KR200280797Y1 - Hori. distribution type regenerative oxidization consumer equipment - Google Patents

Abstract

The present invention relates to a horizontally distributed regenerative oxidative combustion facility that is distributed to a distribution pipe provided with horizontally harmful gas and clean air.

The present invention is a combustion chamber having at least one combustion burner on the upper side, a heat storage layer provided on the lower side of the combustion chamber, and a plurality of distribution chambers are arranged in the longitudinal direction by a plurality of partition plates mounted at predetermined equal intervals below the heat storage layer. A formed facility body; A distribution pipe penetrating through the centers of the plurality of distribution chambers, and having a long hole formed at a predetermined isometric angle on an outer periphery of each distribution chamber section, and radially distributing wings are radially mounted between the long holes therein; A distribution chamber in which mixing of harmful gas and clean air is prevented by a diaphragm mounted above and below the distribution pipe; A supply part provided inside the main duct of one side of the facility body and supplying harmful gas to one side in a cross section coupled to an end of the distribution pipe, a discharge part for discharging clean air to the other side of the supply part, and the supply A rotor formed of a symmetrical shape in the center of the discharge part and purged to pass the respective diaphragms to prevent mixing of harmful gas and clean air; It comprises a drive unit for rotating the rotor at a predetermined speed.

Description

Horizontal Distribution Regenerative Oxygen Combustion Facility {HORI. DISTRIBUTION TYPE REGENERATIVE OXIDIZATION CONSUMER EQUIPMENT}

The present invention relates to a regenerative oxidative combustion plant (RTO) for purifying volatile organic compounds and discharging them into clean air. More specifically, a combustion chamber and a heat storage layer provided with at least one combustion burner on the upper side, and a lower side of the heat storage layer. And a plurality of dividers provided at a predetermined equal interval therebetween and penetrate through a central portion of the divider, and a long hole is formed at a predetermined equiangular periphery in each of the divider sections, and radially between the long holes therein. The main body is composed of a distribution pipe equipped with a distribution wing, the supply unit is coupled to the end of the distribution pipe to rotate at a predetermined speed, supply harmful gas to one side and the other side, and a discharge portion for discharging the clean air And a symmetrical shape formed at the center of the supply and discharge parts to mix harmful gas supplied to the combustion chamber and clean air combusted in the combustion chamber. And a rotor portion comprising purge to prevent, it relates to the rotor for driving the horizontal distribution type thermal storage oxidative combustion equipment configured including for rotating at a predetermined speed.

In general, various types of regenerative combustion equipment (R.T.O) for burning volatile organic compounds (VOCs) (hereinafter referred to as "harmful gases"), purifying them horizontally, and purifying them are disclosed.

For example, as shown in Figure 1, there is disclosed a "horizontal distributed regenerative combustion equipment" of the patent application No. 2002-0000000 filed with the applicant, the contents are as follows.

The blower BL causes the harmful gas generated in the factory to flow into the inner side, and an inner tube having a first discharge hole OH1 formed to have a predetermined equal interval spiral on the outer circumference so as to send the harmful gas to the heat storage layer CM. IP) and a second discharge hole OH2 are formed at the same position as the first discharge hole OH1 and mounted on an outer circumference of the inner pipe IP, and spirally opposite to the second discharge hole OH2. A rotor (RT) having an exterior (OP) for introducing clean air combusted into the inlet hole (IH) formed in the air and discharged to both ends;

Support holes (SH) for supporting both ends of the outer (OP) to facilitate the rotation of the rotor (RT), the first purge plate (PZ1) mounted on the upper side of the support hole (SH), and the first The heat storage layer CM is provided on the second purge plate PZ2 mounted below the first purge plate PZ1 and the first and second purge plates PZ1 and PZ2. A plurality of compartments (SW) made up of vertically above and below the centerline of the RT) and consisting of a partition plate (SP) to prevent mixing of harmful gases and clean air;

The first and second discharge holes OH1 and OH2 and the inlet hole IH, which are symmetrically formed by the rotation of the rotor RT, are blocked by the first and second purge plates PZ1 and PZ2 to inflow and discharge. When this is not done, the purge device (PE) for blowing up the harmful gas remaining on one side to the combustion chamber (FR) to prevent mixing;

It consists of a drive part RE for rotating the rotor at a predetermined speed.

In addition, the purge device PE includes a plurality of purge pipe lines PP mounted on both lower sides of the partition wall SW, dampers DP provided in the plurality of purge pipe lines PP, and each of the dampers It is configured to further include an opening and closing cylinder (CL) mounted on one side of the DP, and a purge blower (PB) provided at one end of the purge pipe (PP).

However, the above-described horizontally distributed combustion equipment has a problem in that the capacity of the driving unit is increased by rotating the entire rotor formed of an inner tube and an outer tube.

In addition, by providing a separate purge device to prevent the mixing of harmful gas and clean air, the device is complicated, there is a problem that the manufacturing installation cost accordingly is input.

The present invention is devised to solve the above problems, the object of the present invention is to minimize the capacity of the drive unit.

In addition, another object of the present invention is to simply configure the device by preventing the harmful gas and the clean air to be mixed at the source without having a separate purge device.

In addition, another object of the present invention, as described above, to simply form the equipment to form a low cost of manufacturing installation, the throughput is maximized.

Further, by attaching the rotor to the outside, easy maintenance is possible.

1 is an exploded perspective view for explaining the configuration of a conventional horizontal distribution type oxidation combustion equipment,

Figure 2 is a side cross-sectional view of a horizontal distribution type oxidation combustion equipment of the present invention,

3 is a cross-sectional view taken along line “A”-“A” of FIG. 2 for explaining the distribution pipe and the distribution vanes.

Figure 4a is a perspective view showing for explaining the coupling relationship between the present invention distribution pipe and the rotor,

Figure 4b is an exploded perspective view showing in detail for the configuration of the rotor of the present invention,

5 is a cross-sectional view taken along line “B”-“B” of FIG. 4A for explaining the correlation between the first through hole and the rotor of the distribution pipe end;

6 to 9 are cross-sectional views illustrating a process of crossing the flow of harmful gas and clean air by the rotor of the present invention,

10 is a cross-sectional view showing another embodiment of the present invention distribution pipe,

FIG. 11 is a cross-sectional view taken along the line “C”-“C” in FIG. 10.

* Explanation of symbols for the main parts of the drawings

10; combustion chamber 11; combustion burner

20; heat storage layer 100; equipment body

110; distribution chamber 120; distribution pipe

130; plate 200; rotor

300; driving part

The present invention relates to a regenerative oxidation and catalytic oxidation combustion (RCO) system for purifying volatile organic compounds and discharging them into clean air. A distributed regenerative regenerative combustion apparatus.

The present invention is a combustion chamber having at least one combustion burner on the upper side, a heat storage layer provided on the lower side of the combustion chamber, and a plurality of distribution chambers are arranged in the longitudinal direction by a plurality of partition plates mounted at predetermined equal intervals below the heat storage layer. A formed facility body;

A distribution pipe penetrating through the centers of the plurality of distribution chambers, and having a long hole formed at a predetermined isometric angle on an outer periphery of each distribution chamber section, and radially distributing wings are radially mounted between the long holes therein; A distribution chamber in which mixing of harmful gas and clean air is prevented by a diaphragm mounted above and below the distribution pipe;

A supply part provided inside the main duct of one side of the facility body and supplying harmful gas to one side in a cross section coupled to an end of the distribution pipe, a discharge part for discharging clean air to the other side of the supply part, and the supply A rotor formed of a symmetrical shape in the center of the discharge part and purged to pass the respective diaphragms to prevent mixing of harmful gas and clean air;

It comprises a drive unit for rotating the rotor at a predetermined speed.

Hereinafter, with reference to the accompanying drawings illustrating a preferred embodiment of the present invention in detail.

Figure 2 is one side cross-sectional view of a horizontal distribution type oxidation combustion apparatus of the present invention, Figure 3 is a cross-sectional view of the line "A"-"A" shown in Figure 2 for explaining the distribution pipe and the distribution wings, Figure 4a 4 is a perspective view illustrating in detail the configuration of the rotor of the present invention. FIG. 5 is an exploded perspective view illustrating the structure of the rotor of the present invention. FIG. 4A is a cross-sectional view taken along line “B”-“B” of FIG. 4, and FIGS. 6 to 9 are cross-sectional views illustrating a process in which noxious gas and clean air cross each other by the present invention rotor. 10 is a cross-sectional view showing another embodiment of the present invention distribution pipe, and FIG. 11 is a cross-sectional view of the line “C”-“C” in FIG. 10. However, only the symbols are explained.)

As shown in Fig. 2 and Fig. 3, the horizontally distributed regenerative oxidative combustion equipment 1 (hereinafter referred to as "combustion equipment") of the present invention is provided with a heat insulating material 101 of a predetermined thickness inward, and the upper side thereof. It is provided with a rectangular installation body 100 is provided with a combustion chamber 10 and the heat storage layer 20 in order.

A plurality of partition plates 111 are mounted at the lower side of the heat storage layer 20 at equal intervals in the longitudinal direction to form a plurality of compartments 110.

A distribution pipe 120 penetrates through a central portion of the distribution chamber 110 in a longitudinal direction, and one end of the distribution pipe 120 is referred to as a volatile organic compound (VOC) generated from a factory (hereinafter referred to as "harmful gas"). ) Is provided with a supply unit 210 for supplying a rotor 200 and a discharge unit 240 for discharging clean air by burning in the heat storage layer 20 and the combustion chamber 10 of the facility body 100, respectively. (The rotor 200 will be described later.)

Each of the distribution chambers 110 partitioned into a plurality of compartments in the longitudinal direction by the divider 111 is provided with a diaphragm 130 above and below the distribution pipe 120 in a cross-section, and each distribution chamber 110. The first, second, and third blocks (1B, 2B, 3B) on the cross section were separated so that harmful gases and clean air by the rotor 200 to be described later are smoothly discharged without being mixed with each other.

In addition, a plurality of distribution blades 123 are radially mounted inside the distribution pipe 120 so that harmful gas and clean air flowing into the long hole 121 formed on the outer circumference of the distribution pipe 120 are not mixed with each other. It was made to flow.

The long hole 121 is formed in each of the distribution chamber 110 in three directions, that is, 120 degrees in the circumference, as shown in Figure 3, in the first distribution chamber 110 on one side of the facility main body 100 The long holes 121 are formed at positions 1, 5, and 9, and the long holes are formed at positions 2, 6, and 10 in the second distribution chamber 110.

Subsequently, in the third and fourth distribution chambers 110, the long holes 121 formed at positions 3, 7, 11, and 4, 8, and 12 are shifted one by one, respectively, to the first, second, and third blocks 1B. (2B) and 3B, respectively, are provided in each distribution chamber 110, and the gas fluids supplied and discharged are prevented from intermixing.

In addition, on the outer circumference of the distribution pipe 120 protruding to the outside of the facility body 100, a plurality of radial first through holes 122 are formed to be coupled to the rotor 200 to be described later, wherein the first through holes ( 122 is in communication with the radially divided distribution wings 123 and the respective long holes 121 communicating with the distribution blades 123 and to supply the harmful gas and the discharge of clean air for each distribution chamber 110. .

A plurality of distribution blades 123 are mounted inside the distribution pipe 120 to supply harmful gas supplied from the rotor 200 to each distribution chamber 110 in which each long hole 121 is formed. Supplying, purging, and discharging operations are sequentially performed with a predetermined time difference for each chamber by the long holes 121 formed by shifting.

On the other hand, as shown in Figure 4a, the distribution pipe 120 is protruded to one side of the installation body 100 is coupled to the rotor 200 provided in the main duct 201.

At the tip of the main duct 201 is formed a contaminated zone 201a into which noxious gas is introduced by a blower (not shown), and at one side of the contaminated zone 201a, i.e., the rotor 200 to be described later. The clean zone 201b through which the clean air discharged from the air exits is formed, and the polluted zone 201a and the clean zone 201b are different zones, which are mutually formed by the blocking flange 222 of the rotor 200 to be described later. It is separated and mixing is prevented.

As shown in FIG. 4B, the rotor 200 has a second through hole 202a radially formed at a tip thereof, and when viewed from the front, a supply part 210 for supplying harmful gas to one side and the supply part ( The discharge unit 240 formed to discharge the purified air to the other side of the 210, and the symmetrical shape is formed in the center of the supply, discharge unit 210,240 is supplied to the combustion chamber and burned in the combustion chamber An inner tube 202 divided into a purge part 280 to prevent mixing of clean air is provided.

The first flange 203 is mounted at the front end of the inner tube 202, and the first flange 203 is formed in a “C” shape so as to cover only the front end of the discharge part 240 and the purge part 280. It is mounted so as to allow the harmful gas of the contaminated zone 201a to flow into the supply unit 210.

The second through hole 202a is radially formed on the outer circumference of the inner tube 202 which is concentric with the first through hole 122 of the distribution pipe 120 above the first flange 203. The first and second through-holes 122 and 202a communicate with each other, and the harmful gas is formed by the distribution blades 123 mounted inside the distribution pipe 120 and the long holes 122 formed at equal angles 120 degrees in each chamber. And clean air are not mixed with each other, and supply, purge, and discharge operations are sequentially performed in each distribution chamber 100.

The second flange 204 mounted to the rear of the first flange 203 is formed in a ring shape and mounted to the outer circumference of the inner tube 202.

A fan-shaped discharge hole 204a is formed at an outer circumference of the discharge part 240 direction, and a first purge hole 204b is formed at one end of the discharge hole 204a, and is located at the rear of the inner tube 202. The second purge hole 202b is formed.

A third flange 205 is mounted to the rear end of the inner tube 202, and is mounted in a direction opposite to the first flange 203 and is formed in a disc shape to prevent the rear end of the inner tube 202, which is not shown.

As shown, a purge plate 281 is mounted on each side of the purge part 280 formed at a position perpendicular to the inner tube 202 so that the gas between the supply part 210 and the discharge part 240 is provided. The fluid is not mixed and the purge gas is supplied to the first and second purge holes 204b and 202b.

As described above, the fourth flange 206 is mounted on the inner circumference of the inner tube 202 divided into the supply unit 210 and the discharge unit 240 so that the purge fluid introduced into the second purge hole 202b is distributed. It is to be prevented from being introduced into (not shown), and is discharged to the third purge hole 202c formed in the supply unit 210 to be mixed with the newly supplied noxious gas and supplied to the combustion chamber (not shown) again.

Meanwhile, the rotor shaft 230 is mounted in the rear of the rotor 200, that is, in the direction of the third flange 205, so that the rotor 200 is rotated at a predetermined speed by the driving unit 300.

The power transmission means 231 between the drive unit 300 and the rotor shaft 230 may be easily deformed and rotated as much as the manufacturing technology of the art, such as a chain and a sprocket or a belt and a pulley.

The exterior 220 is mounted to the outside of the first, second and third flanges 203, 204 and 205, and the exterior 220 is formed at an end of the first and third flanges 203 and 205. The notching part 221 is formed in the direction which cross | intersects mutually at the line | wire and the rear end so that it may be attached.

In other words, when the exterior 220 is mounted on the outside of the first, second, and third flanges 203, 204, and 205, both sides of the exterior 220 may be opened in a staggered direction with respect to the purge part 280. The supply unit 210 is provided in the contaminated zone 201a of the main duct 201 and the discharge unit 240 is provided in the clean zone 201b.

In addition, the main duct (not shown) is mounted on the outer circumference of the exterior 220 so as to prevent the fluids of the clean zone 201b and the contaminated zone 201a from being mixed with each other. It is in close contact with the flange inside the 201, but does not affect the rotation of the rotor 200.

5 is a cross-sectional view showing a state in which the tip of the rotor 200 and the distribution pipe 120 of the present invention is coupled.

As shown, a purge portion 280 symmetrical in the vertical direction is formed, and the purge portion 280 has a purge operation only in a direction in which the second purge hole 202b is formed, as shown, The site formed at the location is blocked and no action is taken.

On the other hand, the harmful gas is supplied to the distribution pipe 120 through the supply unit 210 of one side of the purge 280, flows through the distribution blades 123 radially mounted in the distribution pipe 120, each distribution It is discharged to the long hole 121 formed in the chamber 110 and passes through the heat storage layer 20 and the combustion chamber 10, which is not shown, and the harmful gas is burned to become clean air.

In addition, the clean air is supplied to the other side of the distribution pipe 120, and is discharged to the discharge hole (204a) of the discharge unit 240 through the distribution blade 123.

Although the direction of the arrow is shown in the direction of supply and discharge to the distal end of the distribution pipe 120, the flow is formed in the opposite direction to the long hole (not shown) of each distribution chamber (110).

Subsequently, as shown in FIGS. 6 to 9, the process of cleaning the noxious gas will be described sequentially.

For convenience of explanation, the cross-section shown shows the first distribution chamber 110, and the long holes 121 formed to be equal to each are described by the 1, 5, and 9 long holes 121, and the arrow indicating the direction in which the fluid flows is also shown for each block. In the display in the direction of the clean air flowing into the long hole 121 of the distribution pipe 120 and the harmful gas flowing out.

In addition, the harmful gas discharged to each long hole 121 of the distribution pipe 120 is supplied to the distribution wing 123 via the supply unit 210 of the rotor 200 shown in, and introduced into each long hole 121. The clean air is discharged to the atmosphere through the discharge hole 204a of the discharge part 240 through the distribution blade 123.

First, the noxious gas supplied to the fifth hole 121 of the distribution pipe 120 through the supply unit 210 of the rotor 200 is the fifth hole 121 formed in the first block 1B of the distribution chamber 110. ) Is passed through the heat storage layer 20 and the combustion chamber 10 of the upper side and is burned and purified by a combustion burner (not shown) of the combustion chamber 10.

The purified clean air flows up to the second heat storage layer 20 and flows to the second block 2B, and is discharged toward the rotor 200 on one side through the ninth hole 121, and the discharged clean air is rotated. It is discharged through the discharge hole (204a) formed in the discharge portion 240 of the (200).

Meanwhile, the clean air flowing to the third block 3B is supplied to the supply unit of the rotor 200 through the first and second purge holes 204b (not shown) and the third purge hole (not shown) of the purge part 280 ( It is re-injected to 210 and moved to the noxious gas and the combustion chamber 10 and burned with cleaner air.

When the purge part 280, which is purged from the third block 3B by the rotation of the rotor 200, passes through the first block 1B and the discharge hole 204a formed at one side is stayed, the first long hole 121 Clean air flowing into the) is naturally discharged to the discharge hole (204a) of the rotor 200.

As described above, when the purge part 280 of the rotor 200 passes through the first hole 121 and exists in the first block 1B, the first block 1B having the fifth hole 121 formed therein is formed. The supply of harmful gas is continued, and clean air is discharged to the third and ninth holes 121, and discharged into the atmosphere through the discharge hole 204a of the rotor 200 shown as a virtual ship.

7 illustrates a purge operation for removing the noxious gas remaining in the first block 1B immediately before the rotor 200 rotates and the purge unit 280 passes over to the second block 2B. It is shown to.

The noxious gas remaining in the first block 1B flows into the fifth hole 121 and is sent to the second block 2B through the purge part 280 of the rotor 200 on one side and supplied to the supply part 210. It is purged to be mixed with the harmful gas and the harmful gas remaining in the first block 1B is removed, and the harmful gas is discharged into the nine holes 121 of the second block 2B.

At this time, the clean air introduced into the first long hole 121 exits the discharge hole 204a of the rotor 200 and is discharged into the atmosphere.

As shown in FIG. 8, when the purge part 280 also crosses the block 2B by the rotation of the rotor 200, the noxious gas supplied to the block 2B is the upper combustion chamber 20. Purified from the purified air is introduced into the first and third blocks (1B, 3B), the long hole 121 and the first hole 121 is introduced into the discharge hole 204a of the rotor 200 Is discharged.

In addition, the purge unit 280 purges the boundary of each block 1B, 2B, and 3B, that is, each time it passes through the diaphragm 130, to each block through which the supply unit 210 of the rotor 200 has passed. The residual harmful gas is removed to prevent mixing of clean air discharged to the discharge part 240 passing after the purge part 280.

Subsequently, FIG. 9 shows that the purge operation occurs before the above-described purge section 280 reaches block 3B.

That is, the noxious gas introduced into the nineth hole 121 of the second block 2B is sent to the third block 3B on one side through the purge 280 and mixed with the noxious gas rising to the combustion chamber 10. .

When the purge part 280 enters the third block 3B, no harmful gas remains in the second block 2B so that the clean air passing through the rotor 200 next time is introduced into the nine holes 121. In addition, the rotor 200 is discharged to the discharge part 240 of the rotor 200 along the distribution blade 123 distributed.

The operation as described above is repeated sequentially in the other distribution chamber (110). In other words, when the above-described operation is repeated in the 1, 5, 9 holes of the first distribution chamber 110, the operation described above in the 2, 6, 10 holes 121 in the distribution chamber 110 on one side. This repetition is performed by raising the temperature of the heat storage layer 20 to be kept constant by the harmful gas and clean air passing through each of the blocks 1B, 2B, and 3B. Even if the combustion burner 11 is not continuously operated, the temperature of the combustion chamber 10 can be maintained at a high temperature.

As shown in Figure 10 and 11, the present invention horizontal distribution type oxidative combustion equipment (1) is a manufacturing technique of the art, in addition to the method in the embodiment described above in addition to the method in the main body 100 in the distribution chamber 110 It is possible to increase and increase the combustion capacity of the rotor 200 on both sides with a larger combustion capacity, and the rotor 200 and the distribution pipe 120 in at least one row in the cross section to burn the harmful gas. Modification can be easily carried out so as to be.

In addition, the combustion combustion equipment (1) having the configuration as described above is a description of the configuration of a conventional regenerative combustion combustion equipment (RTO), if the noble metal catalyst layer is added to the heat storage layer (20) regenerative catalytic oxidation combustion equipment. Can also be used as (RCO).

As described above, the rotating rotor 200 supplies the harmful gas, discharges clean air, and purges the harmful gas remaining in each chamber, thereby simplifying the equipment and increasing its processing efficiency. 100) easy to repair the rotor 200 provided to the outside to increase the operation rate of the facility.

The present invention is not limited to the above-described specific preferred embodiment, and any person having ordinary knowledge in the technical field to which the subject matter belongs without departing from the gist of the present invention claimed in the claims, of course, various modifications are possible. Such modifications are within the scope of the claims of the present invention.

As described above, according to the present invention, by reflowing and purging clean air discharged into the atmosphere to prevent mixing of harmful gas and clean air, there is an effect of preventing the harmful gas from being mixed with clean air.

In addition, by increasing the heat storage area of the heat storage layer, compared with the conventional treatment equipment having the same scale, the throughput of harmful gases is maximized.

In addition, as described above, by dividing the horizontally provided rotor at predetermined equal intervals so that harmful gas and clean air can be introduced and discharged, the size of the equipment is reduced, but the processing efficiency is larger than the size of the compact equipment. There is.

In addition, the rotor is provided horizontally to allow harmful gases and clean air to pass evenly across the heat storage layer, thereby maximizing the thermal efficiency area.

In addition, by providing the rotor outside the facility body, it is easy to maintain and there is an effect of increasing the operation rate of the facility with little trouble.

Claims (4)

In Regenerative Oxidation and Catalytic Oxidation Combustion Facility (R.T.O) (R.C.O), which purifies volatile organic compounds generated at the factory and discharges them to clean air. A main body having a plurality of distribution chambers formed in a longitudinal direction by a combustion chamber including at least one combustion burner on the upper side, a heat storage layer provided on the lower side of the combustion chamber, and a plurality of partition plates mounted on the lower side of the heat storage layer at predetermined equal intervals. Wow; A distribution pipe penetrating through the centers of the plurality of distribution chambers, and having a long hole formed at a predetermined isometric angle on an outer periphery of each distribution chamber section, and radially distributing wings are radially mounted between the long holes therein; A distribution chamber in which mixing of harmful gas and clean air is prevented by a diaphragm mounted above and below the distribution pipe; A supply part provided inside the main duct of one side of the facility body and supplying harmful gas to one side in a cross section coupled to an end of the distribution pipe, a discharge part for discharging clean air to the other side of the supply part, and the supply A rotor formed of a symmetrical shape in the center of the discharge part and purged to pass the respective diaphragms to prevent mixing of harmful gas and clean air; Horizontal distribution regenerative oxidative combustion equipment comprising a drive unit for rotating the rotor at a predetermined speed. The method of claim 1, The rotor includes a plurality of second through holes radially formed at the tip, an inner tube having second and third purge holes formed at the rear of the second through hole, a first flange mounted at the tip of the inner tube, and a rear of the first flange. A second flange formed in a fan shape having a predetermined angle on an outer circumference, and having a first purge hole formed at one end of the discharge hole, a third flange mounted behind the second flange, and the inner tube The diaphragm is formed at positions symmetrically perpendicular to both sides on the center line of the diaphragm, and is mounted on the outer circumferences of the first, second and third flanges, and the notched portions are alternately formed at the line and the rear end so as to be mounted to the ends of the first and third flanges. Horizontal distribution regenerative oxidative combustion equipment comprising a. The method of claim 1, The long hole formed at an equidistant periphery of the distribution pipe is formed in a 120-degree direction in the cross-section of each distribution chamber, each chamber is formed by moving one space, characterized in that the supply, discharge, purge operation of harmful gas sequentially occurs Distributed regenerative oxidative combustion equipment. The method of claim 1, The distribution chamber is horizontally distributed regenerative oxidative combustion equipment, characterized in that divided into three blocks on the cross section so as to facilitate the supply and discharge of harmful gas by the rotation of the rotor by the diaphragm.