WO2016169391A1

WO2016169391A1 - Waste gas incinerator

Info

Publication number: WO2016169391A1
Application number: PCT/CN2016/077527
Authority: WO
Inventors: 刘洋
Original assignee: 刘洋
Priority date: 2015-04-23
Filing date: 2016-03-28
Publication date: 2016-10-27
Also published as: CN104791813A; CN104791813B

Abstract

A waste gas incinerator comprises a base (1), a frame body device (2) located above the base (1), waste gas inlet devices (3) located on the left side and the right side of the frame body device (2), a first heating device (4) located in the frame body device (2), a second heating device (5) located below the first heating device (4), a recovery device (6) located above the first heating device (4), and an oxygen inlet device (7) located below the frame body device (2). Waste gas enters a waste gas inlet pipe (31) from a gas intake pipe (32). Oxygen passes through an oxygen inlet pipe (71) and enters a frame body (21). After the waste gas passes through the waste gas inlet pipe (31) and is converged with the oxygen, the waste gas is ignited. Water enters a heating barrel (41) from a water intake pipe (46) and enters a heating frame (51) from a liquid intake pipe (52), and water in the heating frame (51) and water in the heating barrel (41) are heated by means of combustion of combustible gas. Carbon dioxide generated in the combustion enters a sodium hydroxide solution from an output pipe (63) and reacts with the sodium hydroxide solution to generate calcium carbonate and water. A small amount of gas is discharged through a fifth through hole (64) in the top, the liquid after the reaction is discharged through an outflow pipe (65), water is the heating barrel (41) is discharged through a water outflow pipe (44), and water in the heating frame (51) is discharged through a liquid outflow pipe (54). The waste gas incinerator can sufficiently combust waste gas, utilize hot gas generated when the waste gas is combusted, and prevent energy waste.

Description

Exhaust gas incinerator

Technical field

The invention relates to the technical field of environmental protection, and in particular to an exhaust gas incinerator.

Background technique

Quite a lot of industrial production will produce exhaust gas, which will cause great harm to the human body and pollute the atmosphere. Therefore, it is necessary to treat the exhaust gas into a harmless gas and allow it to be discharged. A considerable amount of exhaust gas is a gaseous organic compound, and the incineration process is the most A common, effective, and lowest cost exhaust gas treatment process.

An exhaust gas incinerator disclosed in Chinese Patent No. CN200420024060.9, comprising a casing, a combustion chamber and a burner, one end of the combustion chamber passing through a column pipe to an exhaust port at the other end of the casing, on the casing The exhaust gas inlet passes through the cavity between the tubes and the cavity between the inner wall of the casing and the outer wall of the combustion chamber to the combustion chamber inlet. The exhaust gas incinerator realizes the preheating of the waste gas to be treated by the combustion heat energy with a simple structure. Therefore, the rational use of thermal energy helps to ensure the combustion treatment effect of the exhaust gas, improve the efficiency, and lower the temperature of the exhaust gas, and has low manufacturing and running costs. However, since the high-temperature flue gas generated by the combustion goes inside the tube and preheats the exhaust gas outside the tube, the temperature of the gas in the tube from the inlet portion of the tube to the outlet portion of the tube is gradually decreased, so the temperature of the outlet portion Lower than the inlet section temperature, therefore, the tube must use a high temperature material suitable for the inlet section, resulting in the material properties of the outlet section tube is higher than the required material requirements. In the market, the high temperature material price is greater than The price of low temperature materials, which in turn leads to increased costs. On the other hand, as the temperature is lowered, the volume of the gas is reduced, so that the flow space of the flue gas required for the outlet section of the tube is smaller than the actual space, thereby causing the outlet end of the flue gas to be bulky, wasting material, and increasing the cost.

Therefore, it is necessary to provide a new technical solution to overcome the above drawbacks.

Summary of the invention

It is an object of the present invention to provide an exhaust gas incinerator which can effectively solve the above technical problems.

In order to achieve the object of the present invention, the following technical solutions are adopted:

An exhaust gas incinerator comprising a base, a frame device located above the base, an exhaust gas inlet device located at left and right sides of the frame device, a first heating device located inside the frame device, located at a second heating device below the first heating device, a recovery device located above the first heating device, and an oxygen inlet device located below the frame device, wherein the base is provided with a first support column, The frame device includes a frame body, a first slanting plate located inside the frame body, a first baffle plate located above the first slanting plate, and a first through hole on the right surface of the frame body. a second through hole and a lower wall above the first through hole, the exhaust gas inlet device includes an exhaust gas inlet pipe, an intake pipe on a side of the exhaust gas inlet pipe, a second baffle plate located inside the exhaust gas inlet pipe, a three-resistance baffle and a filter, the first heating device comprising a heating barrel, a first fixing rod located above the heating barrel, a second fixing rod located below the heating barrel, and a water outlet located on a left side of the heating barrel a tube, a first valve disposed on the outlet pipe, an inlet pipe located at a right side of the heating barrel, and a second valve disposed on the inlet pipe, the second heating device including a heating frame, located at the a liquid inlet pipe on one side of the heating frame, and a liquid inlet pipe disposed on the liquid inlet pipe a third valve, a liquid outlet pipe located below the liquid inlet pipe, a fourth valve disposed on the liquid discharge pipe, and a bump disposed on the heating frame, the recovery device includes a second slanting plate, An intermediate hole located in the middle of the second slanting plate, a lead-out tube located above the second slanting plate, a fifth through hole on the upper surface of the frame body, an outflow pipe on the right side of the frame body, and a fifth valve on the outflow pipe, the oxygen inlet device includes an oxygen inlet pipe and a sixth valve disposed on the oxygen inlet pipe, the frame body is a hollow rectangular parallelepiped, and one end of the first inclined plate Fixedly connected to the inner surface of the frame, the other end of the first slanting plate is inclined upward and toward the middle of the frame, the first baffle plate is vertical, and the upper surface and the lower surface of the first baffle plate The surface of the first baffle is fixedly connected to the upper surface of the first slanting plate, and the upper surface of the first baffle is fixedly connected to the lower surface of the second slanting plate, a baffle plate is made of a heat insulating material, and the lower wall is convex upward to form a a corner block, a top end of the triangular block is provided with a third through hole, the third baffle plate is provided with a rectangular hole penetrating the left and right surfaces thereof, and a water is placed between the second baffle plate and the third baffle plate The bump is horizontally placed, a side of the bump is fixedly connected to the heating frame, the bump is located directly above the triangular block, and the outlet tube is inverted "mountain" type. The outlet ends of the outlet tube are vertically downward and directly above the second slanting plate, and the second slanting plate is provided with a sodium hydroxide solution.

The exhaust gas inlet pipe has a rectangular parallelepiped shape, and the exhaust gas inlet pipe is horizontally placed, and one end of the exhaust gas inlet pipe is fixedly connected to the side surface of the frame body and communicates with the inside of the frame body.

The second baffle plate has a rectangular parallelepiped shape, and the second baffle plate is vertically disposed, and a side surface of the second baffle plate is fixedly connected to an inner surface of the exhaust gas inlet pipe.

The third baffle plate has a rectangular parallelepiped shape, and the third baffle plate is vertically disposed, and a side surface of the third baffle plate is fixedly connected to an inner surface of the exhaust gas inlet pipe.

The filter mesh is in the shape of a rectangular parallelepiped, the filter mesh is placed vertically, and the side of the filter mesh is fixedly connected to the inner surface of the exhaust gas inlet pipe.

The heating barrel is a hollow cylinder, and the heating barrel is horizontally disposed, and the heating barrel is provided with a third through hole and a fourth through hole.

The first fixing rod is inclined, the lower end of the first fixing rod is fixedly connected with the surface of the heating barrel, and the upper end of the first fixing rod is fixedly connected with the lower surface of the second inclined board. The first fixing rod is provided with a first through hole penetrating through the left and right surfaces thereof.

An upper end of the second fixing rod is fixedly connected to a surface of the heating barrel, a lower end of the second fixing rod is fixedly connected to the heating frame, and a second fixing rod is provided with a second portion extending through the left and right surfaces thereof Through hole.

The left end of the outflow tube is aligned with the second through hole and is fixedly connected to the right surface of the frame.

The heating frame has a trapezoidal shape, and the heating frame forms a closed space with an inner surface of the frame, and the heating frame is made of a heat conductive metal material.

Compared with the prior art, the invention has the following beneficial effects: the waste gas incinerator of the invention has the advantages of simple structure, convenient use, full combustion of the exhaust gas, high combustion efficiency, and utilization of the hot gas generated by the combustion of the exhaust gas to prevent energy. Waste, and the present invention can make the sulfur dioxide therein be absorbed before the exhaust gas is burned, so that the exhaust gas in the combustion does not contain sulfur dioxide, so that carbon monoxide or the like therein can be fully burned, and the carbon dioxide after combustion is chemically reacted to prevent It is discharged into the atmosphere Environment, aggravating the greenhouse effect.

DRAWINGS

1 is a schematic view showing the structure of an exhaust gas incinerator of the present invention.

detailed description

The exhaust gas incinerator of the present invention will be clearly and completely described below with reference to the accompanying drawings.

As shown in FIG. 1 , the exhaust gas incinerator of the present invention comprises a base 1 , a frame device 2 located above the base 1 , an exhaust gas inlet device 3 located on the left and right sides of the frame device 2 , and an inside of the frame device 2 . The first heating device 4, the second heating device 5 located below the first heating device 4, the recovery device 6 located above the first heating device 4, and the oxygen inlet device 7 located below the frame device 2.

As shown in FIG. 1 , the base 1 has a rectangular parallelepiped, and the base 1 is horizontally disposed. The base 1 is provided with a first support column 11 , and the first support column 11 is provided with two and respectively located on the left and right sides. The first support column 11 is a rectangular parallelepiped, the first support column 11 is vertically placed, and the lower surface of the first support column 11 is fixedly connected to the upper surface of the base 1, the first support column 11 The upper surface is fixedly coupled to the lower surface of the exhaust gas inlet device 3.

As shown in FIG. 1 , the frame device 2 includes a frame body 21 , a first slanting plate 22 located inside the frame body 21 , a first baffle plate 23 located above the first slanting plate 22 , and a frame body A first through hole 24 on the right surface of the 21, a second through hole 26 and a lower wall 25 above the first through hole 24. The frame body 21 has a hollow rectangular parallelepiped, the frame body 21 is vertically placed, the first through hole 24 has a circular shape, the second through hole 26 has a circular shape, and the first through hole 24 and the first through hole 24 The two through holes 26 allow the outer space of the frame 2 to communicate with the inner space thereof. The first slanting plate 22 is disposed at two sides and is respectively located on the left and right sides. One end of the first slanting plate 22 is fixedly connected to the inner surface of the frame body 21, and the other end of the first slanting plate 22 is upward. And tilted to the middle. The first baffle plate 23 has a vertical shape, and the upper surface and the lower surface of the first baffle plate 23 are inclined, and the lower surface of the first baffle plate 23 is fixedly connected to the upper surface of the first slant plate 22 The first baffle plate 23 is made of a heat insulating material. The lower wall 25 protrudes upward to form a triangular block, and the top end of the triangular block is provided with a third through hole 251, and the third through hole 251 allows the inner space of the frame 21 to communicate with the space below.

As shown in FIG. 1 , the exhaust gas inlet device 3 is provided with two and respectively located on the left and right sides of the frame body 21 , and the exhaust gas inlet device 3 includes an exhaust gas inlet pipe 31 and is located at the side of the exhaust gas inlet pipe 31 . The intake pipe 32, the second baffle plate 33 located inside the exhaust gas inlet pipe 31, the third baffle plate 34 and the filter net 36. The exhaust gas inlet pipe 31 has a rectangular parallelepiped shape, and the exhaust gas inlet pipe 31 is horizontally placed. One end of the exhaust gas inlet pipe 31 is fixedly connected to the side surface of the frame body 21 and communicates with the inside of the frame body 21. The second baffle plate 33 has a rectangular parallelepiped shape, the second baffle plate 33 is vertically disposed, and the side surface of the second baffle plate 33 is fixedly connected to the inner surface of the exhaust gas inlet pipe 31, and the second baffle plate 33 is The right surface is in the same vertical plane as the right surface of the exhaust gas inlet pipe 31. The third baffle plate 34 has a rectangular parallelepiped shape, and the third baffle plate 34 is vertically disposed. The side surface of the third baffle plate 34 is fixedly connected to the inner surface of the exhaust gas inlet pipe 31, and the third baffle plate 34 is 34. A rectangular hole 35 is formed through the left and right surfaces thereof. The rectangular hole 35 has a rectangular parallelepiped shape, and water is placed between the second baffle plate 33 and the third baffle plate 34 to fuse the sulfur dioxide in the exhaust gas with water. . The filter net 36 is in the shape of a rectangular parallelepiped, and the filter net 36 is placed vertically. The side surface of the filter net 36 and the inner surface of the exhaust gas inlet pipe 31 The surface is fixedly connected. The intake pipe 32 is L-shaped, one end of the intake pipe 32 extends through the left and right surfaces of the second baffle plate 33 to the inside of the exhaust gas inlet pipe 31, and the intake pipe 32 passes through the second The left and right surfaces of the lower end of the barrier 33.

As shown in FIG. 1, the first heating device 4 includes a heating tub 41, a first fixing rod 42 located above the heating tub 41, and a second fixing rod 43 located below the heating tub 41, located at the heating An outlet pipe 44 on the left side of the tub 41, a first valve 45 disposed on the outlet pipe 44, an inlet pipe 46 on the right side of the heating tub 41, and a second valve 47 disposed on the inlet pipe 46. The heating tub 41 is a hollow cylinder, and the heating tub 41 is horizontally disposed. The heating tub 11 is provided with a third through hole 411 and a fourth through hole 412. The third through hole 411 is circular. The fourth through hole 412 is located below the heating tub 41, and the fourth through hole 412 is located below the heating tub 41. The first fixing rod 42 is provided with two and respectively located on the left and right sides, the first fixing rod 42 is inclined, and the lower end of the first fixing rod 42 is fixedly connected with the surface of the heating barrel 41. The first fixing rod 42 is provided with a first through hole 421 penetrating the left and right surfaces thereof, and the first through hole 421 has a rectangular parallelepiped shape. The second fixing rod 43 is provided with two and respectively located on the left and right sides, the upper end of the second fixing rod 43 is fixedly connected with the surface of the heating barrel 41, and the second fixing rod 43 is provided with a through The second through holes 431 of the left and right surfaces have a rectangular parallelepiped shape. The left end of the water inlet pipe 46 extends through the right surface of the frame body 21 to the inside of the frame body 21, and the left end of the water inlet pipe 46 is aligned with the third through hole 411 and with the heating barrel 41. The surface is fixedly coupled such that the interior of the heating tub 41 communicates with the interior of the inlet pipe 46. The second valve 47 is disposed on the water inlet pipe 46 for controlling the flow rate of water in the water inlet pipe 46. The effluent The right end of the tube 44 extends through the left surface of the frame 21 to the inside of the frame body 21, and the right end of the water outlet pipe 44 is aligned with the fourth through hole 412 and fixed to the surface of the heating barrel 41. The connection is such that the inside of the heating tub 41 communicates with the inside of the outlet pipe 44. The first valve 45 is disposed on the water outlet pipe 44 for controlling the flow rate of water in the water outlet pipe 44.

As shown in FIG. 1 , the second heating device 5 is provided with two and respectively located on the left and right sides, and the second heating device 5 includes a heating frame 51 , a liquid inlet tube 52 on a side of the heating frame 51 , a third valve 53 disposed on the inlet pipe 52, an outlet pipe 54 located below the inlet pipe 52, a fourth valve 55 disposed on the outlet pipe 54, and a heating frame disposed on the heating frame A bump 56 on 51. The heating frame 51 has a trapezoidal shape, and the heating frame 51 forms a closed space with the side wall of the frame body 21. The heating frame 51 is made of a heat conductive metal material, and the heating frame 51 and the frame are The inner surface of the body 21 is fixedly connected. The inlet pipe 52 is L-shaped, and one end of the inlet pipe 52 extends through the side of the frame 21 to the inside of the heating frame 51, so that the inside of the heating frame 51 and the liquid inlet The interior of the tube 52 is in communication. The third valve 53 is disposed on the inlet pipe 52 for controlling the flow rate of the liquid in the inlet pipe 52. The left end of the liquid outlet tube 54 is aligned with the first through hole 24 and is fixedly connected to the side surface of the frame body 21 such that the inside of the heating frame 51 communicates with the inside of the liquid outlet tube 54. The fourth valve 55 is disposed on the liquid discharge pipe 54 for controlling the outflow amount of the liquid in the liquid discharge pipe 54. The bumps 56 are horizontally placed, and one side of the bumps 56 is fixedly connected to the heating frame 51, and the bumps 56 are located directly above the triangular blocks. The lower surface of the second fixing rod 43 is fixedly coupled to the upper surface of the heating frame 51.

As shown in FIG. 1, the recovery device 6 includes a second slanting plate 61, an intermediate hole 62 located in the middle of the second slanting plate 61, and a discharge tube 63 located above the second slanting plate 61. A fifth through hole 64 on the upper surface of the body 21, an outflow pipe 65 on the right side of the frame body 21, and a fifth valve 66 provided on the outflow pipe 65. The second slanting plate 61 is disposed at two sides and is respectively located on the left and right sides. One end of the second slanting plate 61 is fixedly connected to the inner surface of the frame body 21, and the other end of the second slanting plate 61 is upward. And extending to the middle, the upper end of the first fixing rod 42 is fixedly connected to the lower surface of the second slanting plate 61, and the upper surface of the first blocking plate 23 is fixed to the lower surface of the second slanting plate 61. connection. The outlet tube 63 has an inverted "mountain" shape, and the outlet tube 63 is connected to the intermediate hole 62 so that the air below the second slanting plate 61 can enter the inside of the outlet tube 63. The outlet ends of the outlet pipe 63 are vertically downward and aligned directly above the second swash plate 61. A sodium hydroxide solution is placed on the second slanting plate 61, and outlets of both ends of the outlet pipe 63 extend into the sodium hydroxide solution, so that gas flowing out from the inside of the outlet pipe 63 can react with sodium hydroxide. To prevent it from being directly discharged to the outside world, resulting in a greenhouse effect. The left end of the outflow pipe 65 is aligned with the second through hole 26 and is fixedly connected to the right surface of the frame 21 such that a space above the second slanting plate 61 communicates with an inner space of the outflow pipe 65. . The fifth valve 66 is disposed on the outflow pipe 65 for controlling the flow rate of the liquid in the outflow pipe 65.

As shown in FIG. 1, the oxygen inlet device 7 includes an oxygen inlet pipe 71 and a sixth valve 72 disposed on the oxygen inlet pipe 71. The oxygen inlet pipe 71 is L-shaped, and the oxygen inlet pipe 71 is aligned with the third through hole 251 and is fixedly connected to the lower surface of the lower wall 25. The sixth valve 72 is disposed on the oxygen inlet pipe 71 for control The flow rate of oxygen in the oxygen inlet pipe 71.

As shown in Fig. 1, when the exhaust gas incinerator of the present invention is used, the exhaust gas is first introduced from the intake pipe 32 to enter the inside of the exhaust gas inlet pipe 31. At the same time, oxygen is supplied from the oxygen inlet pipe 72, and the oxygen passes through the oxygen inlet pipe 72 and passes through the third through hole 251 to enter the inside of the casing 21. The exhaust gas enters between the second baffle plate 33 and the third baffle plate 34, the sulfur dioxide in the exhaust gas is fused with water, and then the other exhaust gas enters the deep portion of the exhaust gas inlet pipe 31 through the rectangular hole 35, and then is filtered. After the filtering action of the net 36, it enters above the third through hole 251, and merges with oxygen, and then ignites the exhaust gas, and the combustible gas such as carbon monoxide starts to burn, and the combustible gas can be fully combusted due to sufficient oxygen. At this time, water is introduced from the inlet pipe 46 into the heating tub 41 and from the inlet pipe 52 into the inside of the heating frame 51, and then the combustion of the combustible gas heats the water inside the heating frame 51 and the water in the heating tub 41. Until the combustion is completed, the carbon dioxide generated by the combustion enters the outlet pipe 63 from the intermediate hole 62, then enters the sodium hydroxide solution above the second slanting plate 61 and reacts with it to produce calcium carbonate and water, and a small amount of gas can pass through the fifth pass. The hole 64 is discharged, and its damage to the environment is already small. After the reaction is completed, it is discharged through the outflow pipe 65, and the water in the heating tub 41 is discharged through the outlet pipe 44, and the water in the heating frame 51 is discharged through the discharge pipe 55. The invention not only can reduce the pollution of the exhaust gas to the environment, but also can fully utilize the exhaust gas, save energy, protect the environment, and make the amount of gas discharged small, which meets the requirements of energy saving and emission reduction now. So far, the use process of the exhaust gas incinerator of the present invention has been described.

The foregoing is only a specific embodiment of the present invention, but the scope of protection of the present invention is not limited thereto, and any person skilled in the art is within the technical scope disclosed by the present invention. Variations or substitutions are readily conceivable within the scope of the invention. Therefore, the scope of the invention should be determined by the scope of the appended claims.

Claims

An exhaust gas incinerator, characterized in that: the exhaust gas incinerator comprises a base, a frame device located above the base, an exhaust gas inlet device located at left and right sides of the frame device, and a first inside the frame device a heating device, a second heating device located below the first heating device, a recovery device located above the first heating device, and an oxygen inlet device located below the frame device, wherein the base is provided with a first support a frame body, the frame device includes a frame body, a first slanting plate located inside the frame body, a first baffle plate located above the first slant plate, and a first through hole on a right surface of the frame body a second through hole and a lower wall above the first through hole, the exhaust gas inlet device includes an exhaust gas inlet pipe, an intake pipe on a side of the exhaust gas inlet pipe, and a second inner portion of the exhaust gas inlet pipe a baffle plate, a third baffle plate and a filter net, the first heating device comprising a heating barrel, a first fixing rod located above the heating barrel, a second fixing rod located below the heating barrel, and the heating An outlet pipe on the left side of the barrel, a first valve disposed on the outlet pipe, an inlet pipe on the right side of the heating barrel, and a second valve disposed on the inlet pipe, the second heating device including heating a frame, a liquid inlet pipe on one side of the heating frame, a third valve disposed on the liquid inlet pipe, a liquid outlet pipe located below the liquid inlet pipe, and a fourth pipe disposed on the liquid discharge pipe a valve and a bump disposed on the heating frame, the recovery device includes a second slanting plate, an intermediate hole located between the second slanting plates, and a discharge tube located above the second slanting plate, located at the a fifth through hole on the upper surface of the frame, an outflow pipe on the right side of the frame body, and a fifth valve disposed on the outflow pipe, the oxygen inlet device includes an oxygen inlet pipe and is disposed on the oxygen inlet pipe The sixth valve above, the frame is hollow and long a square body, one end of the first slanting plate is fixedly connected to the inner surface of the frame body, the other end of the first slanting plate is inclined upward and toward the middle of the frame body, and the first blocking plate is vertical. The upper surface and the lower surface of the first baffle plate are inclined, and the lower surface of the first baffle plate is fixedly connected to the upper surface of the first slanting plate, and the upper surface of the first baffle plate and the second surface The lower surface of the swash plate is fixedly connected, the first baffle plate is made of a heat insulating material, the lower wall protrudes upward to form a triangular block, and the top end of the triangular block is provided with a third through hole, the third The baffle plate is provided with a rectangular hole penetrating the left and right surfaces thereof, water is placed between the second baffle plate and the third baffle plate, the bump is horizontally placed, and one side of the bump and the heating frame a fixed connection, the bump is located directly above the triangular block, the outlet tube is in an inverted "mountain" shape, and the outlet ends of the outlet tube are vertically downward and located at the second inclined plate Directly above, a sodium hydroxide solution is placed on the second inclined plate.
The exhaust gas incinerator according to claim 1, wherein the exhaust gas inlet pipe has a rectangular parallelepiped shape, the exhaust gas inlet pipe is horizontally placed, and one end of the exhaust gas inlet pipe is fixedly connected to a side surface of the frame body and The inside of the frame communicates.
The exhaust gas incinerator according to claim 2, wherein the second baffle plate has a rectangular parallelepiped shape, and the second baffle plate is vertically placed, the side of the second baffle plate and the inside of the exhaust gas inlet pipe The surface is fixedly connected.
The exhaust gas incinerator according to claim 3, wherein the third baffle plate has a rectangular parallelepiped shape, and the third baffle plate is vertically placed, the side of the third baffle plate and the inside of the exhaust gas inlet pipe The surface is fixedly connected.
The exhaust gas incinerator according to claim 4, wherein the filter mesh has a rectangular parallelepiped, the filter mesh is placed vertically, and the side of the filter mesh and the inside of the exhaust gas inlet pipe The surface is fixedly connected.
The exhaust gas incinerator according to claim 5, wherein the heating barrel has a hollow cylinder, and the heating barrel is horizontally disposed, and the heating barrel is provided with a third through hole and a fourth through hole.
The exhaust gas incinerator according to claim 6, wherein the first fixing rod is inclined, and the lower end of the first fixing rod is fixedly connected to the surface of the heating barrel, and the first fixing rod is The upper end is fixedly connected to the lower surface of the second slanting plate, and the first fixing rod is provided with a first through hole penetrating the left and right surfaces thereof.
The exhaust gas incinerator according to claim 7, wherein an upper end of the second fixing rod is fixedly connected to a surface of the heating barrel, and a lower end of the second fixing rod is fixedly connected to the heating frame. The second fixing rod is provided with a second through hole penetrating the left and right surfaces thereof.
The exhaust gas incinerator according to claim 8, wherein a left end of said outflow pipe is aligned with said second through hole and is fixedly coupled to a right surface of said frame.
The exhaust gas incinerator according to claim 9, wherein the heating frame has a trapezoidal shape, and the heating frame forms a closed space with an inner surface of the frame, and the heating frame is made of a heat conductive metal material. to make.