KR19980076046A - Hazardous Gas Incinerator - Google Patents

Abstract

According to the present invention, harmful gases including harmful substances such as odors and bacterial organic dusts scattered in chemical plants, food treatment plants, and waste treatment plants are incinerated by heat storage and heat exchange of heating heat. Regarding an incineration apparatus, in particular the inflow passage 12 of the gas to be incinerated; A combustion unit (10) mounted on the sealed side of the gas inflow passage (12) and forming a combustion space (18) to combust the gas by direct contact; A heat storage unit 20 adjacent to the combustion unit 10 and installed in the discharge direction of the gas and accumulating heat from the gas passing through the combustion unit; A heat transfer part 30 formed between the heat storage part 20 and the inflow passage 12 of the gas, and transferring heat to the gas passing through the inflow passage; It is formed around the inlet passage 12 that absorbs heat from the heat transfer unit 30 to shield the release of heat, characterized in that consisting of a heat insulating portion 40 formed of the heat insulating material 42 and the housing 44 It is a gas incinerator.

Description

Hazardous Gas Incinerator

The present invention relates to a noxious gas incineration apparatus, and in particular, incineration of harmful gases including odors, bacteria, organic dusts, etc. scattered in a chemical plant, a food treatment plant, a waste treatment plant, etc. The present invention relates to an incinerator for harmful gases that can remove harmful substances.

In the process of producing chemicals, painting factories, vehicles, and other wastes, food, and waste treatment devices, severe odors, dust, and gases containing substances harmful to the human body are scattered, causing serious harm to workers and harassing nearby residents. . Therefore, the authorities are making efforts to protect the health of workers and the safe life of neighbors by establishing regulations along with sanctions.

Conventionally, various means have been devised to remove harmful gases. In other words, a filter such as activated carbon is used to purify the noxious gas, or a method such as treatment by chemical reaction or incineration is used.

If the filter is used to purify the hazardous substances, it is possible to filter the hazardous substances to some extent, but there are limitations on the harmful gases emitted in large quantities, and they need to be replaced over a period of time.

In the case of purifying the harmful gas by reacting with a chemical substance, the kind of the hazardous substance reacting with the harmful gas is limited and the facility must be provided, which is expensive.

In case of purifying the harmful substances by incineration, there is excessive heat consumption since they are not discharged to the outside without utilizing the thermal energy contained in the discharged water after incineration. Therefore, the complete combustion of the hazardous substances is determined by the capacity of the incinerator. If the hazardous material to be incinerated as a result that incomplete combustion occurs and is a nitrogen oxide (NO _X), and other pollution, the gas discharged into the air.

As described above, the conventional noxious gas treatment means cannot handle the noxious substances extensively, and also requires a lot of energy to incinerate the noxious gases, wastes a lot of energy discharged to the outside, and can completely clean the noxious substances. There is no problem.

The present invention has been invented to solve the above problems, and an object of the present invention is to provide a noxious gas incinerator for removing harmful substances by incineration of noxious gases with minimal energy.

In order to achieve the above object, the present invention, the gas inlet passage for introducing a gas to be incinerated; A combustion unit mounted on the sealed side of the gas inflow passage and combusted by direct contact; A heat storage unit configured to accumulate heat from the gas supplied and installed in a direction in which the gas in contact with the combustion unit is discharged to the outside; A heat transfer part formed between the heat storage portion and the gas inflow passage and transferring heat to the gas passing through the gas inflow passage; It is a noxious gas incineration device, characterized in that formed in the periphery of the gas inlet passage for absorbing heat from the heat transfer portion to comprise a heat insulating portion to shield the release of heat.

In addition, the present invention is a harmful gas incineration device, characterized in that the direction of the harmful gas flowing into the gas inlet for the discharge direction and the incineration of the gas incinerated harmful gas in the combustion unit.

According to a preferred embodiment of the present invention, the harmful substances including the foreign matter, odor, organic dust, etc. to be incinerated are discharged to the outside through the heat accumulator while being burned in direct contact with the combustion unit through the inflow passage. Here, the heat storage unit accumulates heat of itself, such as noxious gas, and combustion heat combusted in the combustion unit. Therefore, the temperature of the heat storage unit accumulates a lot of heat according to the time of combustion, and transfers the heat to the gas moving along the inflow passage through the heat transfer unit or ignites the gas having a low flash point. Therefore, the gas discharged to the outside through the combustion unit and the heat storage unit is completely burned to completely incinerate harmful substances.

1 is a cross-sectional view of a noxious gas device according to an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10: combustion part 12: gas inflow passage

14: mediating means 16: heating element

18: combustion space 20: heat storage unit

22: Inlet side 24: Outlet side

30: heat transfer part 40: heat insulation part

42: insulation 44: housing

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

1 is a cross-sectional view of a harmful gas incineration apparatus according to an embodiment of the present invention.

The present invention has a technical idea to suppress the generation of pollution by completely burning the harmful substances contained in the harmful gas with little energy by using the heat storage and heat exchange and heat insulation of the combustion heat.

In this embodiment, the embodiment includes a gas inflow passage 12 through which harmful gas is introduced, a combustion unit 10 that emits thermal energy to combust harmful gas, and a heat storage unit 20 that accumulates heat of the burned gas. And a heat transfer part 30 for transferring the heat accumulated in the heat storage part 20 to the harmful gas flowing into the gas inflow passage 12, and a heat insulating part 40 for preventing heat from being released to the outside. This embodiment maximizes heat exchange by forming the opposite direction of the harmful gas flowing into the gas inlet 12 for the discharge direction and incineration of the gas incinerated harmful gas in the combustion unit (10).

The gas inflow passage 12 is formed while forming a wide width from the direction of introducing the harmful gas to be incinerated and tapered to a narrow width at a certain time, which is intended to induce the smooth inflow of gas. In addition, one or more gas inlet ports 50 and 50 'are formed in the gas inlet passage 12 to guide the gas to be incinerated into the inlet passage.

However, the harmful gas flowing into the gas inflow passage 12 serves to maximize heat exchange of the heat transfer part 30 by primarily insulating the accumulated heat of the heat storage part 20.

The combustion unit 10 ignites and burns the gas to be incinerated by direct contact, and is installed at the closed end of the gas inflow passage 12. It receives the ignition energy from the outside through the medium means 14, forms a heating body 16 toward the gas to be incinerated, thereby completely burning the gas in the combustion space 18 formed at regular intervals. The ignition energy of the heating body 16 may be LPG or the like, but it is preferable to use electricity in terms of continuous supply and regulation of energy and simplification of the combustion device.

The heat storage unit 20 is to accumulate heat by passing a gas ignited and combusted in the combustion unit 10. It is formed in a direction in which gas is discharged with the heating body 16 and the combustion space 18 of the combustion unit 10 interposed therebetween, and ceramic particles that are easy to accumulate and discharge heat are used. Alumina oxide having high durability and heat storage capacity was laminated.

As a result, the gas burning the harmful substances in the combustion section 10 enters the inlet side 22 and passes through the laminated alumina oxide, thereby losing high heat after combustion to the alumina oxide. Therefore, the gas exiting from the outlet side 24 of the heat storage unit 20 is discharged to the outside at a low temperature.

As a result, the heat storage unit 20 retains a large amount of heat in proportion to the number and time of the cycle in which gas is burned and passed through the combustion unit 10. In addition, the inlet side 22 of the heat storage unit 20 retains heat accumulated at a high temperature, and the outlet side 24 has a relatively low temperature. This is an important factor in naturally generating gas containing noxious gas in relation to the heat transfer part 30 which will be described later.

The heat transfer part 30 is formed between the heat storage unit 20 and the gas inflow passage 12 to transfer the internal heat of the heat storage unit 20 to the harmful gas introduced into the gas inflow passage 12.

The heat transfer part 30 may use a metal material such as a copper plate (銅版), but this is difficult to be easily damaged when exposed for a long time at high temperature. In addition, if a ceramic material is used, there is a durability against high heat, but the thermal conductivity is significantly lower than that of the metal material. Therefore, in this embodiment, the ceramic enamel coated with a ceramic material is used, which is advantageous in that it is not only excellent in durability against high heat but also high in thermal conductivity.

Looking at the fixing of the heat transfer of the harmful gas in the relationship between the heat storage unit 20 and the heat transfer unit 30 mentioned above, in order to incinerate the harmful gas introduced there is no accumulation of heat in the heat storage unit 20 initially High heat should be generated in the heating body 16 of the combustion unit 10, but as the cycle of incineration of hazardous gases is repeated, more heat is accumulated in the heat storage unit 20. In particular, the inlet side 22 that initially enters the gas in which noxious substances are incinerated accumulates heat higher than the outlet side 24 that passes through the heat storage unit 20 and releases heat to the alumina oxide.

Accordingly, the inlet side 22 of the heat storage unit 20 accumulates high heat close to the flash point of the noxious gas when the cycle of incineration of the noxious gas and discharged to the outside is repeated for a predetermined time. It is delivered to the harmful gas through the gas inlet through. Therefore, when the harmful gas in the gas inflow path 12 corresponding to the inlet side 22 of the heat storage unit 20 has a low flash point, it ignites spontaneously, and even if the harmful gas has a high flash point, the heat transfer part ( Since 30 receives a relatively high heat, the combustion unit 10 may add some heat energy.

Referring to the heat transfer state of the heat transfer unit 30, the outlet side 24 of the heat storage unit 20 forms a low temperature, the gas flowing through the gas inlet passage 12 also forms a low temperature, heat storage Since the inlet side 22 of the section 20 forms a high temperature, and the harmful gas at a corresponding position is a high temperature, the low temperature thermal energy is absorbed by the low temperature harmful gas at the outlet side 24 of the heat storage unit 20. The high temperature heat energy is absorbed by the high temperature harmful gas at the inlet side 22 of the heat storage unit 20.

As described above, the role of the heat insulating part 40 is important in transferring the heat of the heat storage part 20 through the heat transfer part 30 to burn the harmful gas introduced into the natural ignition or less energy.

The heat insulating part 40 blocks the heat of the heat storage part 20 and the heat transmitted from the heat transfer part 30 to be discharged to the outside, and opens the gas inflow passage 12 between the heat transfer part 30. While forming the heat insulating material 42 around the heat insulating part 40, the housing 44 was formed outside.

As described above, the present invention accumulates heat by passing the heat accumulator while the gas input through the inflow port passes through the inflow passage and gradually receives a lot of heat through the heat transfer unit to be transferred to the combustion unit for combustion. Therefore, the gas entering the inlet port receives heat from the heat accumulator through the heat transfer part and thus increases its own temperature, thereby obtaining a lot of heat energy required for complete combustion. Therefore, the gas is gradually burned even if the heat source of the heating element is small in the combustion part.

As described above, the harmful gas incineration apparatus of the present invention has the effect of completely burning and removing harmful substances from harmful gases including gases, odors, bacteria, organic dusts and the like with minimal energy.

Since what has been described above is merely a mere example in all respects, the present invention should not be limitedly interpreted based on this. Therefore, modifications and equivalent embodiments that fall within the true spirit and scope of the present invention shall fall within the claims of the present invention.

Claims (6)

A gas inflow passage 12 in which a harmful gas to be incinerated is introduced and a wide width is formed in a direction in which the gas is introduced, and is tapered to a narrow width at a predetermined point; A combustion unit (10) mounted on the sealed side of the gas inflow passage (12) and forming a combustion space (18) to combust the gas by direct contact; A heat storage unit 20 adjacent to the combustion unit 10 and installed in the discharge direction of the gas and accumulating heat from the gas passing through the combustion unit; A heat transfer part 30 formed between the heat storage part 20 and the inflow passage 12 of the gas, and transferring heat to the gas passing through the inflow passage; The heat insulator 40 is formed between the heat transfer part 30 and blocks the discharge of heat while the heat insulator 42 is mounted, and the heat insulator 40 is formed to form a housing 44 around its outer periphery. Toxic gas incinerator, characterized in that. According to claim 1, wherein the gas inlet 12 is to insulate the heat of the heat accumulator 20 primarily, one or more inlet ports 50, 50 'in the direction in which the gas flows To form a wide width at the beginning of the inflow, harmful gas incinerator, characterized in that to form a narrow width at a certain point. The apparatus of claim 1, wherein the heat storage unit (20) is formed by stacking ceramic particles. 4. The apparatus of claim 3, wherein the ceramic particles are alumina oxide. According to claim 1, wherein the heat transfer portion 30 is a noxious gas incinerator, characterized in that the ceramic coating on a metal material. Hazardous gas incineration device, characterized in that the direction of incineration from the combustion unit 10 is discharged through the heat storage unit 20 and the direction of harmful gas introduced through the gas inlet passage 12 are opposite to each other.