays, and more particularly, to a carbonization apparatus using far-infrared rays, more specifically, a direct heating method using far-infrared radiation heat to raise the carbonization efficiency and shorten the working time by rapid carbonization heat cooling processing function, The present invention relates to a carbonization apparatus using far-infrared rays that can easily remove various harmful gases, odors, and the like emitted.

Generally, various kinds of garbage (wastes excluding metal and wood) discharged from a home, a restaurant or an industrial site, a ship or a hospital are collected by a standardized standard bag or the like and are transported and buried in a landfill or the like. In addition to polluting the soil and water quality as well as requiring a wide space for landfill, the waste disposal method has a problem in that it can not cope with the ever increasing amount of waste, It is also expanding to serious social problems.

In recent years, there has been widely solved the problems of the conventional waste disposal method as described above, and a carbonization apparatus for heating various garbage discharged from a home, a restaurant, or an industrial site under an oxygen- It is true.

However, in general, a common waste refractory apparatus is provided with indirect heat heating by means of a heater incorporated in a carbonization vessel, which causes a problem of unnecessarily consuming a temperature rise time for carbonization However, this unnecessary increase in the temperature rise time causes excessive power loss, which is a very inefficient use problem.

In addition, since the conventional garbage charger does not have a separate cooling device for discharging the carbonized material from the carbonized container after the carbonizing operation is completed, But also caused a considerable structural deficiency that would severely reduce the operating efficiency of this working hour standby.

On the other hand, the conventional garbage charger does not effectively remove various harmful gases and odors generated during the carbonization operation and thus acts as a cause of air pollution. In addition, due to the cause of such air pollution, And a problem of deterioration of practicality which can not be widely recommended or supplied.

Therefore, the present invention has been made to solve the general problems of the conventional waste charring apparatuses;

The object of the present invention is to shorten the temperature rise time necessary for the carbonization operation by direct heating method using the far infrared ray cartridge heater and to prevent the unnecessary power loss as the shortening of the temperature rise time, And a carbonization apparatus using a far-infrared heater.

Another object of the present invention is to provide a cooling device for rapidly cooling a carbonization vessel by a heat cooling device,

The present invention provides a carbonization apparatus using a far infrared ray heater which can prevent a serious air pollution problem by effectively removing various harmful gases and odors generated during carbonization through filtration means having a plurality of stages.

In order to achieve the above object, the present invention provides a method of manufacturing a semiconductor device,

A main body case having a structure in which an opening and closing door is formed on one side, a far infrared ray heater and a carbonization container are provided inside, and an inner wall surface is made of a heat insulating brick;

A catalytic heater, a catalyst foreign substance removing heater, a first catalyst, a second catalyst, a third catalyst, a fourth catalyst, a fifth catalyst, and a catalyst automatic temperature sensor A shroud segment which is a catalytic thermal insulation of the tubular structure;

An air tank in which a plurality of gas convection preventing plates are provided in the inside of the air tank,

An auxiliary filtration device having a basic activated carbon, an acidic activated carbon, and a neutral activated carbon as a structure for heating the air tank and the piping;

A vacuum pump having a bubble generating tube on one side thereof and having an additional connection with an ozone generator having a separate structure;

A water tank for introducing a bubble generating tube of the vacuum pump, the water tank having a gas discharge hole at an upper side thereof;

This is accomplished by having the electronic control panel device as the control means for controlling the series of component operating relationships.

1 is a system configuration diagram of a carbonization apparatus using a far-infrared heater according to the present invention

Fig. 2 is an enlarged cross-sectional view of the main part of the main body case applied to the present invention

Fig. 3 is an operating circuit diagram of a carbonization apparatus using a far-infrared heater according to the present invention

Description of Reference Numerals for Main Parts of Drawings

1: body case 11: far-infrared heater 12: carbonized container

2: shrinking portion of catalyst insulation 3: air tank 4: auxiliary filtering device

5: ozone generator 6: vacuum pump 7: water tank

8: Electronic control panel device.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a carbonization apparatus using a far infrared ray heater according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a system configuration diagram of a carbonization apparatus using a far-infrared heater according to the present invention, FIG. 2 is an enlarged cross-sectional view of a main part of a main body case applied to the present invention, FIG. 3 is an exploded perspective view of a carbonization apparatus using the far- As a circuit diagram, a series of configurations will be described.

An air tank 3, an auxiliary filtration unit 4, and an ozone generator 5 (hereinafter referred to as " ozone generator ") 5, a body case 1 housing the far infrared heater 11 and the carbonization vessel 12, , A vacuum pump (6), and a water tank (7), and an electronic control panel device (8) for operating and controlling the series of constituent parts.

1 and 2, the main body case 1 is formed with a hinged opening / closing door D of the same type as that of a refrigerator door on one side thereof, and has a rectangular shape And the inner wall surface of the enclosure is constituted by the heat insulating bricks 13. The structure of such a body case 1 is connected to the inside thereof. A cooling fan 14 which is operated by a carburetion temperature sensor (not shown) and a driving motor M is formed on the upper surface of the upper portion and a solenoid valve S is provided on the other side, which is symmetrical with the cooling fan 14, And an air blowing inlet 15 for blowing air.

The far infrared ray heater 11 installed inside the main body case 1 is formed by injecting 100% of ceramic alumina (AL203) having high thermal conductivity into a highly durable stainless steel pipe and then inserting hot wire (not shown) Infrared rays are applied to the outer surface of the far infrared ray heater 11, that is, the outer surface of the stainless tube thus constructed, is coated with a far infrared ray paint which can be used at a high temperature (1200 DEG C) It is preferable to form the far infrared ray ceramic cartridge heater constitution.

The carbonization vessel 12 installed in the main body case 1 is a container structure having an open upper surface as shown in FIG. 1. The carbonization vessel 12 is made of a general iron (Fe) material It is preferable that the container is made of a ceramic coating vessel coated with urethane of a ceramic material.

The shrinkage portion 2, which is the catalyst insulation, is a filtration means for primarily filtering various kinds of pollutant gases (carbonized gas) generated during the carbonization action. As the shrinkage portion of the catalyst heat insulation, A catalytic heater 22, a first catalyst 23, a second catalyst 24, a third catalyst 25, and a third catalytic converter 25 as a sequentially stacked structure having a tubular structure, The fourth catalytic converter 26, the fifth catalytic converter 27 and the catalytic automatic temperature sensor 28 are disposed in the exhaust passage of the exhaust gas purifying catalytic converter It is preferable to form the heater 29 so as to be attached.

At this time, the first catalyst 23 is a catalyst for removing ammonia and an amine-based odor,

ego;

The second catalyst (24) is a catalyst for removing organic acid-based odor, the formula of which is:

;

The third catalyst 25 is a catalyst for removing carbon monoxide and VOC's.

ego;

The fourth catalyst (26) is a catalyst for removing volatile organic compounds.

Lt;

Finally, the fifth catalyst 27 is a catalyst for removing dioxin.

.

The air tank 3 is a means for cooling the carbonized gas delivered through the series of catalysts (the first catalyst to the fifth catalyst) to a state close to room temperature, A plurality of gas convection preventing plates 31 are formed on the inner surface of the casing 31. An inlet 32 having a piping connection relation is formed on one side of the closed container structure and a discharge port 33, Is formed.

At this time, a sheet-like activated carbon 321 and an ion filter 331 are installed in the discharge port 33 of the air tank 3 as shown in FIG.

The auxiliary filtering device 4 is a filtering means for secondarily filtering the carbonated gas delivered through the air tank 3. The auxiliary filtering device 4 as described above is, as shown in FIG. 1, It is preferable to form the basic activated carbon 41, the acidic activated carbon 42, and the neutral activated carbon 43 in a sequential arrangement structure.

In addition, the ozone generator 5 uses a dielectric of glass in front of one of the electrodes and applies an alternating voltage of 25,000 (V) to 30,000 (V) A conventional ozone generator is used which generates ozone (O ₃ ) by reacting with oxygen molecules (O ₂ ). In applying this ozone generator to the present invention, the amount of ozone generated should be limited to 0.03 ppm to 0.05 ppm .

The vacuum pump 6 is a kind of carbon dioxide gas discharging means for compressing the carbonized gas delivered through the auxiliary filter 4 described above to a predetermined pressure and delivering it to a water tank 7 to be described later. As shown in FIG. 1, it is preferable to connect and form a bubble generating tube 61 having a plurality of bubble generating holes P on one side of the pump 6.

In addition, the water tank 7 has a structure in which the above-mentioned carbon dioxide gas introduced from the vacuum pump 6 is subjected to final filtration treatment and discharged to the atmosphere. Such a water tank 7 is filled with a predetermined amount And a gas discharge hole 71 is formed on one side of the upper part of the water tank.

On the other hand, the electronic control panel device 8 automatically controls the above-mentioned series of constituent parts to control a series of driving relationships (temperature and time of the far infrared ray heater, temperature of each catalyst, It is preferable that such an electronic panel device 8 is formed by a conventional electronic control device structure having a circuit connection relationship as shown in Fig.

Therefore, when bonding the carbonization apparatuses using the far-infrared heaters having the above-described configuration to each other,

As shown in Fig. 1, the shrush portion 2, which is a heat insulating member, is formed integrally with the upper center of the main body case 1 in which the far infrared ray heater 11 and the carbonization vessel 12 are mounted, 1, the air tank 3, the auxiliary filtration device 4 and the vacuum pump 6 are connected to each other as shown in Fig. 1, Make connections.

Under such a condition, the ozone generator 5 having a separate constitution is installed on one side of the vacuum pump 6 and connected to the vacuum pump 6, and the ozone generator 5 is again connected to the bubble of the vacuum pump 6 And the water tank 7 is installed as the structure in which the generation tube 61 is introduced, thereby realizing a carbonization apparatus using a series of far-infrared heaters according to the present invention.

Hereinafter, the use relationship of the carbonization apparatus using the far infrared ray heater having the above-described combined structure and the interaction therebetween will be described.

First, with the electronic control panel device 8 as shown in FIG. 2, the carbonized container 12 filled in the case body 1 is filled with the waste 10 requiring carbonization, When the power is supplied, the far infrared ray heater 11 installed in the case body 1 emits radiant heat at a high temperature and carries out the carbonization work by heating the carbonization vessel 12.

The far infrared ray heater 11 for radiating high temperature radiant heat has a line connection structure closely arranged on the bottom surface of the carbonization vessel 12 and is installed into the carbonization vessel 12 through the upper surface of the carbonization vessel 12 The carbonized vessel 12 is directly subjected to heat in the range of 350 ° C to 400 ° C, and the carbonized vessel 12 is subjected to ceramic urethane coating treatment So that it is prevented from being stuck with any carbide.

The heat insulating brick 13 forming the inner wall surface of the case body 1 is made of aluminum oxide, alumina and yellow soil. The insulating brick 13 is provided with an adiabatic effect to withstand a temperature range of 1200 to 1300 占 폚. And a function of evaporating and removing the adsorbed water vapor by the heat of combustion is performed at the same time.

Meanwhile, when the waste is carbonized by the far infrared ray heater 11 and the carbonization vessel 12 as described above, various kinds of harmful carbonized gas are generated in the body case 1, 21), and flows into the shredding portion (2), which is a heat insulating member of the catalyst.

Thus, the shredding section 2, which is the catalyst insulation, turns on the power at a temperature of 350 ° C of the carbonized gas introduced as the temperature sensing by the catalyst automatic temperature sensor 28 to remove the catalyst heater 22, The internal temperature of the series of catalysts (the first catalyst to the fifth catalyst) forming the laminated structure is maintained in the temperature range of 250 ° C. to 350 ° C. by the heat generating action of the heater 29, ), (24), (25), (26), and (27).

At this time, the catalyst foreign substance removing heater 29 is a heater having a self cleaning function, and operates in a temperature range of 500 ° C to 550 ° C for about 2 hours at a time (about 3 months) depending on the carbonization amount It is preferable that the catalyst 29 has a function of selectively removing foreign substances remaining in the catalyst (the first catalyst to the fifth catalyst). It is preferable that no additional carbonization is performed during operation of the catalyst foreign substance removing heater 29 .

The carbonized gas passing through the shroud section 2, which is the catalyst insulation, again flows into the air tank 3 along the line connected with the pipe. When the carbonized gas flows into the air tank 3 , The gas convection prevention plate 31 formed in the air tank 3 delays the residence time of the introduced carbonized gas and cools the carbonized gas to a temperature close to room temperature.

The carbonized gas passing through the air tank 3 flows into the auxiliary filtration device 4 again through the piping line and is transported by the basic activated carbon 41 to the carbonized gas containing trimethylamine, monomethylamine, Removing the benzene, toluene, xylene, styrene, carbon disulfide, acetic acid, valacic acid, lactic acid, hydrogen sulfide, methyl mercaptan, dimethyl sulfide and the like contained in the carbonized gas by the acidic activated carbon 42, The activated carbon 43 removes ethanol, acetic acid, valacic acid, lactic acid, formaldehyde, acetaldehyde, ethylene, carbon monoxide and the like contained in the carbonized gas.

The carbonized gas from which a series of harmful substances have been removed through the auxiliary filtration unit 4 flows into the vacuum pump 6 again and is mixed with the ions supplied from the ion generator 5, The carbonized gas delivered to the water tank 7 through the bubble generating pipe 61 is finally filtered by the water filled in the water tank 7 to be supplied to the gas tank 7, And discharged to the atmosphere through the discharge hole 71, thereby completing a series of carbonization operations.

On the other hand, when a series of carbonization is completed,

The cooling fan 14 and the air blowing inlet 15 are driven as automatic control by the electronic control panel device 8 so that the heat source inside the case body 1 heated by the carbonizing operation is forcibly blown and cooled, When the temperature of the inside of the case body 1 (carbonization vessel) falls in the temperature range of 75 ° C to 80 ° C due to the cooling action, the temperature is sensed by the carbonization temperature sensor (not shown).

Therefore, when the richness indicating the end of the carbonization operation sounds as described above, the operator can open the carbonization vessel 12 whose temperature has been lowered, with the opening / closing door D of the main body case 1 opened, So that the carbide 10 is eventually discarded.

As described above, the carbonization apparatus using the far-infrared heater according to the present invention shortens the temperature rise time necessary for the carbonization work according to the direct heating method using the far infrared ray cartridge heater, and prevents unnecessary power loss by shortening the temperature rise time Not only is the efficiency of operation increased significantly;

In addition, according to the rapid cooling function of the carbonization vessel by the heat cooling apparatus, it is possible to easily carry out the discharging operation of the carbide, and at the same time, various kinds of harmful gas and odor generated during the carbonization Thereby effectively preventing the problem of serious air pollution.

Claims (6)

A body case having a structure in which a door (D) is formed on one side, a far infrared heater and a carbonization container are disposed inside the door, and an inner wall surface is made of a heat insulating brick; A dehumidifier 21, a catalytic heater 22, a first catalyst 23, a second catalyst 24, a third catalyst 25, a fourth catalyst 25, A shroud section 2 which is a catalyst insulation of a tubular structure in which a first catalyst 26, a fifth catalyst 27, a catalyst automatic temperature sensor 28 and a catalyst foreign material removing heater 29 are disposed; An air tank 3 having a structure in which piping is connected to the shrinkage portion 2 as a catalyst insulation, the gas tank 3 having a plurality of gas convection preventing plates 31 therein; An auxiliary filtration device 4 having a basic activated carbon 41, an acidic activated carbon 42 and a neutral activated carbon 43 as a structure to be connected to the air tank 3 by piping; A vacuum pump 6 having a bubble generating tube 61 at one side thereof and having an additional connection with the ozone generator 5 having a separate structure, Wow; A structure in which the bubble generating tube 61 of the vacuum pump 6 is introduced includes a water tank 7 having a gas discharge hole 71 at an upper side thereof; Characterized in that an electronic control panel device (8) is provided as control means for controlling a series of components operating relationship. The far infrared ray heater (11) according to claim 1, wherein the far infrared ray heater (11) is formed by filling and injecting ceramic alumina into a stainless steel pipe into which hot wire is inserted, sealing both ends thereof in a vacuum state, and coating the outer surface of the stainless steel with a far infrared ray paint Wherein the heating device is a carbonizing device using a far infrared heater. The carbonizing apparatus using a far infrared ray heater according to claim 1, wherein the carbonization vessel (12) comprises a urethane-coated vessel made of a ceramic material. The method as claimed in claim 1, wherein the far infrared ray heater (11) has a line connecting structure closely arranged on the bottom surface of the carbonization vessel (12) and is installed into the carbonization vessel (12) through the upper surface of the carbonization vessel A charring device using a far infrared heater. The refrigerator according to claim 1, wherein a cooling fan (14) is formed on one side of the upper surface of the main body case (1) and an air blowing inlet (15) (1) is forced to cool the inside of the carbonization heat. A far infrared ray heater according to claim 1, characterized in that a sheet-like activated carbon (321) and an ion filter (331) are provided in an outlet (33) of an air tank (3) connected to the auxiliary filtration device (4) .