CN221889438U - Activated carbon adsorption device - Google Patents

Abstract

The utility model relates to an activated carbon adsorption device, comprising: an adsorption box, a filter plate, a cleaning component and a telescopic cylinder. A first installation cavity is opened in the adsorption box, a filter plate is arranged in the first installation cavity, a cleaning component is slidably arranged on the filter plate, the cleaning component is movably abutted against two sides of the filter plate, and the telescopic cylinder is drivingly connected to the cleaning component. In this way, the filter plate can filter impurities in the exhaust gas entering the first installation cavity. The cleaning component is driven by the telescopic cylinder to make reciprocating motion on the outer surface of the filter plate, so that the cleaning component can be pushed from the first end of the filter plate to the second end of the filter plate. The moving cleaning component can scrape off the impurities accumulated on the filter plate, successfully reducing the accumulation of impurities on the filter plate, improving the effect of the filter plate in filtering exhaust gas, allowing the gas in the exhaust gas to better pass through the filter plate, while also reducing the number of impurities mixed in the exhaust gas.

Description

Activated carbon adsorption device

Technical Field

The utility model relates to the technical field of waste gas adsorption, in particular to an activated carbon adsorption device.

Background Art

Activated carbon adsorption device is a common gas purification equipment, which is mainly used to remove organic matter, odor and some gaseous pollutants in the gas. It is widely used in various places that need to purify the air and remove organic matter and odor.

At present, the activated carbon adsorption devices on the market are usually provided with a filter plate and an activated carbon layer. The filter plate is used to filter impurities in the exhaust gas. However, with the increase of usage time, a large amount of impurities will accumulate on the filter plate. The accumulated solid impurities will block the filter plate, resulting in the exhaust gas being unable to pass through the filter plate, causing the activated carbon layer to be unable to contact the exhaust gas, making it difficult to filter the exhaust gas. In addition, the accumulated impurities will also adhere to the activated carbon layer, blocking the adsorption mesh of the activated carbon layer, making it impossible for the activated carbon layer to effectively adsorb the exhaust gas, and the exhaust gas adsorption effect is poor.

Utility Model Content

Based on this, it is necessary to provide an activated carbon adsorption device.

The technical solution of the utility model to solve the above technical problems is as follows:

An activated carbon adsorption device, comprising:

An adsorption box body, wherein a first installation cavity is formed in the adsorption box body, an air inlet is formed on the adsorption box body, the air inlet is communicated with the first installation cavity, and a dust collecting cavity is formed on a side wall of the first installation cavity;

A filter plate, the filter plate being arranged in the first installation cavity, the filter plate being arranged toward the air inlet, and a dust discharge hole being opened on a first end of the filter plate;

A cleaning component, wherein the cleaning component is slidably disposed on the filter plate, and the cleaning component is movably abutted against two surfaces of the filter plate, and the cleaning component reciprocates on the outer surface of the filter plate;

A telescopic cylinder is drivingly connected to the cleaning component, and is used to drive the cleaning component to perform reciprocating motion on the outer surface of the filter plate.

In one embodiment, two slide grooves are spaced apart on the side wall of the installation cavity, the two slide grooves are arranged opposite to each other, and the cleaning assembly is slidably arranged in the two slide grooves.

In one embodiment, guide blocks are respectively disposed on both sides of the cleaning assembly, and each guide block is slidably disposed in one of the slide grooves.

In one embodiment, the cleaning assembly includes a first cleaning part and a second cleaning part, the first end of the first cleaning part is connected to the first end of the second cleaning part, the second end of the first cleaning part is connected to the second end of the second cleaning part, the first cleaning part is movably abutted against the first surface of the filter plate, the second cleaning part is movably abutted against the second surface of the filter plate, the telescopic cylinder is drivingly connected to the first cleaning part or the second cleaning part, and the guide block is arranged on the first cleaning part or the second cleaning part.

In one embodiment, it further includes: a push plate, which is slidably disposed in the first installation cavity, and when the push plate slides, it passes through the dust exhaust hole and pushes impurities into the dust collecting cavity.

In one embodiment, it further includes: a water absorption plate, a second installation cavity is opened in the adsorption box, the second installation cavity is communicated with the first installation cavity, and the water absorption plate is slidably arranged in the second installation cavity.

In one embodiment, it further includes: an activated carbon plate, wherein the number of the activated carbon plates is multiple, and each of the activated carbon plates and the water absorption plate are slidably arranged in the second installation cavity in sequence, and the water absorption plate is arranged close to the first installation cavity.

In one embodiment, it further includes: a fan, an air outlet is opened on the side wall of the second installation cavity, and the fan is arranged in the air outlet.

The beneficial effects of the utility model are as follows: an activated carbon adsorption device provided by the utility model opens a first installation cavity in an adsorption box body, a filter plate is arranged in the first installation cavity, a cleaning component is slidably arranged on the filter plate, the cleaning component is movably abutted against two sides of the filter plate, and the telescopic cylinder is driven and connected to the cleaning component. In this way, the filter plate can filter impurities in the exhaust gas entering the first installation cavity, and the cleaning component is driven by the telescopic cylinder to make reciprocating motion on the outer surface of the filter plate, so that the cleaning component can be pushed from the first end of the filter plate to the second end of the filter plate. The moving cleaning component can scrape off the impurities accumulated on the filter plate, successfully reducing the accumulation of impurities on the filter plate, improving the effect of the filter plate in filtering exhaust gas, allowing the gas in the exhaust gas to better pass through the filter plate, while also reducing the number of impurities mixed in the exhaust gas.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings required for use in the embodiments will be briefly introduced below. It should be understood that the following drawings only show certain embodiments of the present application and therefore should not be regarded as limiting the scope. For ordinary technicians in this field, other related drawings can be obtained based on these drawings without paying creative work.

FIG1 is a schematic structural diagram of an activated carbon adsorption device according to an embodiment;

FIG2 is a schematic cross-sectional view of an activated carbon adsorption device according to one embodiment;

FIG3 is a schematic cross-sectional view of an activated carbon adsorption device according to an embodiment of the present invention from another direction;

FIG4 is a schematic cross-sectional view of an activated carbon adsorption device according to another embodiment;

FIG. 5 is a schematic diagram of the structure of a cleaning assembly and a push plate according to an embodiment.

In the accompanying drawings, 100, adsorption box; 110, first installation cavity; 120, air inlet; 130, dust collecting cavity; 140, second installation cavity; 150, entry hole; 160, slide groove; 200, filter plate; 210, cleaning assembly; 211, first cleaning part; 212, second cleaning part; 220, dust exhaust hole; 230, guide block; 300, push plate; 400, water absorption plate; 500, activated carbon plate; 600, air outlet; 700, fan; 800, telescopic cylinder; 810, telescopic rod.

DETAILED DESCRIPTION

It should be noted that, in the absence of conflict, the embodiments and features in the embodiments of the present invention can be combined with each other. The technical solution of the present invention will be further described below in conjunction with the drawings of the embodiments of the present invention, and the present invention is not limited to the following specific implementation methods.

It should be understood that the same or similar numbers in the drawings of the embodiments correspond to the same or similar parts. In the description of the present utility model, it should be understood that if there are terms such as "upper", "lower", "front", "back", "left", "right", "top", "bottom" and the like indicating the orientation or positional relationship, they are based on the orientation or positional relationship shown in the drawings, which is only for the convenience of describing the present utility model and simplifying the description, rather than indicating or implying that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation. Therefore, the terms describing the positional relationship in the drawings are only used for illustrative purposes and cannot be understood as a limitation on this patent. For ordinary technicians in this field, the specific meanings of the above terms can be understood according to specific circumstances.

In one embodiment, as shown in FIGS. 1 to 5 , an activated carbon adsorption device includes: an adsorption box 100, a filter plate 200, a cleaning assembly 210, and a telescopic cylinder 800, wherein a first mounting cavity 110 is provided in the adsorption box 100, an air inlet 120 is provided on the adsorption box 100, and the air inlet 120 is communicated with the first mounting cavity 110, a dust collecting cavity 130 is provided on the side wall of the first mounting cavity 110, and the filter plate 200 is arranged in the first mounting cavity 110, and the filter plate 200 faces The air inlet 120 is provided, a dust exhaust hole 220 is opened on the first end of the filter plate 200, the cleaning component 210 is slidably provided on the filter plate 200, and the cleaning component 210 is movably abutted against two sides of the filter plate 200, the cleaning component 210 reciprocates on the outer surface of the filter plate 200, the telescopic cylinder 800 is drivingly connected to the cleaning component 210, and the telescopic cylinder 800 is used to drive the cleaning component 210 to reciprocate on the outer surface of the filter plate 200.

In this embodiment, the cleaning component 210 is slidably set on the filter plate 200, the cleaning component 210 is movably abutted against two sides of the filter plate 200, and the telescopic cylinder 800 is driven and connected to the cleaning component 210. In this way, the exhaust gas can enter the first installation cavity 110 through the air inlet 120, and the filter plate 200 filters impurities in the exhaust gas entering the first installation cavity 110. The telescopic cylinder 800 drives the cleaning component 210 to reciprocate on the outer surface of the filter plate 200, so that the cleaning component 210 can move from the first end of the filter plate 200 to the second end of the filter plate 200, so that the cleaning component 210 in motion can abut against two sides of the filter plate 200, and can scrape off impurities on both sides of the filter plate 200, thereby reducing the accumulation of impurities on the filter plate 200, improving the effect of the filter plate 200 in filtering exhaust gas, and allowing the gas in the exhaust gas to better pass through the filter plate 200 while also reducing the number of impurities mixed in the exhaust gas.

In this embodiment, a telescopic rod 810 is provided in the telescopic cylinder 800, and the telescopic rod 810 is connected to the cleaning assembly 210. The telescopic cylinder 800 pushes the telescopic rod 810, and the telescopic rod 810 pushes the cleaning assembly 210, so that the cleaning assembly 210 can reciprocate on the outer surface of the filter plate 200, thereby enabling the cleaning assembly 210 to clean impurities on both sides of the filter plate 200.

In one embodiment, as shown in FIGS. 2 to 4 , two slide grooves 160 are provided on the side wall of the installation cavity, the two slide grooves 160 are arranged opposite to each other, and the cleaning assembly 210 is slidably provided in the two slide grooves 160. Specifically, the two sides of the filter plate 200 are connected to the side wall of the first installation cavity 110, and two slide grooves 160 are provided on the side wall of the first installation cavity 110 at this connection, and the cleaning assembly 210 is slidably provided in the two slide grooves 160, so that the exhaust gas in the first installation cavity 110 can be prevented from leaking, and a movement space is provided for the cleaning assembly 210, so that the cleaning assembly 210 can reciprocate on the outer surface of the filter plate 200, so that the cleaning assembly 210 can clean the impurities on the filter plate 200.

In one embodiment, as shown in FIGS. 2 to 5 , guide blocks 230 are respectively disposed on both sides of the cleaning assembly 210, and each guide block 230 is slidably disposed in one of the slide grooves 160. Specifically, the guide block 230 can guide the sliding direction of the cleaning assembly 210 in the slide groove 160, so that the cleaning assembly 210 can slide in the slide groove 160 better.

In one embodiment, as shown in Figures 2 to 5, the cleaning assembly 210 includes a first cleaning part 211 and a second cleaning part 212, the first end of the first cleaning part 211 is connected to the first end of the second cleaning part 212, the second end of the first cleaning part 211 is connected to the second end of the second cleaning part 212, the first cleaning part 211 is movably abutted against the first surface of the filter plate 200, the second cleaning part 212 is movably abutted against the second surface of the filter plate 200, the telescopic cylinder 800 is drivingly connected to the first cleaning part 211 or the second cleaning part 212, and the guide block 230 is arranged on the first cleaning part 211 or the second cleaning part 212. Specifically, the first cleaning part 211 and the second cleaning part 212 are connected to form an annular structure, which is sleeved on the outer surface of the filter plate 200, and the annular structure is movably abutted against the two surfaces of the filter plate 200. An entry hole 150 is opened on the adsorption box 100, and the entry hole 150 is connected to the slide groove 160. The telescopic rod 810 in the telescopic cylinder 800 enters the slide groove 160 through the entry hole 150 and is connected to the annular structure. The two guide blocks 230 are respectively arranged at both ends of the annular structure. In this way, the telescopic rod 810 is driven by the telescopic cylinder 800. Moving in the slide groove 160, the moving telescopic rod 810 can drive the annular structure located in the slide groove 160 to make reciprocating motion on the outer surface of the filter plate 200, wherein the first cleaning part 211 is provided with first bristles, the first bristles abut against the first surface of the filter plate 200, and the first bristles clean the impurities on the first surface of the filter plate 200, and the second cleaning part 212 is provided with second bristles, the second bristles abut against the second surface of the filter plate 200, and the second bristles clean the impurities on the second surface of the filter plate 200, thereby realizing the cleaning of impurities on both sides of the filter plate 200.

In one embodiment, as shown in FIG. 4 and FIG. 5 , it further includes: a push plate 300, the push plate 300 is slidably disposed in the first mounting cavity 110, and when the push plate 300 slides, it passes through the dust discharge hole 220 and pushes the impurities into the dust collecting cavity 130. Specifically, the cleaning component 210 is located on the first end of the filter plate 200. Since the height of the cleaning component 210 is greater than the height of the dust discharge hole 220, the cleaning component 210 can close the dust discharge hole 220, and can prevent the exhaust gas from passing through the dust discharge hole 220, so that the exhaust gas passes through the filter plate 200, and the impurities in the exhaust gas can be filtered. The filtered impurities will accumulate on the filter plate 200; when it is necessary to clean the impurities on the filter plate 200, the impurities on both sides of the filter plate 200 are cleaned by the cleaning component 210, and the cleaning component 210 is removed from the filter plate 20 0 moves to the second end of the filter plate 200, and impurities on both sides of the filter plate are scraped off and fall onto the bottom side wall of the first installation cavity 110. At this time, the cleaning component 210 is located on the second end of the filter plate 200, and the dust discharge hole 220 is not closed by the cleaning component 210. The push plate 300 can be pushed so that the push plate 300 can push the impurities through the dust discharge hole 220 when sliding in the first installation cavity 110, and the impurities can be pushed into the dust collecting cavity 130. An opening is provided on the side wall of the dust collecting cavity 130, and the impurities in the dust collecting cavity 130 can be discharged through the opening.

In one embodiment, as shown in FIGS. 2 to 4 , a water absorption plate 400 is further included. A second installation cavity 140 is provided in the adsorption box 100. The second installation cavity 140 is communicated with the first installation cavity 110. The water absorption plate 400 is slidably arranged in the second installation cavity 140. Specifically, the exhaust gas filtered by the filter plate 200 enters the second installation cavity 140 from the first installation cavity 110. The water absorption plate 400 in the second installation cavity 140 can absorb moisture in the exhaust gas, which is convenient for subsequent treatment of the exhaust gas. An installation groove is provided on the side wall of the second installation cavity 140. By sliding the water absorption plate 400 into or out of the installation groove, the water absorption plate 400 can be loaded and unloaded in a relatively simple manner, which greatly facilitates the installation and disassembly of the water absorption plate 400.

In one embodiment, as shown in FIG. 2 to FIG. 4 , it further includes: an activated carbon plate 500, the number of which is multiple, each of which is slidably arranged in the second installation cavity 140 with the water absorption plate 400, and the water absorption plate 400 is arranged near the first installation cavity 110. Specifically, the water absorption plate 400 is arranged near the first installation cavity 110, and each activated carbon plate 500 is arranged above the water absorption plate 400. The exhaust gas after being filtered by the water absorption plate 400 does not contain water, so that the activated carbon plate 500 can better filter the exhaust gas. The arrangement of multiple activated carbon plates 500 can make more activated carbon in the second installation cavity 140, provide more adsorption sites, thereby improving the adsorption efficiency of the activated carbon plate 500 on the exhaust gas. At the same time, the activated carbon plate 500 is arranged in the installation groove in a sliding manner, which can be more convenient to install and remove the activated carbon plate 500, which greatly facilitates the installation and removal of the activated carbon plate 500.

In one embodiment, as shown in FIG. 4 , it further includes: a fan 700, an air outlet 600 is provided on the side wall of the second installation cavity 140, and the fan 700 is arranged in the air outlet 600. Specifically, the air outlet 600 is communicated with the second installation cavity 140, and the suction force generated by the fan 700 can discharge the gas filtered by the filter plate 200 from the air outlet 600 through the fan 700 arranged in the air outlet 600, and at the same time, the suction force generated by the fan 700 can ensure that the exhaust gas flows smoothly through each activated carbon plate 500, so that the exhaust gas can enter the second installation cavity 140 faster and contact the activated carbon plate 500, which can accelerate the process of the activated carbon plate 500 adsorbing the exhaust gas, thereby improving the adsorption effect of the activated carbon plate 500 on the exhaust gas.

Compared with the prior art, the utility model has at least the following advantages:

The utility model provides an activated carbon adsorption device, which opens a first installation cavity in an adsorption box, arranges a filter plate in the first installation cavity, and slides a cleaning component on the filter plate. The cleaning component is movably abutted against two sides of the filter plate, and a telescopic cylinder is driven and connected to the cleaning component. In this way, the filter plate can filter impurities in the exhaust gas entering the first installation cavity. The cleaning component is driven to make reciprocating motion on the outer surface of the filter plate by the telescopic cylinder, and can be pushed from the first end of the filter plate to the second end of the filter plate. The moving cleaning component can scrape off the impurities accumulated on the filter plate, successfully reducing the accumulation of impurities on the filter plate, improving the effect of the filter plate in filtering exhaust gas, allowing the gas in the exhaust gas to pass through the filter plate better, and also reducing the number of impurities mixed in the exhaust gas.

Obviously, the above embodiments of the utility model are only examples for clearly explaining the utility model, and are not intended to limit the implementation methods of the utility model. For ordinary technicians in the relevant field, other different forms of changes or modifications can be made on the basis of the above description. It is not necessary and impossible to list all the implementation methods here. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the utility model should be included in the protection scope of the claims of the utility model.

Claims (8)

1. An activated carbon adsorption device, comprising: An adsorption box body, wherein a first installation cavity is formed in the adsorption box body, an air inlet is formed on the adsorption box body, the air inlet is communicated with the first installation cavity, and a dust collecting cavity is formed on a side wall of the first installation cavity; A filter plate, the filter plate being arranged in the first installation cavity, the filter plate being arranged toward the air inlet, and a dust discharge hole being opened on a first end of the filter plate; A cleaning component, wherein the cleaning component is slidably disposed on the filter plate, and the cleaning component is movably abutted against two surfaces of the filter plate, and the cleaning component reciprocates on the outer surface of the filter plate; A telescopic cylinder is drivingly connected to the cleaning component, and is used to drive the cleaning component to perform reciprocating motion on the outer surface of the filter plate. 2. The activated carbon adsorption device according to claim 1 is characterized in that two slide grooves are spaced apart on the side wall of the installation cavity, the two slide grooves are arranged opposite to each other, and the cleaning component is slidably arranged in the two slide grooves. 3. The activated carbon adsorption device according to claim 2 is characterized in that guide blocks are respectively provided on both sides of the cleaning component, and each of the guide blocks is slidably arranged in one of the slide grooves. 4. The activated carbon adsorption device according to claim 3 is characterized in that the cleaning assembly includes a first cleaning part and a second cleaning part, the first end of the first cleaning part is connected to the first end of the second cleaning part, the second end of the first cleaning part is connected to the second end of the second cleaning part, the first cleaning part is movably abutted against the first surface of the filter plate, the second cleaning part is movably abutted against the second surface of the filter plate, the telescopic cylinder is drivingly connected to the first cleaning part or the second cleaning part, and the guide block is arranged on the first cleaning part or the second cleaning part. 5. The activated carbon adsorption device according to claim 4 is characterized in that it also includes: a push plate, which is slidably arranged in the first installation cavity, and when the push plate slides, it passes through the dust exhaust hole and pushes the impurities into the dust collecting cavity. 6. The activated carbon adsorption device according to claim 1 is characterized in that it also includes a water absorption plate, a second installation cavity is opened in the adsorption box, the second installation cavity is connected to the first installation cavity, and the water absorption plate is slidably arranged in the second installation cavity. 7. The activated carbon adsorption device according to claim 6 is characterized in that it also includes: an activated carbon plate, the number of the activated carbon plates is multiple, each of the activated carbon plates and the water absorption plate is slidably arranged in the second installation cavity in sequence, and the water absorption plate is arranged close to the first installation cavity. 8. The activated carbon adsorption device according to claim 7, characterized in that it also includes: a fan, an air outlet is opened on the side wall of the second installation cavity, and the fan is arranged in the air outlet.