CN112361353A

CN112361353A - Air supply structure of hazardous waste incineration rotary kiln

Info

Publication number: CN112361353A
Application number: CN202011270112.0A
Authority: CN
Inventors: 胡茂丽; 郑伟; 朱庆毅; 马泽洲; 邓波
Original assignee: Xinzhongtian Environmental Protection Co ltd
Current assignee: Xinzhongtian Environmental Protection Co ltd
Priority date: 2020-11-13
Filing date: 2020-11-13
Publication date: 2021-02-12

Abstract

The invention relates to the technical field of hazardous waste incineration, and particularly discloses an air supply structure of a hazardous waste incineration rotary kiln, which comprises a support frame, a rotary drum and a kiln head cover, wherein the rotary drum is rotatably connected to the support frame, the kiln head cover is fixed on the support frame, the rotary drum is rotatably and hermetically connected with the kiln head cover, the kiln head cover is cylindrical, a main air hole and an auxiliary air hole are formed in the side wall of the kiln head cover, the main air hole is formed in the top of the kiln head cover, the main air hole and the auxiliary air hole are not in the same circumferential line of the kiln head cover, the main air hole is arranged close to the rotary drum, and the auxiliary air. The air feed structure that this patent provided passes through the model simulation, and the air surplus coefficient control that burns useless the danger comes the air-conditioning's supply volume between 0.8 ~ 1.0, calculates the rotatory torrent flow field that obtains this scheme, can make the useless burning of danger of rotary kiln burn the thermal ignition rate and be less than 3%, and under the surplus coefficient prerequisite that can guarantee to hang down, can also guarantee to hang down much thermal ignition rate, the improvement combustion rate.

Description

Air supply structure of hazardous waste incineration rotary kiln

Technical Field

The invention relates to the technical field of hazardous waste incineration, in particular to an air supply structure of a hazardous waste incineration rotary kiln.

Background

A large amount of domestic garbage, waste and the like are produced every day in China, most of the domestic garbage and waste contain toxic and harmful substances, and if the domestic garbage and waste is randomly discharged, the environment is polluted. Therefore, the hazardous waste is disposed of before being discharged. At present, the rotary kiln is mainly used for burning the dangerous waste, wherein the thermal ignition loss rate of the ash slag after the dangerous waste is burned is the most powerful basis for judging whether the rotary kiln is normal or not, and the burning completion condition can be calculated.

Generally, if air introduced into the rotary kiln cannot be sufficiently diffused, a formed flow field is not completely covered, the moving speed along the axis of the rotary kiln is too high, and the like, the thermal ignition loss rate is improved, that is, the complete combustion of hazardous wastes cannot be ensured, but the conventional method at present is to improve the air supply amount, but the air excess coefficient of the rotary kiln is too high, so that a large amount of heat is lost, for example, in the current common process, a wind hole is formed in the top of a kiln head cover, and air is supplied, and in order to ensure that the thermal ignition loss rate is within the range of 5% -8%, the air excess coefficient of the rotary kiln reaches 1.5-2.0, so that the important research subject of the hazardous waste incineration rotary kiln needs to ensure both the low thermal ignition loss rate and the low air excess coefficient at present.

Disclosure of Invention

The invention provides an air supply structure of a hazardous waste incineration rotary kiln, which not only ensures the low heat ignition loss rate of the rotary kiln, but also ensures the low excess air system of the rotary kiln and reduces the heat loss.

In order to achieve the purpose, the technical scheme of the invention is as follows:

danger is useless burns rotary kiln air feed structure, including support frame, rotary drum and kiln hood cover, the rotary drum rotates to be connected on the support frame, and the kiln hood cover is fixed on the support frame, and the rotary drum rotates sealing connection with the kiln hood cover, the kiln hood cover is the cylinder, is equipped with main wind hole and vice wind hole on the lateral wall of kiln hood cover, main wind hole is located the top of kiln hood cover, and main wind hole and vice wind hole are not on the same circumference line of kiln hood cover, and main wind hole is close to the rotary drum setting, and the setting of rotary drum one side is kept away from to vice wind hole.

The technical principle and the effect of the technical scheme are as follows:

1. in the scheme, after the temperature in the rotary drum rises to a preset value, air is supplied into the kiln head cover from the main air hole and the auxiliary air hole at the same time, the air speed of the kiln head cover is consistent with that of the main air hole and the auxiliary air hole, and the air entering from the main air hole and the auxiliary air hole spirally advances along the inner wall of the rotary drum due to the fact that the outer wall of the kiln head cover is cylindrical, and a stable rotating turbulent flow field is formed in the rotary drum.

In addition, through model simulation, the air excess coefficient of dangerous waste incineration is controlled to be between 0.8 and 1.0 to adjust the air supply amount, the dangerous waste incineration heat ignition reduction rate of the rotary kiln can be lower than 3% through the rotating turbulent flow field obtained by the scheme, and therefore the scheme can guarantee the lower heat ignition reduction rate and improve the combustion rate on the premise of guaranteeing the low excess coefficient.

2. The principle of the scheme that the low heat ignition reduction rate of the rotary kiln can be ensured, the low air excess system of the rotary kiln is also ensured, and the heat loss is reduced is that the fed air advances spirally in the rotary drum, and the rotary flow field formed by entering from the main air hole is found through calculation of a power field model, and the strength of the flow field between adjacent spirals is relatively weak, so that the inventor carries out research and design according to the principle, and the auxiliary air hole is arranged on the kiln head cover to reinforce the rotary flow field of the main air hole, so that the radial uniformity of the flow field in the rotary drum is improved.

Furthermore, the rotary drum is arranged obliquely, and one end of the rotary drum close to the kiln head cover is higher than the other end of the rotary drum.

Has the advantages that: the arrangement is convenient for hazardous wastes to continuously move forward along the rotary drum in the incineration process.

Furthermore, the vertical distance between the main air hole and the auxiliary air hole is D, the aperture of the main air hole is D, and D is not less than D and is less than 2D.

Has the advantages that: through simulation calculation, when the vertical distance D is smaller than the aperture D of the main air hole or exceeds twice the aperture D, the burning rate of the dangerous waste incineration heat of the rotary kiln exceeds 5% when the air excess coefficient of the dangerous waste incineration is controlled to be 0.8-1.0 to control the air supply amount, and therefore, the reinforcing effect of the spiral air flow formed by the auxiliary air hole is poor outside the range.

Further, the auxiliary air hole is formed in the top of the kiln head cover.

Has the advantages that: through model simulation calculation, the air excess coefficient of the dangerous waste incineration is controlled to be 0.8-1.0 to control the air supply amount, and the burning reduction rate of the dangerous waste incineration heat of the rotary kiln is lower than 3%.

Further, the auxiliary air hole is formed in the middle of the kiln head cover.

Further, the auxiliary air hole is formed in the bottom of the kiln head cover.

Furthermore, a flow guide sleeve is fixed in the kiln head cover, the flow guide sleeve and the outer wall of the kiln head cover are coaxially arranged, and the auxiliary air hole is located on the flow guide sleeve along the radial projection of the outer wall.

Has the advantages that: the air entering from the auxiliary air hole is arranged, so that spiral air flow can be better formed under the action of the flow guide sleeve, and the air flow discharged from the main air hole is better reinforced.

Drawings

FIG. 1 is a schematic structural view of an embodiment 1 of an air supply structure of a hazardous waste incineration rotary kiln of the invention;

FIG. 2 is a schematic structural view of an air supply structure of a rotary kiln for hazardous waste incineration according to embodiment 3 of the present invention;

FIG. 3 is a schematic structural view of an air supply structure embodiment 4 of the hazardous waste incineration rotary kiln of the present invention;

fig. 4 is a schematic structural view of an air supply structure of a hazardous waste incineration rotary kiln in embodiment 5 of the invention.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the kiln head comprises a support frame 10, a rotary drum 11, a kiln head cover 12, a main air hole 13, an auxiliary air hole 14 and a flow guide sleeve 15.

Example 1:

substantially as shown in figure 1: dangerous useless rotary kiln air feed structure that burns, including support frame 10, rotary drum 11 and kiln hood cover 12, wherein rotary drum 11 rotates to be connected on support frame 10, and kiln hood cover 12 is fixed on support frame 10, for rotating sealing connection between rotary drum 11 and the kiln hood cover 12, and rotary drum 11 sets up for the slope, and rotary drum 11 is close to kiln hood cover 12 one end and will be higher than the other end.

The kiln head cover 12 comprises a cylindrical outer wall and end covers connected to two ends of the outer wall, a main air hole 13 and an auxiliary air hole 14 are arranged on the outer wall of the kiln head cover 12, wherein the main air hole 13 is located at the top of the outer wall, the main air hole 13 and the auxiliary air hole 14 are circular holes, the aperture of the main air hole 13 is larger than that of the auxiliary air hole 14, the main air hole 13 and the auxiliary air hole 14 are arranged in a staggered mode, namely, the main air hole 13 and the auxiliary air hole 14 are not located on the same circumferential line of the kiln head cover 12, the main air hole 13 is close to the rotary drum 11, the auxiliary air hole 14 is far away from one side of the rotary drum 11, the aperture of the main air hole 13 is set to be D, the vertical distance between the main air hole 13 and the auxiliary air hole 14 is D, D is not more than or less than 2D, the linear distance between the main air hole 13 and the auxiliary air hole 14 is L, D is D in the embodiment.

In operation, when the temperature in the rotary drum 11 rises to a preset value, air is simultaneously supplied into the kiln head cover 12 from the main air hole 13 and the auxiliary air hole 14, and the air speeds of the two are consistent, and because the outer wall of the kiln head cover 12 is cylindrical, the air entering from the main air hole 13 and the auxiliary air hole 14 spirally advances along the inner wall of the rotary drum 11, and a stable rotary turbulent flow field is formed in the rotary drum 11.

Through model simulation, the air excess coefficient that burns dangerously is controlled and is adjusted the air supply volume between 0.8 ~ 1.0, and the rotatory torrent flow field that obtains through the scheme of this embodiment for the dangerously of rotary kiln is burnt hot and is reduced the rate and be less than 3% useless, and it can also guarantee to hang down much hot and reduce the rate, improves the combustion rate under the scheme of this embodiment can guarantee the surplus coefficient prerequisite of low.

Example 2:

the difference from embodiment 1 is that D ═ 1.5D in this embodiment; through model simulation calculation, a conclusion similar to that in example 1 is obtained, namely the air excess coefficient of the dangerous waste incineration is controlled to be 0.8-1.0 to control the air feeding amount, and the burning reduction rate of the dangerous waste incineration of the rotary kiln is lower than 3%.

Example 3:

referring to fig. 2, the difference from embodiment 1 is that the auxiliary air hole 14 is located at the middle of the outer wall in this embodiment; through model simulation calculation, a conclusion similar to that in example 1 is obtained, namely the air excess coefficient of the dangerous waste incineration is controlled to be 0.8-1.0 to control the air feeding amount, and the burning reduction rate of the dangerous waste incineration of the rotary kiln is lower than 3%.

Example 4:

referring to fig. 3, the difference from embodiment 1 is that the secondary air hole 14 is located at the bottom of the outer wall in this embodiment; through model simulation calculation, a conclusion similar to that in example 1 is obtained, namely the air excess coefficient of the dangerous waste incineration is controlled to be 0.8-1.0 to control the air feeding amount, and the burning reduction rate of the dangerous waste incineration of the rotary kiln is lower than 3%.

Example 5:

referring to fig. 4, the difference from embodiment 1 is that in this embodiment, a flow guide sleeve 15 is fixed in the kiln head cover 12, wherein the flow guide sleeve 15 is coaxially arranged with the outer wall of the kiln head cover 12, and the secondary air holes 14 are located on the flow guide sleeve 15 along the radial projection of the outer wall, so that the air entering from the secondary air holes 14 is arranged, and under the action of the flow guide sleeve 15, a spiral air flow can be better formed, and the air flow discharged from the primary air holes 13 can be better reinforced.

The foregoing is merely an example of the present invention and common general knowledge of known specific structures and features of the embodiments is not described herein in any greater detail. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims

1. Danger is useless burns rotary kiln air feed structure, including support frame, rotary drum and kiln hood cover, the rotary drum rotates to be connected on the support frame, and the kiln hood cover is fixed on the support frame, and the rotary drum rotates sealing connection, its characterized in that with the kiln hood cover: the kiln head cover is cylindrical, a main air hole and an auxiliary air hole are formed in the side wall of the kiln head cover, the main air hole is located at the top of the kiln head cover, the main air hole and the auxiliary air hole are not located on the same circumferential line of the kiln head cover, the main air hole is close to the rotary drum, and the auxiliary air hole is far away from one side of the rotary drum.

2. The air supply structure of the hazardous waste incineration rotary kiln as claimed in claim 1, wherein: the rotary drum is arranged in an inclined mode, and one end, close to the kiln head cover, of the rotary drum is higher than the other end of the rotary drum.

3. The air supply structure of the hazardous waste incineration rotary kiln as claimed in claim 1, wherein: the vertical distance between the main air hole and the auxiliary air hole is D, the aperture of the main air hole is D, and D is not less than 2D.

4. The air supply structure of the hazardous waste incineration rotary kiln as claimed in claim 1, wherein: the auxiliary air hole is positioned at the top of the kiln head cover.

5. The air supply structure of the hazardous waste incineration rotary kiln as claimed in claim 1, wherein: the auxiliary air hole is positioned in the middle of the kiln head cover.

6. The air supply structure of the hazardous waste incineration rotary kiln as claimed in claim 1, wherein: the auxiliary air hole is positioned at the bottom of the kiln head cover.

7. The air supply structure of the hazardous waste incineration rotary kiln as claimed in claim 1, wherein: a flow guide sleeve is fixed in the kiln head cover, the flow guide sleeve and the outer wall of the kiln head cover are coaxially arranged, and the auxiliary air hole is located on the flow guide sleeve along the radial projection of the outer wall.