KR100959095B1 - Volatile organic compound incinerator - Google Patents

Abstract

PURPOSE: A volatile organic compound incinerator is provided to collect waste heat of exhaust gas by installing a heat exchanger in a combustion chamber. CONSTITUTION: A volatile organic compound incinerator comprises a combustion chamber(10) and a spraying part(40). The combustion chamber has a burner(20) and an exhaust gas chamber(60). The burner is coupled with a burner fixing part(101). The exhaust gas chamber is coupled with the outside of the burner fixing part. The other side of a blower(61) is coupled with a combustion gas inlet port(601) of an exhaust gas chamber through a flange. The spraying part is composed of a swirl pipe(42) and a nozzle(41). The swirl pipe is combined with a through-hole(103) of an inclined wall(102) of a combustion chamber. The cross section of the swirl pipe is identically formed from an entrance to an exit.

Description

Volatile Organic Compound Incinerator

The present invention relates to a volatile organic compound combustion apparatus, in particular, the organic gas in the explosive range is mixed with the exhaust gas in the injection portion to escape the combustion conditions to enter the combustion chamber and decomposes the organic compound in the high temperature combustion chamber At this time, it is to recover the waste heat of the generated high-temperature exhaust gas.

In general, volatile organic compound gases (VOCs) (hereinafter referred to as "organic gases") have a high vapor pressure and are easily evaporated into the atmosphere, causing photochemical reactions due to the action of sunlight when co-existing with nitrogen oxides. It produces photochemical smog by producing secondary pollutants such as peroxyacetyl nitrate.

Aromatic or halogenated hydrocarbons of organic gases are directly harmful to humans. Aliphatic hydrocarbons and especially olefins are not harmful to humans. As a result, there has been an indirect contribution to global warming.

In the meantime, the organic gas is supplied to the combustion chamber by installing a separate organic gas nozzle in a state where fuel is ignited and burned by a burner coupled to one side of the combustion chamber. Accordingly, there was a problem that the risk of explosion and the recovery rate of waste heat are lowered.

In order to solve the problem of the explosion, the air was mixed and diluted outside the explosive range for combustion in the combustion chamber, and the burner for fuel combustion was installed at one side to increase the temperature due to the lack of combustion temperature due to the dilution of the outside air. This method requires fuel to increase the temperature by diluting the cold air in the outside air, and increases the processing cost as the amount of mixed air increases due to the high oxygen concentration and the amount of exhaust gas, which reduces the waste heat recovery rate and increases the use of fossil fuel. There was another problem that the incidence rate of greenhouse gases increases.

The present invention was created to solve the above problems, and incineration of organic gas without explosion, and also to reduce the incineration cost by increasing the recovery rate of waste heat generated, thereby reducing the generation rate of greenhouse gases It is an object to provide a volatile organic compound combustion apparatus.

In the present invention, the burner 20 is coupled to one side of the combustion chamber 10, and the combustion gas outlet 30 is coupled to the other side, and the injection unit 40 is coupled to the burner 20. In the volatile organic compound combustion device (A),
The combustion chamber 10 is coupled to the exhaust gas chamber 60 having a combustion gas inlet 601 on the outside of the burner fixing portion 101 to which the burner 20 is coupled, and the combustion gas inlet 601 is The other side of the blower 61 having one side coupled to the combustion gas outlet 30 is bolted against the flange 62,
The injection unit 40 is installed in the exhaust gas chamber 60, the injection unit 40 is coupled to the through hole 103 formed in the inclined wall 102 of the combustion chamber 10 The swirl pipe 42 and the nozzle 41 provided in the swirl pipe 42, The swirl pipe 42 is formed in the same cross-sectional area from the inlet toward the outlet, the swirl pipe 42 It is characterized in that the spiral blade 421 is formed in the inlet side.

In addition, the nozzle 41 is one side of the expansion pipe 412 is coupled to the end of the injection pipe body 411, characterized in that the flashback prevention nozzle 43 is coupled to the other side of the expansion pipe 412.

In addition, the nozzle 41 is characterized in that it is provided inside the spiral blade 421 of the swirl pipe (42).

In addition, the flashback prevention nozzle 43 has a flat plate 433 against the uneven plate material 432 is formed in the longitudinal direction of the irregularities 431 is repeated, and the butted plate material 432 and the flat plate 433 One side is rolled toward the other direction is characterized in that the tubular hole 434 of the polygonal shape is formed.

And a heat exchanger 70 is inserted into the inlet side of the combustion gas discharge port 30, the heat exchange unit 70 is a plurality of inlet 701 and the discharge port 702, respectively, a plurality of inside the water chamber 71 The two ends of the tube 72 are coupled to each other so that combustion gas is discharged through the inside of the tube 72, and water W is filled in the space between the water chamber 71 and the surface of the tube 72. The purpose of the present invention is to provide a volatile organic compound combustion apparatus, characterized in that the water supply unit 73 is coupled to the inlet 701, and heated steam is generated at the discharge port 702.

According to the present invention, the organic gas in the explosive range is supplied to the combustion chamber through the injection unit and at the same time a part of the exhaust gas is supplied to the surrounding area where the organic gas is supplied by the blower, thereby leaving the combustion range of the organic gas without backfire. An effect that can be stably burned in the chamber can be obtained.

In addition, by allowing the heat exchange part to be installed in the combustion chamber through which the combustion gas is discharged, it is possible to obtain the effect that the waste heat of the discharged exhaust gas is easily recovered.

In addition, through this, the amount of fossil fuel used for incineration may be reduced, thereby reducing costs and further reducing greenhouse gas emissions.

An embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view of a volatile organic compound combustion apparatus according to the present invention, FIG. 2 is a longitudinal sectional view of a volatile organic compound combustion apparatus according to the present invention, and FIG. 3 is an exploded perspective view of main parts of the volatile organic compound combustion apparatus according to the present invention. 4A and 4B are exemplary views illustrating the flashback prevention nozzle constituting the volatile organic compound combustion device according to the present invention.

The organic compound combustion apparatus A according to the present invention is composed of a combustion chamber 10, a burner 20, a combustion gas outlet 30, and an injection unit 40, as shown in Figs. It is. That is, a burner 20 in which the fuel supplied through the fuel supply pipe 21 is ignited and combusted is coupled to one side of the combustion chamber 10 in which a combustion space is provided, and corresponds to the burner 20. Combustion gas outlet 30 through which the combustion gas combusted on the other side is discharged is coupled, and the organic gas VG and the exhaust gas EG are brought into the combustion chamber 10 to be close to the burner 20. It is configured to be coupled to the injection portion 40 to be injected toward.

The combustion chamber 10 has a long tunnel shape in which both sides have a smaller diameter and a wider center, and a known fire brick 11 having a predetermined thickness is stacked therein to prevent heat from being conducted to the outside. It is configured to be.

The exhaust gas chamber 60 having the combustion gas inlet 601 is coupled to the outside of the burner fixing part 101 to which the burner 20 is coupled to one side of the combustion chamber 10, so that the exhaust gas EG It is comprised so that it may supply uniformly through the several swirl pipe | tube 42 mentioned later.

The combustion gas inlet 601 is configured such that the other side of the blower 61 having one side coupled to the combustion gas outlet 30 is bolted against the flange 62.

The injector 40 injects a part of the exhaust gas EG discharged through the combustion gas outlet 30 while the organic gas VG is injected into the combustion chamber 10. It is configured to prevent backfire by lowering the oxygen concentration on the side, and to reduce the supply of air required for combustion and to reduce the generation of nitrogen oxides.

To this end, the injection unit 40 is a swirl pipe 42 coupled to the through hole 103 formed in the inclined wall 102 of the combustion chamber 10 into the nozzle 41 and the exhaust gas chamber 60. )

The nozzle 41 is coupled to one end of the expansion tube 412 to the end of the injection pipe 411 is coupled to the end of the supply pipe 401 to which the organic gas (VG) is supplied, the expansion tube 412 Flashback prevention nozzle 43 is coupled to the other side is configured to prevent the flame flow back.

The swirl pipe 42 has the same cross-sectional area from the inlet toward the outlet, and a spiral blade 421 is formed inside the inlet side of the swirl pipe 42 so that the exhaust gas EG is a swirl pipe 42. In the process of flowing from the inlet side of the inlet) flows in a vortex form can be discharged into the combustion chamber 10 in a turbulent acceleration state. That is, the combustion gas is mixed with the organic gas in the swirl pipe 42 to escape the combustion conditions to prevent the backfire phenomenon and pushed into the combustion chamber 10 to be decomposed in the combustion chamber 10 having a high temperature.

The swirl pipe 42 is further extended to a predetermined length from the end of the spiral blade 421 is configured to form a swirl space 422 therein.

The nozzle 41 is provided inside the spiral blade 421 of the swirl tube 42, the organic gas (VG) is injected is provided in a state that is spaced apart from the inner circumferential edge of the swirl tube (32) The exhaust gas EG passing between the nozzle 41 and the swirl pipe 42 in the middle of the paper may be supplied or discharged into the combustion chamber 10 while swirling in a mixed state.

In addition, the flashback prevention nozzle 43 has an unevenness 431 which is repeated to have a function of preventing the flame ignited at the outlet side of the swirl pipe 42 from backfired into the expansion pipe 412 and the injection pipe 411. The flat plate 433 abuts against the uneven plate member 432 formed in the longitudinal direction, and one side thereof is rolled toward the other side to form a tubular hole 434 having a polygonal shape. That is, when the other side where the customs hole 434 is formed is in contact with the flame, the heat is conducted to the one side by heat conduction and cooled, thereby preventing the flame from extinguishing and backfire due to the stop of combustion in the customs hole 434. Will be.

The heat exchange part 70 is inserted into the inlet side of the combustion gas discharge port 30 so that waste heat can be recovered from the combustion gas discharged.

The heat exchange part 70 is a combustion that is combusted in the combustion chamber 10 by coupling both ends of the plurality of tubes 72 inside the water chamber 71 in which the inlet 701 and the outlet 702 are formed. In the process of the gas is discharged toward the combustion gas outlet 30 is configured to be discharged after passing through the inside of the tube (72).

The space between the water chamber 71 and the surface of the tube 72 is filled with a predetermined amount of water (W) and the water (W) is a water supply unit 73 coupled to the inlet 701 of the water chamber 71 It is configured to always be filled by a certain amount.

The discharge port 702 is configured to generate heated steam through heat exchange.

The volatile organic compound is combusted by the volatile organic compound combustion device A as follows.

First, the fuel supplied to the burner 20 through the fuel supply pipe 21 is ignited by an ignition device (not shown) and combusted by supplying external air. In the burned state, the organic gas VG is supplied to the supply pipe 401. Through the tubular hole 434 of the injection pipe 411 and expansion pipe 412 and the flashback prevention nozzle 43 is to be injected through.

Next, the injected organic gas (VG) passes through the interior of the swirl tube 42 inserted and fixed to the inclined wall 102, and at the same time, the combustion gas combusted in the combustion chamber 10 is combusted. As part of the exhaust gas EG is discharged through the exhaust gas EG, the exhaust gas EG is swirled into the exhaust gas chamber 60 by the suction force and the earth output of the blower 61. Will flow into the interior.

Next, the exhaust gas EG introduced into the swirl tube 42 is swirled while flowing along the spiral blade 421 formed inside the inlet side, and the swirling exhaust gas EG is turbulent, and the swirl space portion ( At 422, the organic gas VG is further compressed and expelled from the end of the orifice tube 42 in the process of being further mixed and accelerated to be out of the combustion condition and discharged into the combustion chamber 10.

In addition, when the gas flows into the swirl space in the process of burning the organic gas (VG), the flame contacts the end of the capillary hole 434 and the heat of the flame is one side of the capillary hole 434 due to heat conduction. As it is cooled while being inverted, the combustion is stopped inside the tubular hole 434 to extinguish the flame, thereby preventing backfire.

Next, as the combustion gas combusted in the combustion chamber 10 is moved toward the combustion gas outlet 30, it passes through the inside of the tube 72 formed in the water chamber 71. Heat is exchanged with the water (W) filled therein, and the heat (W) is heat-exchanged is discharged to the discharge port 702 is heated steam is recovered waste heat from the combustion gas.

1 is a perspective view of a volatile organic compound combustion apparatus according to the present invention.

2 is a longitudinal sectional view of a volatile organic compound combustion apparatus according to the present invention;

3 is an exploded perspective view of main parts of a volatile organic compound combustion device according to the present invention;

Figures 4a, 4b is an illustration showing a flashback prevention nozzle constituting a volatile organic compound combustion apparatus according to the present invention.

<Brief description of symbols for the main parts of the drawings>

10: combustion chamber 20: burner

30: combustion gas outlet 40: injection unit

41 nozzle 42 swirl tube

60: exhaust gas chamber 61: blower

62: flange 101: burner fixing part

102: inclined wall 103: through hole

421: spiral blade 601: combustion gas inlet

Claims (6)

The burner 20 is coupled to one side of the combustion chamber 10, the combustion gas outlet 30 is coupled to the other side, the volatile organic compound configured to be coupled to the injection unit 40 in close proximity to the burner 20 In the combustion device (A), The combustion chamber 10 is coupled to the exhaust gas chamber 60 having a combustion gas inlet 601 on the outside of the burner fixing portion 101 to which the burner 20 is coupled, and the combustion gas inlet 601 is The other side of the blower 61 having one side coupled to the combustion gas outlet 30 is bolted against the flange 62, The injection unit 40 is installed in the exhaust gas chamber 60, the injection unit 40 is coupled to the through hole 103 formed in the inclined wall 102 of the combustion chamber 10 The swirl pipe 42 and the nozzle 41 provided in the swirl pipe 42, The swirl pipe 42 is formed in the same cross-sectional area from the inlet toward the outlet, the swirl pipe 42 Volatile organic compound combustion apparatus, characterized in that the spiral blade (421) is formed in the inlet side. delete The method of claim 1, The nozzle 41 is coupled to one side of the expansion pipe 412 at the end of the injection pipe 411, the volatile organic compound characterized in that the flashback prevention nozzle 43 is coupled to the other side of the expansion pipe 412 Combustion device. The method according to claim 1 or 3, The nozzle (41) is a volatile organic compound combustion apparatus, characterized in that provided in the spiral blade (421) of the swirl tube (42). The method of claim 3, The flashback prevention nozzle 43 has a flat plate 433 against the uneven plate material 432 is formed in the longitudinal direction of the repeated irregularities 431, one side of the butted plate material 432 and the flat plate 433 is Volatile organic compound combustion apparatus, characterized in that the tubular hole (434) of the polygonal shape is rolled toward the other direction. The method of claim 1, The heat exchange part 70 is inserted into the inlet side of the combustion gas discharge port 30, and the heat exchange part 70 has a plurality of inside of the water chamber 71 in which the inlet 701 and the discharge port 702 are formed. Both ends of the tube 72 are coupled to each other so that combustion gas is discharged through the inside of the tube 72, and water W is filled in the space between the water chamber 71 and the surface of the tube 72. Volatile organic compound combustion apparatus, characterized in that the water supply unit 73 is coupled to the inlet 701, the heating steam is generated in the discharge port (702).

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