CN217312622U - Waste gas treatment equipment for reclaimed rubber production and processing - Google Patents

Abstract

The utility model relates to a waste gas treatment equipment especially relates to a waste gas treatment equipment of reclaimed rubber production and processing. The technical problem of the utility model is that: the waste gas treatment equipment for producing and processing reclaimed rubber can quickly replace activated carbon, is simple to operate and saves labor and time. The technical implementation scheme of the utility model is: a waste gas treatment device for reclaimed rubber production and processing comprises a gas storage tank, a gas inlet pipe, a porous filter element and the like; two air inlet pipes are arranged on the left side and the right side of the bottom of the air storage tank, and a porous filter element is vertically and fixedly connected to the middle of the air storage tank. The utility model discloses a pulling carriage downwards, carriage lapse drive the slide bar lapse through the stopper, and the slide bar lapse drives the sprue lapse, and the active carbon of saturation is discharged from porous filter core bottom, and long rack rebound drives the sprue rebound, and the active carbon just from discharging porous filter core in the storage tank through the unloading pipe, so, alright accomplish the quick replacement of active carbon.

Description

Waste gas treatment equipment for reclaimed rubber production and processing

Technical Field

The utility model relates to a waste gas treatment equipment especially relates to a waste gas treatment equipment of reclaimed rubber production and processing.

Background

The reclaimed rubber is rubber which is processed by taking vulcanized leftover materials in the production of rubber products as raw materials, has certain plasticity and can be reused, and is called reclaimed rubber for short. According to the different waste rubbers, the regenerated rubbers are classified into outer tyres, inner tyres, rubber shoes and the like.

The most adopted process in the production of reclaimed rubber at present is a high-pressure high-temperature dynamic desulfurization process, a large amount of waste gas can be intermittently discharged when the process is used for production, the waste gas contains a large amount of harmful gases such as hydrogen sulfide, benzene, toluene and xylene, the surrounding environment is seriously influenced, and air is polluted, so that the waste gas needs to be adsorbed by using activated carbon, the activated carbon has a saturation degree, the activated carbon needs to be frequently replaced under the condition of continuous use, but the operation of replacing the activated carbon is complex, and much labor time is consumed.

Therefore, it is necessary to design a waste gas treatment device for reclaimed rubber production and processing, which can rapidly replace activated carbon, is simple to operate and saves labor and time.

SUMMERY OF THE UTILITY MODEL

In order to overcome the shortcoming that changes activated carbon complex operation, consume a lot of human time, the utility model discloses a technical problem does: the waste gas treatment equipment for producing and processing reclaimed rubber can quickly replace activated carbon, is simple to operate and saves manpower time.

The utility model discloses a following technical approach realizes: a waste gas treatment device for production and processing of reclaimed rubber comprises a gas storage tank, gas inlet pipes, gas outlet pipes, porous filter elements, filter paper, a mounting rack, a slide bar, a plugging block, a fixed rod, a first spring, a limiting block, a torsion spring, a sliding rack, a storage tank, a cover, a discharging pipe, a fixing rack, a column gear, a plugging rod, a short rack and a long rack, wherein the left side and the right side of the bottom of the gas storage tank are provided with the two gas inlet pipes, the middle part of the gas storage tank is vertically and fixedly connected with the porous filter elements, the middle part of the porous filter elements is porous, the porous filter elements are used for storing filter raw materials such as active carbon and the like, the upper end and the lower end of each porous filter element penetrate through the gas storage tank, the top of the gas storage tank is circumferentially and uniformly provided with the six gas outlet pipes, the six gas outlet pipes are communicated with the top of the porous filter elements, the filter paper is sleeved outside the porous filter elements, the primary filtration of the waste gas storage tank is realized, the mounting rack is welded at the lower part of the gas storage tank, the fixed rod is welded on the mounting rack, a sliding rod is slidably mounted on the fixed rod, a plugging block is fixedly connected to the top end of the sliding rod, a first spring is connected between the sliding rod and the fixed frame, two limiting blocks are rotatably mounted on the inner portion of the sliding rod, a torsion spring is connected between the middle portions of the two limiting blocks, a sliding frame is slidably mounted on the outer side of the air storage tank, the top portion of the sliding frame is annularly arranged, the sliding rod penetrates through the bottom portion of the sliding frame, the tops of the two limiting blocks are in contact fit with the bottom portion of the sliding frame, two blanking pipes are fixedly connected to the top portion of each air storage tank, a storage tank is connected to the tops of the two blanking pipes, a cover is covered on the top portion of each storage tank, a fixed frame is welded on the inner side of the right blanking pipe, a column gear is rotatably mounted on the left portion of the fixed frame, a plugging rod is slidably mounted on the upper portion of the porous filter core, a long rack is fixedly connected to the upper portion of the plugging rod, the long rack is meshed with the column gear, a short rack is welded on the right side of the top portion of the sliding frame, and the short rack is driven to move downwards through the sliding frame, the driving column gear rotates to realize that the long rack drives the blocking rod to move upwards.

In a preferred embodiment of the present invention, the filter further comprises a round bar, a spiral groove bar, a roller and a clip, the round bar is welded to the bottom of the storage tank, the spiral groove bar is rotatably installed at the lower end of the round bar, the spiral groove bar rotatably passes through the blocking bar, the roller is welded to the left side in the top of the sliding frame, the roller is matched with the spiral groove bar, the clip is welded to the bottom of the spiral groove bar, the clip is located in the porous filter element, and when the sliding frame slides downward, the roller can drive the spiral groove bar to drive the clip to rotate in the porous filter element.

In a preferred embodiment of the present invention, the plug further comprises a rubber ring, the rubber ring is fixed to the upper and lower sides of the plug rod, the spiral groove rod is tightly attached to the rubber ring, and the rubber ring can prevent the waste gas from leaking around the spiral groove rod when the plug rod slides.

In a preferred embodiment of the present invention, the gas storage tank further comprises a U-shaped clamping bar and a second spring, the U-shaped clamping bar is slidably penetrated at the rear portion of the sliding frame, the left end of the U-shaped clamping bar is clamped on the gas storage tank, and the second spring is connected between the U-shaped clamping bar and the sliding frame.

In a preferred embodiment of the present invention, the plug further comprises a conical block, the upper portion of the plug is fixedly connected with the conical block, and the conical block can prevent raw materials such as activated carbon from accumulating on the plug when the raw materials are discharged.

Compared with the prior art, the utility model discloses it is showing the progress and lies in: the utility model discloses a pulling the carriage downwards, the carriage lapse drives the slide bar lapse through the stopper, the slide bar lapse drives the sprue lapse, the sprue breaks away from the back with porous filter core, the active carbon of saturation is discharged from porous filter core bottom, the carriage lapse just in time drives short rack and column gear engagement, short rack lapse drives the column gear reversal, column gear reversal drives long rack rebound, long rack rebound drives the sprue upshift, the sprue upshift drives the maximum stroke after, the active carbon just discharges into porous filter core through the unloading pipe in the storage tank, so, alright accomplish the quick replacement of active carbon.

Drawings

Fig. 1 is a schematic view of a first three-dimensional structure of the present invention.

Fig. 2 is a schematic view of a second three-dimensional structure of the present invention.

Fig. 3 is a schematic sectional view of the present invention.

Fig. 4 is a schematic view of the cross-sectional structure of the gas storage tank of the present invention.

Fig. 5 is a schematic view of the three-dimensional structure of the porous filter element and the filter paper of the present invention.

Fig. 6 is a schematic view of the three-dimensional structure of the porous filter element of the present invention.

Fig. 7 is a schematic view of the three-dimensional structure of the slide rod and the fixing rod of the present invention.

Fig. 8 is a schematic perspective view of the round bar and the spiral grooved bar of the present invention.

Fig. 9 is a schematic perspective view of the U-shaped rod and the second spring of the present invention.

The parts are labeled as follows: 1. the air storage tank comprises an air storage tank, 2, an air inlet pipe, 3, an air outlet pipe, 4, a porous filter element, 5, filter paper, 6, a mounting rack, 7, a sliding rod, 8, a blocking block, 9, a fixing rod, 10, a first spring, 11, a limiting block, 12, a torsion spring, 13, a sliding frame, 14, a storage tank, 15, a cover, 16, a discharging pipe, 17, a fixing frame, 18, a column gear, 19, a blocking rod, 20, a long rack, 21, a short rack, 22, a round rod, 23, a spiral groove rod, 24, a rolling shaft, 25, a clip frame, 26, a rubber ring, 27, a U-shaped clamping rod, 28, a second spring, 29 and a conical block.

Detailed Description

The invention is further explained by combining the attached drawings of the specification, and the embodiment of the invention is given by combining the attached drawings of the specification.

Example 1

A waste gas treatment device for producing and processing reclaimed rubber is shown in figures 1, 2, 3, 4, 5, 6, 7 and 8 and comprises a gas storage tank 1, a gas inlet pipe 2, a gas outlet pipe 3, a porous filter element 4, filter paper 5, a mounting rack 6, a slide rod 7, a plugging block 8, a fixed rod 9, a first spring 10, a limiting block 11, a torsion spring 12, a sliding rack 13, a storage tank 14, a cover 15, a discharging pipe 16, a fixing rack 17, a column gear 18, a plugging rod 19, a short rack 21 and a long rack 20, wherein the left side and the right side of the bottom of the gas storage tank 1 are provided with the two gas inlet pipes 2, the middle of the gas storage tank 1 is vertically and fixedly connected with the porous filter element 4, the middle of the porous filter element 4 is porous, the porous filter element 4 is used for storing filter raw materials such as active carbon, the upper end and the lower end of the porous filter element 4 both penetrate through the gas storage tank 1, and the top of the gas storage tank 1 is circumferentially and uniformly provided with six gas outlet pipes 3, six gas outlet pipes 3 are communicated with the top of a porous filter element 4, filter paper 5 is sleeved outside the porous filter element 4, the filter paper 5 can primarily filter waste gas, a mounting frame 6 is welded at the lower part of a gas storage tank 1, a fixing rod 9 is welded on the mounting frame 6, a sliding rod 7 is slidably mounted on the fixing rod 9, a blocking block 8 is fixedly connected at the top end of the sliding rod 7, a first spring 10 is connected between the sliding rod 7 and a mounting frame 17, two limiting blocks 11 are rotatably mounted on the inner part of the sliding rod 7, a torsion spring 12 is connected between the middle parts of the two limiting blocks 11, a sliding frame 13 is slidably mounted on the outer side of the gas storage tank 1, the top of the sliding frame 13 is annularly arranged, the sliding rod 7 penetrates through the bottom of the sliding frame 13, the tops of the two limiting blocks 11 are in contact fit with the bottom of the sliding frame 13, two discharging pipes 16 are fixedly connected at the top of the gas storage tank 1, a storage tank 14 is covered with a cover 15, the inboard welding of right part unloading pipe 16 has mount 17, and post gear 18 is installed to mount 17 left part rotary type, and stifled pole 19 is installed to the upper portion slidingtype in the porous filter core 4, and 19 upper portion rigid couplings of stifled pole have long rack 20, and long rack 20 and the meshing of post gear 18, and the welding of carriage 13 top right side has short rack 21, drives short rack 21 downstream through carriage 13, drives the rotation of post gear 18 and can realize that long rack 20 drives stifled pole 19 upward movement.

Still including round bar 22, spiral groove pole 23, roller bearing 24 and time shape frame 25, the welding of 14 bottoms of storage tank has round bar 22, spiral groove pole 23 is installed to round bar 22 lower extreme rotary type, stifled pole 19 is passed to spiral groove pole 23 rotary type, the welding of left side has roller bearing 24 in the carriage 13 top, roller bearing 24 and the cooperation of spiral groove pole 23, the welding of spiral groove pole 23 bottom has time shape frame 25, it is located porous filter core 4 to return shape frame 25, when carriage 13 glides downwards, can realize that roller bearing 24 drive spiral groove pole 23 drives and returns shape frame 25 at the internal rotation of porous filter core 4.

Firstly, an operator opens a cover 15, adds active carbon into a material storage tank 14, the active carbon falls down from a blanking pipe 16 to contact with a blocking rod 19, then covers the cover 15, then pulls a sliding frame 13 downwards, the sliding frame 13 moves downwards to drive a sliding rod 7 to move downwards through a limiting block 11, a first spring 10 is compressed along with the sliding frame, the sliding rod 7 moves downwards to drive a blocking block 8 to slide downwards, when the lower part of the limiting block 11 touches the top end of a fixed rod 9, the lower parts of the two limiting blocks 11 expand outwards under the action of the fixed rod 9, so that the upper parts of the two limiting blocks 11 contract inwards, a torsion spring 12 twists along with the sliding frame, when the top part of the limiting block 11 contracts inwards to the maximum stroke, the limiting block 11 is separated from the sliding frame 13, under the action of the first spring 10, the sliding rod 7 drives the limiting block 11 to move upwards together to reset, when the limiting block 11 is separated from the fixed rod 9, under the action of the torsion spring 12, the upper part of the limiting block 11 can be expanded outwards to reset, the plugging block 8 slides upwards to plug the porous filter element 4, at the moment, the sliding frame 13 moves downwards to just drive the short rack 21 to be meshed with the column gear 18, the short rack 21 moves downwards to drive the column gear 18 to rotate reversely, the column gear 18 rotates reversely to drive the long rack 20 to move upwards, the long rack 20 moves upwards to drive the plugging rod 19 to move upwards, after the plugging rod 19 moves upwards to the maximum stroke, the active carbon is discharged into the porous filter element 4 from the storage tank 14 through the discharging pipe 16, after the porous filter element 4 is filled with the active carbon, the sliding frame 13 is pulled to move upwards, the sliding frame 13 moves upwards to drive the short rack 21 to move upwards, the short rack 21 moves upwards to drive the column gear 18 to rotate forwards, the column gear 18 rotates forwards to drive the long rack 20 to move downwards, the long rack 20 moves downwards to drive the plugging rod 19 to move downwards, and the plugging rod 19 moves downwards to plug the discharging pipe 16 again, after the sliding frame 13 moves upwards to contact with the limiting blocks 11, under the limitation of the sliding frame 13, the two limiting blocks 11 contract inwards, the torsion spring 12 twists with the torsion spring, the sliding frame 13 moves upwards to be separated from the limiting blocks 11, the two limiting blocks 11 reset under the action of the torsion spring 12, the tops of the two limiting blocks 11 are contacted with the bottom of the sliding frame 13 again to clamp the torsion spring, then an operator opens the valve of the air inlet pipe 2 to discharge waste gas into the air storage tank 1, the waste gas enters the air storage tank 1 and is primarily filtered by the filter paper 5, then is secondarily filtered by the activated carbon in the porous filter element 4 and is discharged through the air outlet pipe 3, when the activated carbon adsorbs harmful gas to reach a saturation degree, the operator closes the valve of the air inlet pipe 2, then pulls the sliding frame 13 downwards, the sliding frame 13 moves downwards through the limiting blocks 11 to drive the sliding rod 7 to move downwards, and the first spring 10 is compressed therewith, the sliding rod 7 moves downwards to drive the plugging block 8 to slide downwards, after the plugging block 8 is separated from the porous filter element 4, saturated activated carbon is discharged from the bottom of the porous filter element 4, when the lower part of the limiting block 11 touches the top end of the fixing rod 9, the lower parts of the two limiting blocks 11 expand outwards under the action of the fixing rod 9, so that the upper parts of the two limiting blocks 11 contract inwards, the torsion spring 12 twists along with the torsion spring, when the top part of the limiting block 11 contracts inwards to the maximum stroke, the limiting block 11 is separated from the sliding frame 13, under the action of the first spring 10, the sliding rod 7 drives the limiting block 11 to move upwards together to reset, after the limiting block 11 is separated from the fixing rod 9, under the action of the torsion spring 12, the upper part of the limiting block 11 expands outwards to reset, the plugging block 8 slides upwards to plug the porous filter element 4, at the moment, the sliding frame 13 moves downwards to just drive the short rack 21 to be meshed with the column gear 18, the short rack 21 moves downwards to drive the column gear 18 to rotate reversely, the column gear 18 reversely rotates to drive the long rack 20 to move upwards, the long rack 20 moves upwards to drive the blocking rod 19 to move upwards, after the blocking rod 19 moves upwards to the maximum stroke, the activated carbon is discharged into the porous filter core 4 from the storage tank 14 through the discharging pipe 16, when the porous filter core 4 is filled with the activated carbon, the sliding frame 13 is pulled to move upwards, the sliding frame 13 moves upwards to drive the short rack 21 to move upwards, the short rack 21 moves upwards to drive the column gear 18 to rotate forwards, the column gear 18 rotates forwards to drive the long rack 20 to move downwards, the long rack 20 moves downwards to drive the blocking rod 19 to move downwards, the blocking rod 19 moves downwards to block the discharging pipe 16 again, after the sliding frame 13 moves upwards to contact with the limiting blocks 11, under the limitation of the sliding frame 13, the two limiting blocks 11 contract inwards, the torsion spring 12 twists along with the torsion spring, the sliding frame 13 moves upwards to be separated from the limiting blocks 11, under the action of the torsion spring 12, the two limit blocks 11 are reset, and the tops of the two limit blocks 11 are contacted with the bottom of the sliding frame 13 again to clamp the two limit blocks, so that the quick replacement of the active carbon can be completed. Through pulling carriage 13 downwards, carriage 13 is removed downwards and is driven slide bar 7 to remove downwards through stopper 11, slide bar 7 is removed downwards and is driven sprue 8 and slide downwards, sprue 8 breaks away from the back with porous filter core 4, saturated active carbon is discharged from porous filter core 4 bottom, carriage 13 removes downwards and just in time drives short rack 21 and post gear 18 meshing, short rack 21 moves down and drives post gear 18 reversal, post gear 18 reversal drives long rack 20 and moves upwards, long rack 20 upward movement drives sprue 19 upward movement, sprue 19 upward movement is to the maximum stroke after, active carbon just discharges into porous filter core 4 through unloading pipe 16 in storage tank 14, so, alright completion active carbon's quick replacement.

When carriage 13 lapse makes sprue 8 and porous filter core 4 break away from, and when the active carbon of saturation discharged from porous filter core 4 bottom, drive roller bearing 24 downstream, under roller bearing 24's effect, spiral groove rod 23 reverses, and spiral groove rod 23 reverses and drives back shape frame 25 and reverse, scrapes porous filter core 4 inner wall, so, alright discharge the active carbon of saturation in the porous filter core 4 fast. Slide down through carriage 13 and drive roller bearing 24 downstream, under roller bearing 24's effect, spiral groove rod 23 reverses, and spiral groove rod 23 reverses and drives back shape frame 25 and reverse, scrapes porous filter core 4 inner wall, so, alright discharge porous filter core 4 interior saturated active carbon fast.

Example 2

In addition to embodiment 1, as shown in fig. 4, 8 and 9, the exhaust gas purifying device further includes a rubber ring 26, the rubber ring 26 is fixed to the upper and lower sides of the blocking rod 19, the spiral groove rod 23 is tightly attached to the rubber ring 26, and the rubber ring 26 can prevent the exhaust gas from leaking from the peripheral side of the spiral groove rod 23 when the blocking rod 19 slides.

The air storage tank further comprises a U-shaped clamping rod 27 and a second spring 28, the U-shaped clamping rod 27 is connected to the rear portion of the sliding frame 13 in a sliding mode in a penetrating mode, the left end of the U-shaped clamping rod 27 is clamped on the air storage tank 1, and the second spring 28 is connected between the U-shaped clamping rod 27 and the sliding frame 13.

The device also comprises a conical block 29, the upper part of the block 8 is fixedly connected with the conical block 29, and the conical block 29 can prevent raw materials such as active carbon and the like from being accumulated on the block 8 when being discharged.

When the blocking rod 19 moves up and down, the rubber rings 26 on the upper and lower sides of the blocking rod 19 are tightly attached to the spiral groove rod 23, so that the leakage of the waste gas from the upper part of the blocking rod 19 can be prevented.

When the sliding frame 13 needs to be moved downwards, the U-shaped clamping rod 27 is pulled out backwards, the second spring 28 is compressed along with the U-shaped clamping rod, the sliding frame 13 can be moved downwards after the U-shaped clamping rod 27 is separated from the air storage tank 1, after the sliding frame 13 is moved upwards and is reset, the U-shaped clamping rod 27 is loosened, the U-shaped clamping rod 27 is reset under the action of the second spring 28 and is clamped on the air storage tank 1 again, and therefore the sliding frame 13 can be prevented from being moved under the action of non-manual operation.

When carriage 13 lapse makes sprue 8 and porous filter core 4 break away from, when saturated active carbon discharged from porous filter core 4 bottom, under conical block 29's effect, saturated active carbon along 8 circumference landing of sprue, can not pile up on sprue 8, so, alright prevent that saturated active carbon from piling up on sprue 8 to raw materials such as the active carbon of saturation in avoiding porous filter core 4 remain.

Finally, it is necessary to state that: the above contents are only used to help understanding the technical solution of the present invention, and should not be interpreted as limiting the scope of the present invention; insubstantial modifications and adaptations of the present invention as described above will now occur to those skilled in the art and are intended to be covered by the present invention.

Claims (5)

1. The utility model provides a waste gas treatment equipment of reclaimed rubber production and processing, including gas holder (1), intake pipe (2), outlet duct (3), porous filter core (4) and filter paper (5), two intake pipe (2) are installed to gas holder (1) bottom left and right sides, the perpendicular form rigid coupling in gas holder (1) middle part has porous filter core (4), porous filter core (4) middle part is porous form, porous filter core (4) are used for storing filtration raw materials such as active carbon, gas holder (1) is all passed at both ends about porous filter core (4), six outlet ducts (3) are installed to gas holder (1) top circumference evenly distributed, six outlet ducts (3) and porous filter core (4) top intercommunication, porous filter core (4) outside cover has filter paper (5) to the preliminary filtration of waste gas, characterized by: the automatic material storage device is characterized by further comprising a mounting frame (6), a sliding rod (7), a blocking block (8), a fixing rod (9), a first spring (10), a limiting block (11), a torsion spring (12), a sliding frame (13), a material storage tank (14), a cover (15), a discharging pipe (16), a mounting frame (17), a column gear (18), a blocking rod (19), a short rack (21) and a long rack (20), the mounting frame (6) is fixedly connected to the lower portion of the gas storage tank (1), the fixing rod (9) is fixedly connected to the mounting frame (6), the sliding rod (7) is slidably mounted on the fixing rod (9), the blocking block (8) is fixedly connected to the top end of the sliding rod (7), the first spring (10) is connected between the sliding rod (7) and the mounting frame (17), the two limiting blocks (11) are rotatably mounted on the inner portion of the sliding rod (7), the torsion spring (12) is connected between the middle portions of the two limiting blocks (11), the sliding frame (13) is slidably mounted on the outer side of the gas storage tank (1), carriage (13) top is the annular setting, carriage (13) bottom is passed in slide bar (7), two stopper (11) tops and carriage (13) bottom contact cooperation, gas holder (1) top rigid coupling has two unloading pipe (16), two unloading pipe (16) tops are connected with storage tank (14), storage tank (14) top is covered with lid (15), the inboard rigid coupling of right side unloading pipe (16) has mount (17), column gear (18) are installed to mount (17) left part rotary type, stifled pole (19) are installed to upper portion slidingtype in porous filter core (4), stifled pole (19) upper portion rigid coupling has long rack (20) that drive stifled pole (19) rebound, long rack (20) and column gear (18) meshing, carriage (13) top right side rigid coupling has short rack (21).

2. The waste gas treatment equipment for reclaimed rubber production and processing according to claim 1, further comprising a round rod (22), a spiral grooved rod (23), a roller (24) and a clip frame (25), wherein the round rod (22) is welded at the bottom of the storage tank (14), the spiral grooved rod (23) for driving the clip frame (25) to rotate in the porous filter element (4) is rotatably installed at the lower end of the round rod (22), the clip rod (19) is rotatably penetrated through the spiral grooved rod (23), the roller (24) is fixedly connected to the left side in the top of the sliding frame (13), the roller (24) is matched with the spiral grooved rod (23), the clip frame (25) is fixedly connected to the bottom of the spiral grooved rod (23), and the clip frame (25) is positioned in the porous filter element (4).

3. The waste gas treatment equipment for reclaimed rubber production and processing according to claim 2, further comprising rubber rings (26), wherein the rubber rings (26) for preventing waste gas from leaking from the periphery of the spiral grooved rod (23) when the blocking rod (19) slides are fixedly connected to the upper and lower sides of the blocking rod (19), and the spiral grooved rod (23) is tightly attached to the rubber rings (26).

4. The waste gas treatment equipment for reclaimed rubber production and processing according to claim 3, further comprising a U-shaped clamping rod (27) and a second spring (28), wherein the U-shaped clamping rod (27) is slidably connected to the rear part of the sliding frame (13), the left end of the U-shaped clamping rod (27) is clamped on the gas storage tank (1), and the second spring (28) is connected between the U-shaped clamping rod (27) and the sliding frame (13).

5. The waste gas treatment equipment for reclaimed rubber production and processing according to claim 4, further comprising a tapered block (29), wherein the tapered block (29) for preventing the raw materials such as activated carbon from being accumulated on the block (8) when the raw materials such as activated carbon are discharged is fixed on the upper part of the block (8).

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