CN117018786B - Industrial waste gas purifying device - Google Patents

Abstract

The application discloses an industrial waste gas purifying device, and relates to the technical field of waste gas treatment. The application comprises the following steps: the top of the gas storage bin is provided with an opening, and the bottom of the gas storage bin is provided with a water tank; and the cylinder body is fixedly arranged opposite to the gas storage bin, and the gas outlet end of the cylinder body is communicated with the gas compressing equipment. According to the application, under the cooperation of the air compressing equipment, the waste gas can be continuously pressed into the cylinder, and finally high-temperature and high-pressure gas is formed to be sprayed out from the nozzle at a high speed, so that impurities are beaten on a water wall formed by a water body, toxic and harmful substances in the waste gas can be fully contacted with the water, the toxic and harmful substances in the waste gas can be fully removed, the waste gas treatment performance of the whole structure is better and more stable, and the pollution of the toxic and harmful substances in the waste gas to the environment can be reduced.

Description

Industrial waste gas purifying device

Technical Field

The application relates to the technical field of waste gas treatment, in particular to an industrial waste gas purifying device.

Background

The chemical industry waste gas mainly originates from the production and processing of products. The chemical products are rich in variety, the used raw materials are various and large in quantity, and the production process is complex in reaction, so that the chemical industrial waste gas is various, the exhaust amount is large, and the waste gas components are complex. The chemical waste gas generally contains inorganic and organic gaseous substances and often contains various toxic, carcinogenic, teratogenic, mutagenic and highly corrosive components. The existing industrial waste gas not only comprises large particles such as dust and dust, but also is acid-base gas, the acid-base waste gas is dispersed in the air, and the acid-base waste gas is used as inorganic waste gas with extremely high harm, so that acid sedimentation in the atmosphere environment can be caused, physical health of workers and residents around a factory are endangered, factory equipment and precise instruments and the like are corroded, acid rain is formed in the atmosphere environment, adverse effects on existence of crops and other animals and plants in a large range can be brought, even serious corrosion and the like can be caused to buildings, the harm is large, the range of the wave is wide, and therefore waste gas from the factory needs to be purified. In the prior art, the waste gas containing toxic gas is generally adsorbed by an adsorbent, and some novel adsorbents, such as a polymer adsorbent, are adopted in some places of treatment factories, and special treatment equipment is needed to be matched when the adsorbent is used, however, when the adsorbent is used for adsorption, the adsorbent can only act on the gas, generally, the waste gas directly coming out of the factory generally contains certain solid particles, if the adsorbent is not used for interception treatment, when the waste gas reaches the inside of the treatment equipment, the waste gas is liable to cause certain influence on the equipment, and when the waste gas is serious, the equipment is liable to be blocked due to excessive deposition, in the prior art, when the solid particles in the waste gas are intercepted, a filter screen or a filter screen cylinder is generally arranged at the front end of the treatment equipment, but the interception effect of the interception mode is poor, and smaller particles still can penetrate through the filter screen.

Disclosure of Invention

The application aims at: in order to solve the problems in the background art, the application provides an industrial waste gas purifying device.

The application adopts the following technical scheme for realizing the purposes:

an industrial waste gas purifying device comprising:

The top of the gas storage bin is provided with an opening, and the bottom of the gas storage bin is provided with a water tank;

The cylinder body is fixedly arranged opposite to the gas storage bin, and the gas compression equipment is communicated with the cylinder body at the gas outlet end, so that waste gas is pressed into the cylinder body under the action of the gas compression equipment;

the gas storage cover is arranged on the cylinder body, the inside of the gas storage cover is communicated with one end of the cylinder body, a nozzle is arranged on the gas storage cover in a communicated manner, and the gas storage cover faces the inner wall of the gas storage bin;

The water in the water tank enters the pipeline assembly under the action of the diversion assembly and is sprayed to the inner wall of the gas storage bin.

Further, the inner wall of the gas storage bin is of an annular structure, the pipeline assembly comprises an annular pipe which is fixedly arranged relative to the gas storage bin and is coaxial with the gas storage bin, a plurality of spray holes which face the inner wall of the gas storage bin are arranged on the annular pipe in an annular array mode, the pipeline assembly further comprises a connecting pipe which is communicated between the water tank and the annular pipe, and water enters the connecting pipe under the action of the flow guide assembly.

Further, the space in the gas storage cover comprises a pressurizing part and a driving part, the nozzle is communicated with the pressurizing part, the driving part is in a columnar structure, one end of the driving part is communicated with the outside, the pressurizing part is slidably provided with an annular frame, a piston block positioned at the driving part is fixedly connected onto the pressurizing part, a stress spring is connected between the piston block and the inner wall of the driving part, and under the action of the stress spring, the annular frame forms a sealing block for the air inlet end part of the nozzle.

Further, the jet direction of the nozzle is staggered with the rotation axis of the gas storage cover, and the gas storage cover is in rotary fit with the cylinder.

Further, the liquid accumulation cavity is arranged on the drift diameter of the connecting pipe, the flow guide assembly comprises a spiral blade which is rotatably arranged in the liquid accumulation cavity, and the mounting shaft of the flow guide assembly is fixedly connected with the gas storage cover.

Further, the inner diameter of the effusion cavity is larger than the inner diameter of the connecting pipe, and the height of the effusion cavity is larger than the height of the annular pipe.

Further, the spiral blade and the gas storage cover are integrally constructed and made of heat conducting materials.

Further, a plurality of first turbine blades which are uniformly distributed along the length direction of the cylinder body are fixedly arranged on the inner wall of the cylinder body, a plurality of second turbine blades which are uniformly distributed along the length direction of the rotating axis of the cylinder body are arranged on the outer wall of the gas storage cover, and the directions of the second turbine blades and the notches of the first turbine blades are opposite.

Further, the gas storage cover is connected with a plurality of balancing weights and distributed in an annular array along the direction of the rotation axis of the gas storage cover.

Further, the balancing weight is arranged on the gas storage cover in a sliding mode, when the balancing weight slides, the balancing weight is close to or far away from the rotation axis of the gas storage cover, and a tension spring is connected between the balancing weight and the gas storage cover.

The beneficial effects of the application are as follows:

1. According to the application, under the cooperation of the air compressing equipment, the waste gas can be continuously pressed into the cylinder body and enters the air storage cover, so that high-temperature and high-pressure gas is formed in the air storage cover, and the high-speed air can be sprayed out under the action of the nozzle, so that impurities such as solid particles carried in the waste gas can obtain certain kinetic energy and strike on the inner wall of the air storage bin, namely the water wall formed by the water body, and the waste gas is brought into the water tank under the action of the water body.

2. According to the application, through the arrangement of the annular pipeline, when the water body reaches the inner wall of the gas storage bin, the distribution is more uniform, so that the water body can be better and more uniformly contacted with the particles.

3. According to the application, through the cooperation between the annular frame and the piston block, gas can enter the nozzle only when the pressure of the gas in the gas storage cover reaches a certain degree, so that the phenomenon that solid particles cannot obtain kinetic energy due to insufficient pressure is reduced, the particulate matters in the waste gas are fully ensured to have enough speed when exiting the nozzle, and the particulate matters can be fully impacted on the water wall.

Drawings

FIG. 1 is a perspective view of the present application;

FIG. 2 is a split view of the present application;

FIG. 3 is a schematic perspective view of a portion of the structure of the present application;

FIG. 4 is a further view of the application of FIG. 3;

FIG. 5 is a graph showing the effect of the present application when the partial structure of FIG. 3 is vertically cut;

FIG. 6 is a diagram showing the effect of another part of the structure of the present application when it is vertically cut;

FIG. 7 is a schematic diagram of the fit between the gas cap and the cylinder in the present application;

FIG. 8 is a split view between portions of the present application;

Reference numerals: 1. a gas storage bin; 2. an opening; 3. a water tank; 4. a cylinder; 5. a gas compressing device; 6. a gas storage cover; 7. a nozzle; 8. a flow guiding assembly; 9. a conduit assembly; 10. an annular tube; 11. a spray hole; 12. a connecting pipe; 13. a pressurizing section; 14. a driving section; 15. an annular frame; 16. a piston block; 17. a force spring; 18. a effusion chamber; 19. spiral leaves; 20. a first turbine blade; 21. a second turbine blade; 22. balancing weight; 23. and a tension spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application.

As shown in fig. 1 to 6, an industrial exhaust gas purifying apparatus according to an embodiment of the present application is an apparatus for intercepting solid particulate matter of exhaust gas entering into an exhaust gas treatment device at a front end of the exhaust gas treatment device, the apparatus comprising:

The top of the gas storage bin 1 for containing the waste gas is provided with an opening 2, and particularly as shown in fig. 1, fig. 3 is a schematic diagram in which the top of the gas storage bin 1 is separately removed, the bottom of the gas storage bin 1 is provided with a water tank 3, the water tank and the bin wall of the gas storage bin 1 are in a state of being in a common wall, and the opening 2 is used for connecting waste gas treatment equipment at the rear end of the device;

the cylinder body 4 is fixedly arranged opposite to the gas storage bin 1, and the air compressing equipment 5 with the air outlet end communicated with the cylinder body 4 is arranged, the cylinder body 4 can be directly fixed on the gas storage bin 1, waste gas is pressed into the cylinder body 4 under the action of the air compressing equipment 5, and the air compressing equipment 5 can be an air compressor or a high-power blower;

The gas storage cover 6 is arranged on the cylinder body 4 and internally communicated with one end of the cylinder body 4, and a nozzle 7 is arranged on the gas storage cover in a communicated manner and faces the inner wall of the gas storage bin 1;

the water body in the water tank 3 enters the pipeline assembly 9 under the action of the flow guide assembly 8 and is sprayed to all positions of the inner wall of the gas storage bin 1, so that a water wall is formed on the bin wall of the gas storage bin 1;

based on the characteristics, when the device works, the air compressing device 5 is started, waste gas enters the air compressing device 5 and is continuously pressed into the air storage cover 6, so that the waste gas is in a compressed state in the air storage cover 6, in addition, the temperature of the gas is increased when the waste gas is compressed, so that a high-temperature and high-pressure state is formed, the waste gas is finally sprayed out from the nozzle 7 at a high speed, so that impurities such as solid particles carried in the waste gas can acquire a certain kinetic energy under the action of the gas, and are continuously smashed on a water wall, so that the waste gas is finally flushed into the water tank 3 under the action of water flow and continuously accumulated in the water tank 3, the waste gas finally sinks to the bottom of the water tank 3 due to the gravity of the impurities, and the water in the water tank 3 continuously enters the pipeline assembly 9 under the action of the diversion assembly 8, in the state of flowing into the bin wall of the gas storage bin 1, so in a circulating state, after the impurities in the waste gas from the nozzle 7 are beaten on the water wall, the waste gas is finally accumulated in the gas storage bin 1 and flows out of the opening 2 at the top, so that the waste gas and the particulate matters enter into the treatment equipment at the rear end, the whole process is finished, compared with the interception mode of a net plug in the prior art, the kinetic energy of the particulate matters from the nozzle 7 can be basically obtained, and the particulate matters can be beaten on the water wall, but only the particulate matters with a certain size can be intercepted in the net plug mode, so that the effect of the device is better.

As shown in fig. 3 to 5, in some embodiments, the inner wall of the gas storage bin 1 is in an annular structure, the pipe assembly 9 includes an annular pipe 10 which is relatively fixedly arranged with the gas storage bin 1 and is coaxial with the gas storage bin 1, a plurality of spray holes 11 which face the inner wall of the gas storage bin 1 are arranged on the annular pipe in an annular array, and a connecting pipe 12 which is communicated between the water tank 3 and the annular pipe 10 is also included, water enters the connecting pipe 12 under the action of the flow guiding assembly 8, through the design of the annular pipe 10, after the water reaches the annular pipe 10 from the connecting pipe 12, the water is uniformly filled in the annular pipe 10, and finally, the water is uniformly sprayed out from the spray holes 11 at all positions, so that the uniformity degree of water flow at all positions of the water wall can be improved through the design of the annular pipe 10, and the impurities discharged from all positions of the spray nozzles 7 can be uniformly contacted with the water.

As shown in fig. 5-8, in some embodiments, the space inside the gas storage cover 6 includes a pressurizing portion 13 and a driving portion 14, in order to match the configuration, the appearance of the gas storage cover 6 may be designed into the configuration shown in fig. 6, where the nozzle 7 is communicated with the pressurizing portion 13, the driving portion 14 is in a columnar configuration, one end of the driving portion is communicated with the outside, the pressurizing portion 13 is slidably provided with an annular frame 15, specifically, vertically slides, and the cylindrical cavity shape of the pressurizing portion 13 is used to realize the matching sliding, a piston block 16 located at the driving portion 14 is fixedly connected to the annular frame 15, and is also slidably matched with the driving portion 14, a force spring 17 is connected between the piston block 16 and the inner wall of the driving portion 14, under the action of which, when the whole gas storage cover 6 has no air pressure inside, the annular frame 15 forms a blocking for the air inlet end of the nozzle 7;

Based on the above characteristics, in normal state, under the action of the elastic force of the force spring 17, the annular frame 15 forms a seal at the connection position between the nozzle 7 and the inside of the gas storage cover 6, so when the whole device is started and the pressure in the pressure gas storage cover 6 does not reach a certain degree, the nozzle 7 and the inside of the gas storage cover 6 are in an unconnected state, when the exhaust gas is continuously pressed into the gas storage cover 6 along with the air compressing equipment 5, the internal pressure is gradually increased, the piston block 16 is subjected to pressure to overcome the elastic force of the force spring 17 to move, so as to drive the annular frame 15 to remove the seal at the connection position between the nozzle 7 and the inner cavity of the gas storage cover 6, and at the moment, the high-temperature and high-pressure exhaust gas can instantly enter the nozzle 7 and be sprayed out.

As shown in fig. 5 and 8, in some embodiments, the injection direction of the nozzle 7 is offset from the rotation axis of the gas storage cover 6, and the gas storage cover 6 is in rotation fit with the cylinder 4, so that the whole gas storage cover 6 can rotate at a high speed under the action of the exhaust gas sprayed at a high speed, and as the working time of the whole device increases, the rotation speed of the gas storage cover 6 can be increased to a certain extent and is in a stable running state, so that impurities can be uniformly sprayed to all parts of the water wall when being sprayed, and the contact uniformity between the impurities and the water wall can be promoted.

As shown in fig. 5, in some embodiments, the path of the connecting pipe 12 is provided with a effusion chamber 18, and with respect to the above flow guiding assembly 8, the flow guiding assembly may specifically include a spiral vane 19 rotatably disposed inside the effusion chamber 18, and the installation shaft of the flow guiding assembly is fixedly connected with the air storage cover 6, so that when the air storage cover 6 rotates at a high speed, the air storage cover 6 will bring the spiral vane 19 into a working state, so that a reverse suction phenomenon will occur in the connecting pipe 12, thereby sucking a water body from the water tank 3 into the effusion chamber 18, finally entering into the annular pipe 10 and being ejected from the nozzle hole 11, and in cooperation with the action of the annular frame 15, when the exhaust gas is just ejected from the nozzle 7, the air storage cover 6 is in a state of rotating at a high speed, so that a water wall can be formed rapidly when the exhaust gas exits.

In some embodiments, as shown in fig. 5, the inner diameter of the effusion chamber 18 is larger than the inner diameter of the connecting pipe 12, and the height of the effusion chamber is larger than the height of the annular pipe 10, so that when the water flows down into the annular pipe 10 from the effusion chamber 18, a siphon effect is generated on the front end of the effusion chamber 18 due to the gravity, so that the water is better sucked into the effusion chamber 18, and the circulation of the water is realized.

As shown in fig. 5 and 8, in some embodiments, the spiral vane 19 is integrally configured with the gas storage cover 6 and made of a heat conducting material, specifically may be made of copper, and since the exhaust gas has a certain amount of heat and is compressed, the temperature when reaching the inside of the gas storage cover 6 is very high, which is easy to cause the temperature of the gas storage cover 6 to be too high, so by virtue of the design, the temperature of the gas storage cover 6 is transferred to the spiral vane 19, and the water body can cool the spiral vane 19 when passing through the spiral vane, thereby cooling the housing of the gas storage cover 6.

As shown in fig. 5 to 8, in some embodiments, the inner wall of the cylinder 4 is fixedly provided with a plurality of first turbine blades 20 uniformly distributed along the length direction of the cylinder, the outer wall of the gas storage cover 6 is provided with a plurality of second turbine blades 21 uniformly distributed along the length direction of the rotation axis of the gas storage cover 6, and the notches of the second turbine blades 21 are opposite to the notches of the first turbine blades 20, and the second turbine blades 21 synchronously rotate along with the high-speed rotation of the gas storage cover 6, and cooperate with the first turbine blades 20 to perform secondary compression on the exhaust gas entering the cylinder 4, so that the effect of compressing the exhaust gas is further increased, and the exhaust gas obtains larger pressure.

As shown in fig. 5 to 8, in some embodiments, in order to make the gas storage cover 6 have a better stabilizing effect during high-speed rotation, and meanwhile, can better maintain the stability of the self-rotation speed, a plurality of balancing weights 22 may be further connected to the gas storage cover 6 and distributed in an annular array along the self-rotation axis direction, so that when the gas storage cover 6 rotates, the gas storage cover 6 can maintain a better stabilizing effect by means of the inertia of the balancing weights 22, for example, when the exhaust gas pressure is short, the gas storage cover 6 can still be kept in a high-speed rotation state in a short time by means of the inertia of the balancing weights 22.

As shown in fig. 6, in some embodiments, in order to reduce the starting resistance of the gas storage cover 6 caused by the inertia of the balancing weight 22 when the gas storage cover 6 starts to rotate, the balancing weight 22 is further slidably disposed on the gas storage cover 6, the sliding direction is such that when the balancing weight 22 slides and is close to or far away from the rotation axis of the gas storage cover 6, a tension spring 23 is further connected between the balancing weight 22 and the gas storage cover 6, when the balancing weight 22 slides away from the gas storage cover 6 to the maximum extent, the balancing weight 22 is within the elastic force range of the tension spring 23, and no damage is caused to the tension spring 23, through the design, when the balancing weight 22 is close to the gas storage cover 6 under the action of the tension spring 23 in normal state, the resistance of the balancing weight 22 is smaller when the gas storage cover 6 starts, and when the balancing weight 22 gradually slides away from the gas storage cover 6 due to the centrifugal force along with the whole rotation speed, so that the rotation radius is increased, the centrifugal force is increased, the stabilizing effect on the gas storage cover 6 is better, and a sleeve is fixed on the gas storage cover 6, and a plug rod is inserted in the sliding inside the sleeve, so that the plug rod 22 can be fixed on the gas storage cover 6.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (5)

1. An industrial waste gas purifying apparatus, characterized by comprising:

The gas storage bin (1) is used for containing waste gas, an opening (2) is formed in the top of the gas storage bin, and a water tank (3) is arranged at the bottom of the gas storage bin (1);

A cylinder (4) which is fixedly arranged opposite to the gas storage bin (1) and a gas compressing device (5) with a gas outlet end communicated with the cylinder (4), wherein the waste gas is pressed into the cylinder (4) under the action of the gas compressing device (5);

The gas storage device comprises a gas storage cover (6) which is arranged on a cylinder body (4) and is internally communicated with one end of the cylinder body (4), a nozzle (7) is arranged on the gas storage cover in a communicating way and faces to the inner wall of a gas storage bin (1), the inner space of the gas storage cover (6) comprises a pressurizing part (13) and a driving part (14), the nozzle (7) is communicated with the pressurizing part (13), the driving part (14) is in a columnar structure, one end of the driving part is communicated with the outside, the pressurizing part (13) is slidably provided with an annular frame (15), a piston block (16) positioned at the driving part (14) is fixedly connected onto the driving part, a stress spring (17) is connected between the piston block (16) and the inner wall of the driving part (14), under the effect of the stress spring, the annular frame (15) seals the gas inlet end part of the nozzle (7), the spraying direction of the nozzle (7) is staggered with the rotation axis of the gas storage cover (6), and the cylinder body (4) are in a rotating fit;

The water body in the water tank (3) enters the pipeline assembly (9) under the action of the water guide assembly (8) and is sprayed to the inner wall of the gas storage bin (1), the inner wall of the gas storage bin (1) is of an annular structure, the pipeline assembly (9) comprises an annular pipe (10) which is fixedly arranged opposite to the gas storage bin (1) and is coaxial with the gas storage bin (1), a plurality of spray holes (11) which face the inner wall of the gas storage bin (1) are arranged on the annular pipe in an annular array manner, the pipeline assembly also comprises a connecting pipe (12) which is communicated between the water tank (3) and the annular pipe (10), the water body enters the connecting pipe (12) under the action of the water guide assembly (8), a liquid accumulation cavity (18) is arranged on the path of the connecting pipe (12), and the water guide assembly (8) comprises a spiral blade (19) which is rotatably arranged in the liquid accumulation cavity (18), and the installation shaft of the spiral blade is fixedly connected with the gas storage cover (6);

The novel air storage device is characterized in that a plurality of first turbine blades (20) which are uniformly distributed along the length direction of the air storage cover are fixedly arranged on the inner wall of the cylinder body (4), a plurality of second turbine blades (21) which are uniformly distributed along the length direction of the rotation axis of the air storage cover are arranged on the outer wall of the air storage cover (6), and the directions of the notches of the second turbine blades are opposite to those of the notches of the first turbine blades (20).

2. An industrial waste gas purifying device according to claim 1, wherein the inner diameter of the liquid accumulation chamber (18) is larger than the inner diameter of the connecting pipe (12) and the height thereof is larger than the height of the annular pipe (10).

3. An industrial waste gas purifying device according to claim 2, characterized in that the spiral blade (19) is constructed integrally with the gas storage cap (6) and is made of a heat conducting material.

4. An industrial waste gas purifying device according to claim 3, wherein the gas storage cover (6) is connected with a plurality of balancing weights (22) and distributed in a ring-shaped array along the direction of the rotation axis thereof.

5. An industrial waste gas purifying device according to claim 4, wherein the counterweight (22) is slidably arranged on the gas storage cover (6), and when the counterweight (22) slides, it is close to or far away from the rotation axis of the gas storage cover (6), and a tension spring (23) is connected between the counterweight (22) and the gas storage cover (6).