CN212167405U

CN212167405U - Reactor for thermal roasting oxidation process

Info

Publication number: CN212167405U
Application number: CN202020139548.5U
Authority: CN
Inventors: 冯涛
Original assignee: Chongqing Hengrui Kiln And Furnace Engineering Co ltd
Current assignee: Chongqing Hengrui Kiln And Furnace Engineering Co ltd
Priority date: 2020-01-21
Filing date: 2020-01-21
Publication date: 2020-12-18
Anticipated expiration: 2030-01-21

Abstract

The utility model discloses a reactor for hot oxidation process of accompanying and burning, including the reactor body, reactor body top intermediate position is provided with the mounting bracket, mounting bracket top intermediate position is provided with the motor, just be located the inboard cover of mounting bracket on the output shaft of motor and be equipped with first conical gear, the mounting bracket bilateral symmetry alternates and is provided with the drive shaft, the one end of drive shaft and the inboard cover that is located the mounting bracket are equipped with the second conical gear with first conical gear engaged with, the other end of drive shaft and the outside cover that is located the mounting bracket are equipped with third conical gear, the both sides of mounting bracket and the below symmetry that is located the drive shaft are provided with the mount, the inside interlude of axle sleeve is provided with the (mixing) shaft, the top cover of (mixing) shaft is equipped with the fourth conical gear engaged with third conical gear, the bottom of (mixing) shaft runs through the reactor body and is. Has the advantages that: so that the materials in the reactor body are stirred more fully.

Description

Reactor for thermal roasting oxidation process

Technical Field

The utility model relates to a chemical industry equipment particularly, relates to a reactor that is used for hot oxidation process of accompanying burning.

Background

A reactor is a reaction device commonly used in the chemical field, in which substances are reacted to generate new substances or to change the properties of the substances. A reactor for a thermal co-combustion oxidation process in the prior art comprises a shell, wherein a reaction cavity is arranged in the shell, and a feed inlet and a discharge outlet are also arranged on the shell. In order to improve the reaction efficiency of the substance in the reaction chamber, the reactor in the prior art is generally rotationally connected to a frame, a driving machine for driving the reactor to rotate is arranged on the frame, and the reactor rotates around an axis under the driving of the driving machine so as to improve the reaction efficiency of the substance. The reactor for the thermal roasting oxidation process has a simple structure, and can improve the reaction efficiency of substances to a certain extent, but the improvement of the reaction efficiency of the substances is not obvious, so that the reactor in the prior art has the technical problem of low reaction speed.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

To the problems in the related art, the utility model provides a reactor for hot cofiring oxidation technology to overcome the above-mentioned technical problem that current related art exists.

Therefore, the utility model discloses a specific technical scheme as follows:

a reactor for a thermal combustion process comprises a reactor body, wherein a mounting frame is arranged at the middle position of the top end of the reactor body, a motor is arranged at the middle position of the top end of the mounting frame, a first bevel gear is sleeved on an output shaft of the motor and positioned at the inner side of the mounting frame, a driving shaft is symmetrically and alternately arranged on one end of the driving shaft, a second bevel gear meshed with the first bevel gear is sleeved on the inner side of the mounting frame, a third bevel gear is sleeved at the other end of the driving shaft and positioned at the outer side of the mounting frame, fixing frames are symmetrically arranged at the two sides of the mounting frame and positioned below the driving shaft, a shaft sleeve is arranged at one end of the fixing frame far away from the mounting frame, a stirring shaft is alternately arranged inside the shaft sleeve, a fourth bevel gear meshed with the third bevel gear is sleeved at the top end of the stirring shaft, the bottom end of the stirring shaft penetrates through the reactor body and is connected with a stirring mechanism arranged in the reactor body.

Furthermore, in order to enable the stirring blade to swing around the sliding groove while rotating around the limiting column, so that the stirring blade is in more sufficient contact with the materials in the reactor body, and further the reaction rate of the reactor is further improved, the stirring mechanism comprises a rotating frame connected with the bottom end of the stirring shaft, the limiting column is arranged in the rotating frame, a first fixing column is arranged at the bottom end of the limiting column, the bottom end of the first fixing column penetrates through the rotating frame and is connected with the inner wall of the reactor body, a second fixing column is arranged at the middle position of the top end in the rotating frame, a bearing matched with the bottom end of the second fixing column is arranged at the top end of the limiting column, a plurality of sliding grooves are uniformly arranged on the side wall of the limiting column from top to bottom, a sliding block is arranged in each sliding groove, and one side of the sliding block, which is far away, the other end of the L-shaped connecting rod is connected with one end of a rotating shaft which is arranged on the rotating frame in an inserting mode, and the other end of the rotating shaft is provided with stirring blades.

Furthermore, in order to enable the sliding block to reciprocate up and down around the sliding groove and further enable the sliding block to drive the stirring blade to swing around the sliding groove, the sliding groove is composed of a first horizontal section, a second horizontal section and an inclined section, and the first horizontal section is located below the second horizontal section.

Furthermore, in order to enable the sliding block to move up and down in a reciprocating mode around the sliding groove and further enable the sliding block to drive the stirring blades to swing around the sliding groove, the first horizontal section and the second horizontal section are respectively located on two sides of the limiting column, and the first horizontal section and the second horizontal section are connected end to end through the two groups of inclined sections.

Furthermore, in order to improve the strength of the stirring blade and further prolong the service life of the stirring blade, reinforcing ribs are arranged at the transverse middle positions of the two sides of the stirring blade.

Further, in order to increase the resistance between stirring vane and the inside material of reactor body, and then make stirring vane and the inside material contact of reactor body more abundant, and then further improve the reaction rate of reactor, stirring vane's both sides just are located a plurality of X shape flutings have all been seted up respectively to the both sides of strengthening rib, a plurality of damping pieces evenly are provided with inside the X shape fluting.

The utility model has the advantages that:

1. through setting up a set of first bevel gear and two sets of second bevel gear to make the direction of rotation of two sets of (mixing) shafts opposite, and then make the inside two sets of rabbling mechanisms' of reactor body direction of rotation opposite, and then make the inside material stirring of reactor body more abundant, and then improve the reaction rate of reactor.

2. Through setting up rabbling mechanism to make stirring vane encircle the spout swing when rotating around spacing post, and then make stirring vane and the inside material contact of reactor body more abundant, and then further improve the reaction rate of reactor.

3. Constitute by first horizontal segment, second horizontal segment and slope section through setting up the spout to make the slider can encircle the spout and carry out up-and-down reciprocating motion, and then make the slider can drive stirring vane and encircle the spout and swing.

4. Through setting up the strengthening rib to improve stirring vane's intensity, and then improve stirring vane's life.

5. Through setting up X shape fluting and damping piece to increase the resistance between stirring vane and the inside material of reactor body, and then make stirring vane and the inside material contact of reactor body more abundant, and then further improve the reaction rate of reactor.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic diagram of a reactor for a thermal co-firing oxidation process according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a stirring mechanism of a reactor for a thermal co-firing oxidation process according to an embodiment of the present invention;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

fig. 4 is an axially expanded partial view of a spacing post of a reactor for a thermal co-firing oxidation process according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a stirring blade of a reactor for a thermal co-firing oxidation process according to an embodiment of the present invention.

In the figure:

1. a reactor body; 2. a mounting frame; 3. a motor; 4. a first bevel gear; 5. a drive shaft; 6. a second bevel gear; 7. a third bevel gear; 8. a fixed mount; 9. a shaft sleeve; 10. a stirring shaft; 11. a fourth bevel gear; 12. a stirring mechanism; 1201. a rotating frame; 1202. a limiting column; 1203. fixing a first column; 1204. fixing a second column; 1205. a bearing; 1206. a chute; 120601, a first horizontal segment; 120602, a second horizontal segment; 120603, an inclined section; 1207. a slider; 1208. an L-shaped connecting rod; 1209. a rotating shaft; 1210. a stirring blade; 121001, reinforcing ribs; 121002, X-shaped slot; 121003, damping block.

Detailed Description

For further explanation of the embodiments, the drawings are provided as part of the disclosure and serve primarily to illustrate the embodiments and, together with the description, to explain the principles of operation of the embodiments, and to provide further explanation of the invention and advantages thereof, it will be understood by those skilled in the art that various other embodiments and advantages of the invention are possible, and that elements in the drawings are not to scale and that like reference numerals are generally used to designate like elements.

According to an embodiment of the present invention, a reactor for a thermal co-firing oxidation process is provided.

Referring to the drawings and the detailed description, as shown in fig. 1-5, a reactor for thermal combustion oxidation process according to an embodiment of the present invention includes a reactor body 1, a mounting frame 2 is disposed at a middle position of a top end of the reactor body 1, a motor 3 is disposed at a middle position of a top end of the mounting frame 2, a first bevel gear 4 is sleeved on an output shaft of the motor 3 and located inside the mounting frame 2, a driving shaft 5 is symmetrically inserted and disposed at two sides of the mounting frame 2, a second bevel gear 6 engaged with the first bevel gear 4 is sleeved at one end of the driving shaft 5 and located inside the mounting frame 2, a third bevel gear 7 is sleeved at the other end of the driving shaft 5 and located outside the mounting frame 2, and mounting frames 8 are symmetrically disposed at two sides of the mounting frame 2 and located below the driving shaft 5, mount 8 keeps away from the one end of mounting bracket 2 is provided with axle sleeve 9, the inside (mixing) shaft 10 that alternates of axle sleeve 9, the top cover of (mixing) shaft 10 be equipped with third bevel gear 7 engaged with fourth bevel gear 11, the bottom of (mixing) shaft 10 is run through reactor body 1 and with be provided with reactor body 1 inside rabbling mechanism 12 is connected.

By means of the above technical scheme, through setting up a set of first bevel gear 4 and two sets of second bevel gear 6 to make the direction of rotation of two sets of (mixing) shafts 10 opposite, and then make the direction of rotation of two sets of rabbling mechanisms 12 of reactor body 1 inside opposite, and then make the inside material stirring of reactor body 1 more abundant, and then improve the reaction rate of reactor.

In one embodiment, for the stirring mechanism 12, the stirring mechanism 12 includes a rotating frame 1201 connected to the bottom end of the stirring shaft 10, a limiting column 1202 is disposed inside the rotating frame 1201, a fixing column 1203 is disposed at the bottom end of the limiting column 1202, the bottom end of the fixing column 1203 penetrates through the rotating frame 1201 and is connected to the inner wall of the reactor body 1, a fixing column 1204 is disposed at the middle position of the top end of the rotating frame 1201, a bearing 1205 matched with the bottom end of the fixing column 1204 is disposed at the top end of the limiting column 1202, a plurality of sliding slots 1206 are uniformly disposed on the side wall of the limiting column 1202 from top to bottom, a sliding block 1207 is disposed inside the sliding slot 1206, one side of the sliding block 1207 away from the limiting column 1202 is connected to one end of an L-shaped connecting rod 1208, and the other end of the L-shaped connecting rod 1208 is connected to one end of a rotating shaft 1209, the other end of pivot 1209 is provided with stirring vane 1210 to make stirring vane 1210 encircle the spout 1206 swing when rotating around spacing post 1202, and then make stirring vane 1210 and the inside material contact of reactor body 1 more abundant, and then further improve the reaction rate of reactor.

In one embodiment, for the sliding chute 1206, the sliding chute 1206 is composed of a first horizontal segment 120601, a second horizontal segment 120602 and an inclined segment 120603, and the first horizontal segment 120601 is located below the second horizontal segment 120602, so that the sliding block 1207 can reciprocate up and down around the sliding chute 1206, and the sliding block 1207 can drive the stirring blade 1210 to swing around the sliding chute 1206.

In an embodiment, for the first horizontal segment 120601, the first horizontal segment 120601 and the second horizontal segment 120602 are respectively located at two sides of the limiting pillar 1202, and the first horizontal segment 120601 and the second horizontal segment 120602 are connected end to end through two sets of the inclined segments 120603, so that the sliding block 1207 can reciprocate up and down around the sliding groove 1206, and the sliding block 1207 can drive the stirring blade 1210 to swing around the sliding groove 1206.

In one embodiment, for the stirring blade 1210, the reinforcing ribs 121001 are disposed at the lateral middle positions of the two sides of the stirring blade 1210, so as to improve the strength of the stirring blade 1210 and further improve the service life of the stirring blade 1210.

In an embodiment, for the above stirring blade 1210, a plurality of X-shaped slots 121002 are respectively formed on both sides of the stirring blade 1210 and both sides of the reinforcing rib 121001, and a plurality of damping blocks 121003 are uniformly arranged inside the X-shaped slots 121002, so as to increase resistance between the stirring blade 1210 and materials inside the reactor body 1, so that the stirring blade 1210 is more fully contacted with the materials inside the reactor body 1, and further the reaction rate of the reactor is further increased.

For the convenience of understanding the technical solution of the present invention, the following detailed description is made on the working principle or the operation mode of the present invention in the practical process.

In the time of practical application, the staff starts motor 3, thereby make motor 3 rotate through two sets of second bevel gears 6 of first bevel gear 4 simultaneous drive, thereby make second bevel gear 6 pass through the motion of drive shaft 5 drive third bevel gear 7, third bevel gear 7 passes through the motion of fourth bevel gear 11 drive (mixing) shaft 10, thereby make the inside rabbling mechanism 12 motion of (mixing) shaft 10 drive reactor body 1, because two sets of second bevel gears 6's direction of rotation are opposite, thereby make the inside two sets of rabbling mechanism 12's of reactor body 1 motion opposite, and then make the inside material stirring of reactor body 1 more abundant, and then improve the reaction rate of reactor.

Wherein, rabbling mechanism 12 is when specifically using, (mixing) shaft 10 drive swivel mount 1201 rotates, thereby make swivel mount 1201 rotate around spacing post 1202 again under the effect of fixed column two 1204 and bearing 1205, thereby make slider 1207 move along spout 1206, and then make slider 1207 move through this L shape connecting rod 1208 drive pivot 1209 under the effect of spout 1206, and then make stirring vane 1210 swing along spout 1206, and then make stirring vane 1210 encircle spout 1206 swing around spacing post 1202 pivoted while, and then make stirring vane 1210 more abundant with the inside material contact of reactor body 1, and then further improve the reaction rate of reactor.

To sum up, with the aid of the above technical scheme of the utility model, through setting up a set of first bevel gear 4 and two sets of second bevel gear 6 to make the direction of rotation of two sets of (mixing) shafts 10 opposite, and then make the direction of rotation of two sets of rabbling mechanisms 12 of reactor body 1 inside opposite, and then make the stirring of the inside material of reactor body 1 more abundant, and then improve the reaction rate of reactor. Through setting up rabbling mechanism 12 to make stirring vane 1210 encircle the spout 1206 swing around spacing post 1202 pivoted in, and then make stirring vane 1210 and the inside material contact of reactor body 1 more abundant, and then further improve the reaction rate of reactor. The sliding groove 1206 is formed by a first horizontal section 120601, a second horizontal section 120602 and an inclined section 120603, so that the sliding block 1207 can reciprocate up and down around the sliding groove 1206, and the sliding block 1207 can drive the stirring blade 1210 to swing around the sliding groove 1206. By providing the reinforcing ribs 121001, the strength of the stirring blade 1210 is improved, and the service life of the stirring blade 1210 is further prolonged. Through setting up X shape fluting 121002 and damping piece 121003 to increase the resistance between stirring vane 1210 and the inside material of reactor body 1, and then make stirring vane 1210 more abundant with the inside material contact of reactor body 1, and then further improve the reaction rate of reactor.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate medium, and may be connected through the inside of two elements or in an interaction relationship between two elements, unless otherwise specifically defined, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art according to specific situations.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a reactor for hot burning oxidation technology that accompanies, a serial communication port, including reactor body (1), reactor body (1) top intermediate position is provided with mounting bracket (2), mounting bracket (2) top intermediate position is provided with motor (3), just be located on the output shaft of motor (3) the inboard cover of mounting bracket (2) is equipped with first conical gear (4), mounting bracket (2) bilateral symmetry alternates and is provided with drive shaft (5), the one end of drive shaft (5) just is located the inboard cover of mounting bracket (2) is equipped with second conical gear (6) that first conical gear (4) meshed, the other end of drive shaft (5) just is located the outside cover of mounting bracket (2) is equipped with third conical gear (7), the both sides of mounting bracket (2) just are located the below symmetry of drive shaft (5) is provided with mount (8), keep away from mount (8) the one end of mounting bracket (2) is provided with axle sleeve (9), axle sleeve (9) inside interlude is provided with (mixing) shaft (10), the top cover of (mixing) shaft (10) be equipped with third bevel gear (7) engaged with fourth bevel gear (11), the bottom of (mixing) shaft (10) is run through reactor body (1) and with be provided with reactor body (1) inside rabbling mechanism (12) are connected.

2. The reactor for the thermal co-combustion oxidation process according to claim 1, wherein the stirring mechanism (12) comprises a rotating frame (1201) connected with the bottom end of the stirring shaft (10), a limiting column (1202) is arranged inside the rotating frame (1201), a first fixing column (1203) is arranged at the bottom end of the limiting column (1202), the bottom end of the first fixing column (1203) penetrates through the rotating frame (1201) and is connected with the inner wall of the reactor body (1), a second fixing column (1204) is arranged in the middle position of the top end inside the rotating frame (1201), a bearing (1205) matched with the bottom end of the second fixing column (1204) is arranged at the top end of the limiting column (1202), a plurality of sliding grooves (1206) are uniformly arranged on the side wall of the limiting column (1202) from top to bottom, a sliding block (1207) is arranged inside the sliding groove (1206), and one side of the sliding block (1207) far away from the limiting column (1202) is connected with one end of an L-shaped connecting rod (1208), the other end of the L-shaped connecting rod (1208) is connected with one end of a rotating shaft (1209) which is arranged on the rotating frame (1201) in a penetrating mode, and the other end of the rotating shaft (1209) is provided with a stirring blade (1210).

3. The reactor for thermal co-combustion oxidation process according to claim 2, wherein the chute (1206) is composed of a first horizontal segment (120601), a second horizontal segment (120602), and an inclined segment (120603), and the first horizontal segment (120601) is located below the second horizontal segment (120602).

4. The reactor for thermal co-combustion oxidation process according to claim 3, wherein the first horizontal segment (120601) and the second horizontal segment (120602) are respectively located at two sides of the limiting pillar (1202), and the first horizontal segment (120601) and the second horizontal segment (120602) are connected end to end through two sets of the inclined segments (120603).

5. The reactor for a thermal roasting oxidation process according to claim 2, wherein reinforcing ribs (121001) are provided at lateral middle positions of both sides of the stirring blade (1210).

6. The reactor for the thermal roasting oxidation process according to claim 5, wherein a plurality of X-shaped slots (121002) are respectively formed in two sides of the stirring blade (1210) and two sides of the reinforcing rib (121001), and a plurality of damping blocks (121003) are uniformly arranged in the X-shaped slots (121002).