CN219424049U - Decarbonization device with high carbon-containing gas removal rate - Google Patents

Abstract

The utility model discloses a decarburization device with high removal rate of carbon-containing gas, which comprises a device body and an air inlet pipe, wherein the left end of the device body is connected with the air inlet pipe, the upper end of the device body is connected with the air outlet pipe, the front end of the device body is connected with a bin gate in a shaft manner, the rear end of the bin gate is connected with a first gear, the rear side of the first gear is provided with a double-sided rack, the inside of the device body is connected with a pressing plate in a clamping manner, and the lower end of the pressing plate is provided with an adsorption plate. This decarbonization device that carbonaceous gas desorption rate is high can remove the clamp plate when opening the bin gate through the rotation and to the fixed of adsorption plate, can dismantle it fast to can drive the clamp plate when closing the bin gate and push down fixedly to the adsorption plate downwards, save the time of dismouting adsorption plate, improve the convenience of use, can carry out the preliminary treatment to the air through the setting of filter screen, can filter the great dust granule that suspends in the air, prevent dust granule jam adsorption plate, improve adsorption plate life, save device's use cost.

Description

Decarbonization device with high carbon-containing gas removal rate

Technical Field

The utility model relates to the technical field of decarburization devices, in particular to a decarburization device with high removal rate of carbon-containing gas.

Background

The decarburization technology is more, and there are a physical method, a chemical method and an adsorption method, wherein the physical absorption method comprises an NHD method, a carbon-carbon method, a low-temperature methanol washing method and the like, the chemical method is typically a hot potash method, and the adsorption method is a new decarburization technology developed in recent years, and is mainly characterized in that: the consumption is low, the investment is high, the occupied area is large, and different decarburization methods can be adopted according to the characteristics of raw materials.

1. When the existing decarburization device is used, the adsorption method needs to periodically replace the adsorption material, but the existing device is inconvenient to fix and detach the adsorption material, can not quickly install and detach the adsorption material, and has low use and replacement efficiency;

2. the existing decarburization device cannot filter larger suspended particles in the air when in use, so that the adsorption material is easily blocked, and the service life of the adsorption material is reduced.

So we propose a decarbonization device with high removal rate of carbon-containing gas in order to solve the above-mentioned problems.

Disclosure of Invention

The utility model aims to provide a decarbonization device with high removal rate of carbon-containing gas, which solves the problems that the existing decarbonization device provided by the background art is inconvenient to replace adsorption materials, is troublesome to detach and install, can not pretreat larger suspended particles such as dust in air, and has short service life and high overall cost.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the decarbonization device with high carbon-containing gas removal rate comprises a device body and an air inlet pipe:

the left end of the device body is connected with an air inlet pipe, the upper end of the device body is connected with an air outlet pipe, and the front end of the device body is connected with a bin gate through a shaft;

the rear end of the bin gate is connected with a first gear, and a double-sided rack is arranged on the rear side of the first gear;

the device comprises a device body, a pressing plate, a pressure plate and a suction plate, wherein the pressing plate is connected in a clamping manner in the device body;

the right end of the air inlet pipe is connected with a square pipe, an impeller is connected with an inner shaft of the square pipe, and a filter screen is arranged at the lower end of the device body.

Preferably, the first gear and the bin gate form a coaxial rotating structure, the rear end of the first gear is connected with the double-sided rack in a meshed mode, and the rear end of the double-sided rack is connected with the second gear in a meshed mode.

By adopting the technical scheme, the first gear is driven to rotate simultaneously through the rotary bin gate, and the second gear is driven to synchronously rotate while the rack is driven to move through the first gear.

Preferably, a worm is connected to the device body through a bearing, the left end of the worm is connected to the second gear, the worm and the second gear form a coaxial rotating structure, the front end of the worm is connected with a worm wheel in a meshed manner, and the worm wheel and the worm form a rotating structure.

By adopting the technical scheme, the worm can be driven to synchronously rotate through the second gear, and meanwhile, the worm can drive the worm wheel to synchronously rotate.

Preferably, the worm wheel lower extreme is connected with the threaded rod, and threaded rod lower extreme threaded connection has the movable rod to movable rod lower extreme carries out fixed connection with the clamp plate, the inside hollow structural design that is of clamp plate.

By adopting the technical scheme, the worm wheel can be rotated to drive the threaded rod to rotate, and the movable rod drives the pressing plate to move in the vertical direction inside the device body.

Preferably, the impeller upper end is connected with the third gear, square pipe right side upper end hub connection has the brush, and the brush is cross structural design.

By adopting the technical scheme, the impeller can be driven to rotate through the air entering the square tube, and the filter screen can be cleaned when the hairbrush arranged at the lower end of the filter screen rotates, so that the filter screen is prevented from being blocked.

Preferably, the lower end of the brush is connected with a fourth gear, the fourth gear is meshed with the third gear to form a rotary structure, and the diameter of the fourth gear is larger than that of the third gear.

By adopting the technical scheme, the third gear is driven to rotate through the rotation of the impeller, and the fourth gear and the hairbrush are driven to synchronously rotate through the third gear, so that the filter screen is cleaned.

Compared with the prior art, the utility model has the beneficial effects that: the decarbonization device has high removal rate of the carbon-containing gas;

1. the bin gate is opened in a rotating mode, the fixation of the pressing plate to the adsorption plate can be relieved, the bin gate can be quickly disassembled, the pressing plate can be driven to downwards press and fix the adsorption plate when the bin gate is closed, the time for disassembling the adsorption plate is saved, the use convenience is improved, the bin gate drives the first gear to rotate, the rack drives the second gear and the worm to rotate, the worm wheel and the threaded rod are driven to rotate when the worm rotates, and therefore the movable rod drives the pressing plate to move;

2. can carry out the preliminary treatment to the air through the setting of filter screen, can filter the great dust granule of suspension in the air, prevent that dust granule from blockking up the adsorption plate, improve adsorption plate life, economizer's use cost.

Drawings

FIG. 1 is a schematic elevational view of the present utility model;

FIG. 2 is a schematic elevational cross-sectional view of the present utility model;

FIG. 3 is a schematic view of a first gear and a double-sided rack of the present utility model;

FIG. 4 is a schematic view of the structure of the movable rod and the pressing plate of the present utility model;

fig. 5 is an enlarged schematic view of the structure of fig. 2 a according to the present utility model.

In the figure: 1. a device body; 2. an air inlet pipe; 3. an air outlet pipe; 4. a bin gate; 5. a first gear; 6. double-sided racks; 7. a second gear; 8. a worm; 9. a worm wheel; 10. a threaded rod; 11. a movable rod; 12. a pressing plate; 13. an adsorption plate; 14. square tubes; 15. an impeller; 16. a filter screen; 17. a third gear; 18. a brush; 19. and a fourth gear.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, the present utility model provides a technical solution: the utility model provides a decarbonization device that carbonaceous gas desorption rate is high, including device body 1 and intake pipe 2, device body 1 left end is connected with intake pipe 2, and device body 1 upper end is connected with outlet duct 3, device body 1 front end hub connection has bin gate 4, bin gate 4 rear end is connected with first gear 5, and first gear 5 rear side is provided with double-sided rack 6, device body 1 inside block is connected with clamp plate 12, and clamp plate 12 lower extreme is provided with adsorption plate 13, first gear 5 constitutes coaxial revolution mechanic with bin gate 4, and first gear 5 rear end and double-sided rack 6 meshing connection, and double-sided rack 6 rear end meshing connection has second gear 7, can drive first gear 5 through rotatory bin gate 4, and drive double-sided rack 6 activity and then drive second gear 7 through first gear 5 and rotate, device body 1 inside run-through bearing is connected with 8, and worm 8 left end and second gear 7 are connected, and worm 8 and second gear 7 constitute coaxial revolution mechanic, and worm 8 front end meshing connection has 9, and worm wheel 9 and worm wheel 8 revolution mechanic and worm wheel 8 constitute coaxial revolution mechanic, 10 and 10, and the top end 10 and 10 are connected with the screw rod 11 when the top end is connected with the screw rod is realized to the rotation of the screw rod is 12, and the top end is realized to the rotation of the screw rod is realized by the rotation of the fixed rod that the two-side rod is 11, and the top thread rod is 11 is connected with the 10, and is realized by the rotation of the rotation rod is connected with the top thread rod 11 when the top rod is changed, and the top rod is 11, and the top rod is connected with the top rod 11 through the rotation rod is changed, and the top rod is 11.

As shown in fig. 1 and 2, the right end of the air inlet pipe 2 is connected with a square pipe 14, the inner shaft of the square pipe 14 is connected with an impeller 15, the lower end of the device body 1 is provided with a filter screen 16, the upper end of the impeller 15 is connected with a third gear 17, the right upper end of the square pipe 14 is connected with a brush 18, the brush 18 is of a cross-shaped structural design, the lower end of the brush 18 is connected with a fourth gear 19, the fourth gear 19 and the third gear 17 are in meshed connection to form a rotary structure, the diameter of the fourth gear 19 is larger than that of the third gear 17, decarburized air can be pretreated through the arrangement of the filter screen 16, larger dust particles suspended in the air can be filtered, and when the air enters the square pipe 14, the impeller 15 can be driven to rotate, the third gear 17 is synchronously driven to rotate, and the brush 18 is driven to rotate through the fourth gear 19, so that the filter screen 16 is cleaned, and dust blockage is prevented.

Working principle: when using this decarbonization device that carbonaceous gas desorption rate is high, can drive first gear 5 through rotatory bin gate 4 and drive double-sided rack 6 activity and then drive second gear 7 through first gear 5 and rotate, can drive worm 8 and rotate when second gear 7 rotates, and drive worm wheel 9 and threaded rod 10 synchronous rotation through worm 8, simultaneously threaded rod 10 can drive clamp plate 12 and move up and down vertically through movable rod 11, movable rod 11 drives clamp plate 12 upward movement and releases the fixed to adsorption plate 13 when opening bin gate 4, the convenience is changed adsorption plate 13, can carry out the preliminary treatment to decarbonization air through the setting of filter screen 16, can filter the great dust granule that suspends in the air, and when air gets into square pipe 14 inside, can drive impeller 15 and rotate, synchronous drive third gear 17 rotates, and drive brush 18 through fourth gear 19 and rotate, clean filter screen 16, prevent that the dust from blocking up, can reduce the change frequency of adsorption plate 13, reduce use cost.

To complete a series of work, and what is not described in detail in this specification is prior art that is well known to those skilled in the art.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. The utility model provides a decarbonization device that carbonaceous gas desorption rate is high, includes device body (1) and intake pipe (2), its characterized in that:

the left end of the device body (1) is connected with an air inlet pipe (2), the upper end of the device body (1) is connected with an air outlet pipe (3), and the front end of the device body (1) is connected with a bin gate (4) through a shaft;

the rear end of the bin gate (4) is connected with a first gear (5), and a double-sided rack (6) is arranged at the rear side of the first gear (5);

the device is characterized in that a pressing plate (12) is connected in a clamping manner in the device body (1), and an adsorption plate (13) is arranged at the lower end of the pressing plate (12);

the right end of the air inlet pipe (2) is connected with a square pipe (14), an impeller (15) is connected with the inner shaft of the square pipe (14), and a filter screen (16) is arranged at the lower end of the device body (1).

2. The decarburization facility having a high removal rate of a carbonaceous gas as set forth in claim 1, wherein: the first gear (5) and the bin gate (4) form a coaxial rotating structure, the rear end of the first gear (5) is connected with the double-sided rack (6) in a meshed mode, and the rear end of the double-sided rack (6) is connected with the second gear (7) in a meshed mode.

3. The decarburization facility having a high removal rate of a carbonaceous gas as set forth in claim 1, wherein: the device is characterized in that a worm (8) is connected to the inside through bearing of the device body (1), the left end of the worm (8) is connected with the second gear (7), the worm (8) and the second gear (7) form a coaxial rotating structure, the front end of the worm (8) is connected with a worm wheel (9) in a meshed mode, and the worm wheel (9) and the worm (8) form a rotating structure.

4. A decarbonizing apparatus having a high removal rate of carbon-containing gas according to claim 3, wherein: the lower extreme of worm wheel (9) is connected with threaded rod (10), and threaded rod (10) lower extreme threaded connection has movable rod (11) to movable rod (11) lower extreme and clamp plate (12) carry out fixed connection, clamp plate (12) inside is cavity form structural design.

5. The decarburization facility having a high removal rate of a carbonaceous gas as set forth in claim 1, wherein: the upper end of the impeller (15) is connected with a third gear (17), the upper end shaft of the right side of the square tube (14) is connected with a brush (18), and the brush (18) is in a cross-shaped structural design.

6. The decarburization facility having a high removal rate of a carbonaceous gas as set forth in claim 5 wherein: the lower end of the hairbrush (18) is connected with a fourth gear (19), the fourth gear (19) is meshed with the third gear (17) to form a rotary structure, and the diameter of the fourth gear (19) is larger than that of the third gear (17).