KR20120092348A - Incineration system using low thermal decomposition - Google Patents

Abstract

PURPOSE: An incineration system using low temperature pyrolysis is provided to incinerate a large quantity of garbage in a short time by consecutively inputting the garbage with a dual door. CONSTITUTION: An incineration system using low temperature pyrolysis comprises a pyrolysis furnace(100), a heat supply unit(200), an air supply unit(300), and a gas burner(400). The pyrolysis furnace has a waste input hole(110) and a dual door(111). Waste is inputted in the pyrolysis furnace through a waste input port. The dual door is formed between the input port and the pyrolysis furnace. The heat supply unit supplies heat to the water inputted through the waste input port. The air supply unit supplies external air to an internal space of the pyrolysis furnace and makes the waste to a ceramic cinder. The gas burner burns dioxin of exhaust gas generating in pyrolyzing the waste.

Description

Incineration system using low thermal decomposition

The present invention relates to an incineration system using low pyrolysis, and in particular, the present invention relates to an incineration system for incineration of various wastes using a low temperature.

Conventional waste incineration system is divided into large incineration system and medium / small incineration system according to the waste disposal capacity. Among these, large incineration system regulates the generation of dioxin at the government level, but small / small incineration system is There is no regulation yet.

In particular, the incineration ash generated in the conventional waste incineration system is about 10 to 15% of the waste input amount, which is entirely buried, and the incineration ash contains a large amount of heavy metals, which are harmful environmental pollutants. Therefore, when landfills containing heavy metals are buried, they cause soil and groundwater contamination, which is a serious environmental pollution source.

Although there exist many isomers in the said dioxins, they are PCDD (polybenzoic dioxin) and PCDF (polychlorinated dibenzo franc) typically, and are classified into various by the number of substitution of Cl (chlorine).

Regarding the mechanism in which dioxins are generated in a pyrolysis furnace, unpyrolyzed organic substances due to pyrolysis or incomplete pyrolysis of organic matter in wastes are contained on the fly ash surface of flue gas. Occurs by catalysis such as

Alternatively, polycyclic aromatic hydrocarbons (many of naphthalene, anthracene, clycene, pyrene, phenanthrene, etc.) generated by pyrolysis are decomposed by catalysis, or flammable gas generated by pyrolysis is reacted with chlorine by catalysis. It is estimated that it becomes a precursor called chlorophenol (C6H3Cl3O), and this produces | generates dioxins, such as PCDD by condensation reaction.

Usually, in pyrolysis treatment, waste is pyrolyzed above 850 ° C, so that hardly decomposable organic substances (dioxin) are generated.

However, a large amount of dioxin precursor is contained in the exhaust gas, and when the exhaust gas is cooled due to heat recovery, the resynthesis temperature of the dioxin of the dioxin precursor is 300 ° C. to 400 ° C., so that dioxin is resynthesized. have.

Therefore, in order to solve the above problems, in the pyrolysis furnace or pyrolysis method, wastes are treated in a low oxygen atmosphere as disclosed in Japanese Patent Application Laid-Open No. 2002-307045, and exhaust gas is fed to a cooler. By high-speed cooling, it is made to pass instantaneously through the temperature range (300-400 degreeC) which dioxins recombine, and it does not produce as much as possible the resynthesis reaction of dioxins.

However, in the conventional pyrolysis furnace or the pyrolysis method, in order to prevent resynthesis of dioxins, waste is treated under a low oxygen atmosphere, and the dioxin precursor contained in the exhaust gas is rapidly cooled by a cooler. By passing through the temperature range (300-400 degreeC) which dioxins recombine instantaneously, it prevents a resynthesis reaction as much as possible.

However, although the dioxin precursor contained in exhaust gas is instantaneous at the time of cooling, since it passes through the temperature range (300-400 degreeC) which resynthesizes, it is impossible to prevent resynthesis of dioxins completely. In addition, since it is necessary to install a cooling system, problems such as the increase in size of two devices also occur.

Therefore, Korean Patent Registration No. 10-2006-0111216 "pyrolysis furnace" has been applied as a method for solving the above problems.

As shown in FIG. 1, the pyrolysis furnace decomposes waste introduced into a space separated from an external space by a heat insulation wall and discharges the gas into a gas, and the gas discharged from the pyrolysis unit 1 is underwater. It includes a bubbling tank (35, 36) for aeration in the harmful substances to be absorbed in water and then exhausted. A pyrolysis section (1) which is blocked from an external space and formed of a refractory brick, a pyrolysis air inlet (4, 5) provided in a wall portion of the pyrolysis section to blow air into the pyrolysis section as a natural intake, and the air inlet By magnetically forming the magnetic field on the inlet air limiting means 17 for restricting the flow of air into the pyrolysis section by tightening, and an air passage for inducing air at the pyrolysis section at the air inlet to magnetically treat the air for pyrolysis. A plurality of pairs of magnets (15), waste support means (6, 7) for supporting wastes in a grill on a shelf inside the heat-resistant container, an exhaust gas discharge port (3) provided at a wall of the pyrolysis section, The apparatus 23 for removing harmful substances which aeration and exhaustion of the exhaust gas discharged from the exhaust gas discharge port in a water tank, and eggs such as dioxins and prolons contained in the exhaust gas. ) Consists of a catalytic system 19 for adsorbing and decomposing substances, exhaust means for exhausting the exhaust gas into the atmosphere by the fan section (24).

The pyrolysis furnace configured as described above maintains the amount of oxygen supplied to a certain limit, so that most of the heat generated by oxidation of combustibles is consumed for endothermic reactions such as drying, carbonization, and (pyrolysis), which are preliminary steps of the oxidation reaction. Be sure to

The temperature inside the pyrolysis unit is not increased by controlling the oxidation rate, which is an exothermic reaction. In addition, since the (thermal) decomposition and oxidation reaction of the waste introduced into the pyrolysis unit 1 is to occur at the lower portion of the pyrolysis unit 1, the bottom of the oxidation zone, the top (thermal) decomposition zone, the next top The carbonization zone and the top part consist of the drying zone.

Therefore, the radiant heat emitted from the exothermic reaction zone is suppressed from being radiated in the pyrolysis unit, so that the temperature inside the pyrolysis unit maintains a temperature below the pyrolysis temperature.

In other words, in the oxidation zone, the gas, which was higher than the pyrolysis temperature, is decomposed from the pyrolysis zone and is slightly higher than the pyrolysis temperature.Then, the gas is deprived of heat while passing through the carbonization zone and the drying zone. When the temperature is lower than the pyrolysis temperature. This series of reactions is relatively gentle enough to be manually controlled while reading the temperature inside the pyrolysis unit 1, so there is no problem in manual operation, and the temperature in the pyrolysis unit is proportional to the flow rate of the supply air for pyrolysis. Automatic control is possible by the control method.

Furthermore, in each of the air intake openings 4 and 5, the magnetized air is sucked in as the pyrolysis air by the magnetization effect on the air passage 28, and therefore, the pyrolysis section 1 before the pyrolysis. Even after using the present air (oxygen) for pyrolysis, using the slight air sucked by natural intake, for example, the temperature of the pyrolysis furnace 50 at the temperature of 300 ° C. or lower, preferably at an ambient temperature of 120 to 250 ° C., It can continuously pyrolyze at low temperatures. Therefore, it is possible to advantageously suppress the production of dioxins by pyrolysis.

In addition, the waste introduced into the pyrolysis unit through the waste inlet 9 is accumulated in the upper heat transfer unit 30 placed on the upper waste support means 6. If there is only one heat transfer section, thermoplastic plastics, etc., in the input waste are heated and liquefied and then flowed down prior to pyrolysis. Holding it.

Accordingly, the present invention has been made in view of the above, and the present invention allows the waste to be continuously introduced by adopting a double door, so that a large amount can be incinerated in a short time to incineration system using low pyrolysis. Led to develop.

Another object of the present invention is to minimize the heat loss during incineration by using the heat of the incinerated ash as a heat source.

Another object of the present invention is to compact an incinerator so that a large amount of waste can be incinerated without occupying many places.

The incineration system using the low thermal decomposition of the present invention is a thermal decomposition unit for injecting waste into the inner space separated by the outer space and the thermal insulation wall, and decomposed the waste into exhaust gas, and the exhaust gas generated from the pyrolysis unit inside In a pyrolysis furnace having a bubbling tank that aeration in the water contained in the water to adsorb the harmful substances contained in the exhaust gas to the water and then discharge the exhaust gas,

A double door disposed at a side of a waste inlet for introducing waste into the pyrolysis furnace and formed between the inlet and the pyrolysis furnace; And

Heat supply means for applying heat to the waste introduced into the waste inlet; And

An air supply means for supplying outside air to the internal space of the pyrolysis unit and installed to be connected to the outside at a lower side of the pyrolysis furnace to make the waste into ceramic incinerator; And

A gas combustion burner installed to extinguish dioxins contained in exhaust gases generated by pyrolysis of the incinerated waste; And

.

The air supply means is a pair of air inlet formed to face each other under the thermal decomposition unit; And

An inlet air limiting valve installed at the air inlet to limit inflow of air into the pyrolysis unit; And

The magnetic field is formed on the air passage formed in the air inlet, and is composed of a magnetic material for magnetically treating the air for pyrolysis. The incinerated ash is used as a heat source.

The incineration system using the low thermal decomposition of the present invention can obtain the following effects.

First, by adopting a double door to enable continuous input of waste, it was possible to incinerate a large amount in a short time.

Second, heat loss during incineration was minimized by using the heat of incinerated ash as a heat source.

Third, the incinerator was compacted so that a large amount of waste could be incinerated without taking up many places.

1 is a cross-sectional view showing a conventional pyrolysis furnace.
2 is a cross-sectional view of an incineration system using low pyrolysis according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation according to the present invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description with reference to the accompanying drawings, the same reference numerals denote the same elements regardless of the reference numerals, and redundant description thereof will be omitted. Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

In the present invention, a waste heat is injected into the inner space separated by the outer space and the insulation wall, and the waste gas is decomposed and discharged into the exhaust gas, and in the water containing the exhaust gas generated in the pyrolysis portion therein. The constitution of a pyrolysis having a bubbling tank for aeration and adsorbing harmful substances contained in the exhaust gas to water and then exhausting the exhaust gas is similar to that of the prior art, but the configuration is different as follows.

In the present invention, a waste inlet 110 for introducing waste into the pyrolysis furnace 100 is installed at the side, and a double door 111 is formed between the inlet and the pyrolysis furnace.

A heat supply means for applying heat to the waste introduced into the waste inlet 110 and the outside air to the internal space of the pyrolysis unit 200, and to the bottom of the pyrolysis furnace to make the waste ceramicized incinerator The air supply means 300 is installed to be connected to the outside, and the gas combustion burner 400 is installed to extinguish dioxin contained in the exhaust gas generated by the pyrolysis of the incinerated waste.

The air supply means 300 is a pair of air inlet 310 formed to face each other at the bottom of the pyrolysis section, and an inlet air limiting valve installed at the air inlet to limit the amount of air to the pyrolysis section ( 320 and a magnetic 330 for magnetically treating the air for pyrolysis by forming a magnetic field on the air passage formed in the air inlet.

Hereinafter, the installation method will be described before explaining in detail the function and operation of the incineration system using low pyrolysis.

After opening the double door 111 formed in the pyrolysis furnace 100 of the present invention, the waste is introduced through the waste inlet 110, and the double door is closed.

Then, the fire is turned on through a burner (not shown) through the heat supply means 200 and heated for about 30 degrees so that the temperature in the furnace is about 280 ° C, and then the heating source is cut off from the burner.

Then, the waste is pyrolyzed by the temperature in the furnace, and the waste incinerator is ceramicized and falls to the bottom.

At this time, the worker checks this and removes the incineration ash and re-injects it into the pyrolysis furnace to reuse it as a heating source.

On the other hand, the gas coming out while the waste is incinerated is reburned by the gas combustion burner 400, at this time by heating for about 2 seconds at a temperature of 850 ℃ to burn dioxin or the like to discharge only the clean air to the outside.

Although the present invention has been described with reference to the above-described preferred embodiments and the accompanying drawings, different embodiments may be constructed within the spirit and scope of the invention. Accordingly, the scope of the present invention is defined by the appended claims, and is not to be construed as limited to the specific embodiments described herein.

100: pyrolysis furnace 110: waste inlet
111: double door 200: heat supply means
300: air supply means 310: air inlet
320: limiting valve 330: magnetic
400: gas burner

Claims (3)

The waste is injected into the inner space separated by the outer space and the insulation wall, and a pyrolysis section for decomposing the waste into the exhaust gas and aeration in the water containing the exhaust gas generated in the pyrolysis section is exhausted. In a pyrolysis furnace having a bubbling tank for allowing the harmful substances contained in the gas to be adsorbed to water and then discharge the exhaust gas,
A double door disposed at a side of a waste inlet for introducing waste into the pyrolysis furnace and formed between the inlet and the pyrolysis furnace; And
Heat supply means for applying heat to the waste introduced into the waste inlet; And
An air supply means for supplying outside air to the internal space of the pyrolysis unit and installed to be connected to the outside at a lower side of the pyrolysis furnace to make the waste into ceramic incinerator; And
A gas combustion burner installed to extinguish dioxins contained in exhaust gases generated by pyrolysis of the incinerated waste; And
Incineration system using low pyrolysis characterized by. According to claim 1, The air supply means is a pair of air inlet formed to face each other under the pyrolysis unit; And
An inlet air limiting valve installed at the air inlet to limit inflow of air into the pyrolysis unit; And
Magnetic to form a magnetic field on the air passage formed in the air inlet to magnetically process the air for pyrolysis;
Incineration system using low pyrolysis, characterized in that consisting of. The method of claim 1,
Incineration system using low pyrolysis, characterized in that the incinerated ash used as a heat source.

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