Activated carbon filter device
By using a spring-loaded retraction mechanism to vibrate the filter plate and incorporating a clogging plate design, the clogging problem in activated carbon filtration devices is solved, enabling efficient separation and regeneration of granular activated carbon and improving filtration efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- INNER MONGOLIA TANJING ENVIRONMENTAL PROTECTION TECHNOLOGY CO LTD
- Filing Date
- 2025-06-13
- Publication Date
- 2026-06-09
AI Technical Summary
In existing activated carbon filtration devices, larger particles of impurities easily clog the mesh during filtration, leading to decreased filtration efficiency or even complete blockage, especially resulting in unsatisfactory separation and regeneration effects for granular activated carbon.
The design employs a spring retraction mechanism to drive the filter plate to vibrate. Combined with the use of a unclogging plate, the filter plate and the unclogging plate work together to achieve secondary filtration of granular activated carbon and unclog the feed inlet, preventing blockage.
It improves filtration efficiency, reduces the filtration burden, effectively prevents clogging, and enhances the separation and regeneration effects of granular activated carbon.
Smart Images

Figure CN224332738U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of activated carbon technology, and in particular relates to an activated carbon filtration device. Background Technology
[0002] Waste activated carbon is mostly divided into powdered activated carbon and granular activated carbon. When waste activated carbon needs to be regenerated, since powdered activated carbon and granular activated carbon have different regeneration methods, they usually need to be separated by filtration to prevent them from mixing together during regeneration and resulting in unsatisfactory regeneration effect.
[0003] When processing granular activated carbon, filtration is usually required to separate the particles by size. However, existing filtration devices use a single filter plate, which can cause larger particles to clog the mesh, leading to a rapid decrease in filtration efficiency or even complete blockage. To address this, we provide an activated carbon filtration device. Utility Model Content
[0004] The purpose of this invention is to provide an activated carbon filtration device. By using a spring to retract, the second filter plate is pulled upwards, causing it to vibrate and perform secondary filtration. Since the pores of the first filter plate are larger than those of the second filter plate, the burden during filtration is reduced and the filtration efficiency is improved. After filtration, the first baffle and the second baffle are opened to collect the activated carbon particles above the second filter plate. This solves the problem that existing activated carbon filtration uses a single filter plate, which may cause larger particles of impurities to directly clog the mesh, leading to a rapid decrease in filtration efficiency or even complete blockage.
[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0006] This utility model relates to an activated carbon filtration device, comprising a filtration section for filtering activated carbon material; and:
[0007] An anti-clogging section is installed above the filter section and is used to unclog the activated carbon material.
[0008] In this process, activated carbon material is fed into the filtration section through the anti-clogging section, and then filtered through the filtration section.
[0009] Furthermore, the filtration unit includes a power assembly for providing power to the device;
[0010] A reinforcing component, installed inside the power assembly, is used for secondary filtration of the activated carbon material; and:
[0011] A filter assembly, which is installed inside the power assembly, is used to filter activated carbon material.
[0012] In this process, after the activated carbon material enters the power component, it is filtered by a filtration component, and then the filtered material is filtered a second time by a reinforcement component.
[0013] Furthermore, the anti-clogging part includes a pushing component, which is used to clear the blockage of the activated carbon material;
[0014] A transmission assembly is mounted on the right side of the push assembly, and the transmission assembly is used to provide power to the push assembly;
[0015] The transmission component drives the push component to move, and then the push component drives the feed inlet to clear the blockage.
[0016] Furthermore, the power assembly includes a processing box, a connecting plate is fixedly connected to the right side of the processing box, a motor is fixedly connected to the top of the connecting plate, a rotating shaft is fixedly connected to the left output end of the motor via a coupling, the left side of the rotating shaft extends into the interior of the processing box, and a rotating block is fixedly connected to the outer surface of the rotating shaft;
[0017] The reinforcing component includes two slides inside the processing box. Each slide has a support block slidably connected to its inner wall. A spring is fixedly connected to the inner wall of each support block. The top of the spring is fixedly connected to the inner wall of the slide. A filter plate is fixedly connected to one side of the support blocks that are close to each other. A collection frame is inserted into the front of the processing box. A baffle is hinged to the left side of the processing box.
[0018] When the motor drives the rotating shaft to rotate, it will simultaneously drive the rotating block to rotate.
[0019] Furthermore, the filter assembly includes a fixed plate fixedly connected to the inner wall of the processing box, a filter plate in contact with the top of the fixed plate, a spring fixedly connected to the top of the filter plate, a guide plate fixedly connected to the top of the spring, the outer surface of the guide plate fixedly connected to the inner wall of the processing box, a protrusion fixedly connected to the bottom of the filter plate, and a baffle hinged to the left side of the processing box.
[0020] After filtration is completed, the baffle is opened to clean the activated carbon material located above the filter plate. The springs are protected by retractable protective rods fitted on the outer surface of the four springs to prevent the granular activated carbon from affecting the springs. The top of the protective rods is fixed to the bottom of the guide plate, and the bottom of the guide plate has a circular groove.
[0021] Furthermore, the pushing assembly includes a feed hopper fixedly connected to the top of the processing box, a support frame fixedly connected to the inner wall of the feed hopper, a second spring fixedly connected to the top of the support frame, a movable rod slidably connected to the inner wall of the support frame, the movable rod and the second spring being sleeved together, the bottom of the movable rod penetrating the support frame, a rack fixedly connected to the back of the movable rod, and a drain plate fixedly connected to the bottom of the movable rod.
[0022] When the movable rod moves downward, it simultaneously moves the unblocking plate, and then the unblocking plate moves to unclog the feed hopper.
[0023] Furthermore, the transmission assembly includes a connecting rod rotatably connected inside the feed hopper, a pulley one fixedly connected to the outer surface of the right side of the connecting rod, a belt drivingly connected to the outer surface of the pulley one, a pulley two drivingly connected to the other end of the belt, the inner wall of the pulley two fixedly connected to the outer surface of the rotating shaft, and a half gear fixedly connected to the outer surface of the connecting rod, the front of the half gear meshing with the back of the rack.
[0024] When the movable rod moves downward, it compresses the second spring. After the rack and half gear disengage, the second spring rebounds to reset the movable rod. A protective cover is installed on the outside of the rack and half gear to protect them. The inner wall of the protective cover slides against the outer surface of the rack. The rotating shaft and the protective cover are rotatably connected.
[0025] This utility model has the following beneficial effects:
[0026] 1. This utility model features a second filter plate. Specifically, when the rotating block reaches the bottom, it pushes the second filter plate downwards. The downward movement of the second filter plate causes the support block to slide down the groove and stretch the spring. After the rotating block disengages from the second filter plate, the spring retracts and pulls the second filter plate upwards, causing it to vibrate and perform secondary filtration. Since the holes in the filter plate are larger than those in the second filter plate, the burden during filtration is reduced and the filtration efficiency is improved. After filtration is completed, the first and second baffles are opened to collect the granular activated carbon particles above the filter plate and the second filter plate.
[0027] 2. This utility model uses a drain plate, specifically a pulley that rotates to drive a connecting rod. When the connecting rod rotates, it simultaneously drives a half gear to rotate, which in turn drives a rack to move downwards. As the rack moves downwards, it simultaneously drives a movable rod to move and compresses a spring. The movable rod then moves the drain plate downwards, thus clearing the feed inlet of the hopper and preventing blockage.
[0028] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description
[0029] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0030] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0031] Figure 2 This is a schematic diagram of the overall structure of the rotating block of this utility model;
[0032] Figure 3 This is a schematic diagram of the overall structure of the filter plate of this utility model;
[0033] Figure 4 This is a schematic cross-sectional view of the back of the feed hopper of this utility model;
[0034] Figure 5 This is a schematic diagram of the overall structure of the unblocking board of this utility model;
[0035] Figure 6 This utility model Figure 3 A magnified structural diagram of A in the middle.
[0036] The attached diagram lists the components represented by each number as follows:
[0037] 1. Filter section; 11. Power assembly; 111. Processing box; 112. Connecting plate; 113. Motor; 114. Rotating shaft; 115. Rotating block; 12. Reinforcing assembly; 121. Filter plate II; 122. Slide groove; 123. Support block; 124. Spring; 125. Collection frame; 126. Baffle I; 13. Filter assembly; 131. Filter plate; 132. Baffle; 133. Guide plate; 134. Spring I; 135. Fixing plate; 136. Protrusion; 2. Anti-clogging section; 21. Pushing assembly; 211. Feed hopper; 212. Support frame; 213. Spring II; 214. Movable rod; 215. Rack; 216. Unblocking plate; 22. Transmission assembly; 221. Connecting rod; 222. Belt; 223. Belt pulley I; 224. Half gear; 225. Belt pulley II. Detailed Implementation
[0038] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of the present utility model.
[0039] Please see Figures 1-6As shown, this utility model is an activated carbon filtration device, including a filter section 1 for filtering activated carbon material; and an anti-clogging section 2 installed above the filter section 1 for unclogging the activated carbon material. The activated carbon material is fed into the filter section 1 through the anti-clogging section 2 and then filtered through the filter section 1. The filter section 1 includes a power assembly 11 for providing power to the device; a reinforcing assembly 12 installed inside the power assembly 11 for secondary filtration of the activated carbon material; and a filter assembly 13 installed inside the power assembly 11 for further filtration of the activated carbon material. The process includes filtration; after the activated carbon material enters the power assembly 11, it is filtered by the filter assembly 13, and then filtered again by the reinforcing assembly 12; the anti-clogging part 2 includes a pushing assembly 21, which is used to clear the activated carbon material; a transmission assembly 22, which is installed on the right side of the pushing assembly 21 and provides power to the pushing assembly 21; the transmission assembly 22 drives the pushing assembly 21 to move, and then the pushing assembly 21 drives the feed inlet to clear the blockage; the power assembly 11 includes a processing box 111, a connecting plate 112 is fixedly connected to the right side of the processing box 111, and a motor 1 is fixedly connected to the top of the connecting plate 112. 13. A rotating shaft 114 is fixedly connected to the left output end of the motor 113 via a coupling. The left side of the rotating shaft 114 extends into the interior of the processing box 111. A rotating block 115 is fixedly connected to the outer surface of the rotating shaft 114. The reinforcing component 12 includes a slide groove 122 opened inside the processing box 111. There are two slide grooves 122. A support block 123 is slidably connected to the inner wall of each slide groove 122. A spring 124 is fixedly connected to the inner wall of the support block 123. The top of the spring 124 is fixedly connected to the inner wall of the slide groove 122. A filter plate 121 is fixedly connected to the side of the support blocks 123 that are close to each other. A collection frame 125 is inserted into the front of the processing box 111. A baffle 126 is hinged to the left side of the processing box 111. Among them, when the motor 113 drives the rotating shaft 114 to rotate... When in motion, the rotating block 115 will rotate synchronously. When the rotating block 115 reaches the bottom, it will push the filter plate 121 downward. Then, the downward movement of the filter plate 121 will drive the support block 123 to slide down along the slide groove 122 and stretch the spring 124. After the rotating block 115 disengages from the filter plate 121, the spring 124 retracts and pulls the filter plate 121 upward, causing it to vibrate and perform secondary filtration. Since the holes of the filter plate 131 are larger than those of the filter plate 121, the burden during filtration is reduced and the filtration efficiency is improved. After filtration is completed, the baffle 126 and the baffle 132 are opened to collect the granular activated carbon above the filter plate 131 and the filter plate 121.The filter assembly 13 includes a fixed plate 135 fixedly connected to the inner wall of the processing box 111. The top of the fixed plate 135 contacts the filter plate 131. A spring 134 is fixedly connected to the top of the filter plate 131. A guide plate 133 is fixedly connected to the top of the spring 134. The outer surface of the guide plate 133 is fixedly connected to the inner wall of the processing box 111. A protrusion 136 is fixedly connected to the bottom of the filter plate 131. A baffle 132 is hinged to the left side of the processing box 111. After filtration, the baffle 132 is opened to clean the activated carbon material located above the filter plate 131. The pushing assembly 21 includes a fixed connection... The feed hopper 211 is located at the top of the processing box 111. A support frame 212 is fixedly connected to the inner wall of the feed hopper 211. A spring 213 is fixedly connected to the top of the support frame 212. A movable rod 214 is slidably connected to the inner wall of the support frame 212. The movable rod 214 and the spring 213 are sleeved together. The bottom of the movable rod 214 passes through the support frame 212. A rack 215 is fixedly connected to the back of the movable rod 214. A drain plate 216 is fixedly connected to the bottom of the movable rod 214. When the movable rod 214 moves downward, it will simultaneously drive the drain plate 216 to move. Then, the movement of the drain plate 216 will move the feed hopper 211. 1. To clear blockages, pulley 223 rotates, causing connecting rod 221 to rotate. The rotation of connecting rod 221 synchronously drives half gear 224 to rotate, which in turn drives rack 215 to move downwards. As rack 215 moves downwards, it synchronously drives movable rod 214 to move, compressing spring 213. The movement of movable rod 214 then drives unblocking plate 216 downwards, clearing the feed inlet of hopper 211 and preventing blockages. The transmission assembly 22 includes connecting rod 223 rotatably connected inside hopper 211. 1. A pulley 223 is fixedly connected to the outer surface of the right side of the connecting rod 221. A belt 222 is driven to the outer surface of the pulley 223. A pulley 225 is driven to the other end of the belt 222. The inner wall of the pulley 225 is fixedly connected to the outer surface of the rotating shaft 114. A half gear 224 is fixedly connected to the outer surface of the connecting rod 221. The front of the half gear 224 meshes with the back of the rack 215. When the movable rod 214 moves downward, it will compress the spring 213. After the rack 215 disengages from the half gear 224, the spring 213 rebounds to reset the movable rod 214.
[0040] A specific application of this embodiment is as follows: In use, the activated carbon material is first poured into the feed hopper 211, then the motor 113 is started. The motor 113 drives the rotating shaft 114 to rotate, which in turn drives the pulley 225 to rotate. As the pulley 225 rotates, the belt 222 synchronously drives the pulley 223 to rotate, which in turn drives the connecting rod 221 to rotate. As the connecting rod 221 rotates, it synchronously drives the half gear 224 to rotate, which in turn drives the rack 215 downwards. When the rack 215 moves downward, it synchronously drives the movable rod 214 to move, compressing the spring 213. The movable rod 214 then moves the unblocking plate 216 downward, clearing the feed inlet of the hopper 211 to prevent blockage. When the half gear 224 disengages from the rack 215, the spring 213 rebounds to reset the movable rod 214. When the activated carbon material enters the processing box 111 through the feed hopper 211, it falls above the filter plate 131. The rotating shaft 114 then rotates, driving the rotating block 115 to rotate. Rotating block 115 pushes protrusion 136 upward, causing filter plate 131 to move upward and compressing spring 134. When rotating block 115 disengages from protrusion 136, spring 134 rebounds, pushing filter plate 131 downward and causing it to collide with fixed plate 135, resulting in vibration of filter plate 131. This vibration then performs the first filtration of granular activated carbon, which falls onto filter plate 121 below filter plate 131. When rotating block 115 reaches the bottom, it... The filter plate 121 is pushed downwards, and the downward movement of the filter plate 121 causes the support block 123 to slide downwards along the slide groove 122, stretching the spring 124. After the rotating block 115 disengages from the filter plate 121, the spring 124 retracts and pulls the filter plate 121 upwards, causing it to vibrate and perform secondary filtration. Since the holes of the filter plate 131 are larger than those of the filter plate 121, the burden during filtration is reduced and the filtration efficiency is improved. After filtration is completed, the baffle 126 and the baffle 132 are opened to collect the granular activated carbon above the filter plate 131 and the filter plate 121.
[0041] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.
[0042] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the present utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the present utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.
Claims
1. An activated carbon filtration device, characterized in that, include: The filter section (1) is used to filter activated carbon materials; as well as: Anti-clogging part (2), the anti-clogging part (2) is installed above the filter part (1), the anti-clogging part (2) is used to unclog the activated carbon material; In this process, activated carbon material is fed into the filter section (1) through the anti-clogging section (2), and then filtered through the filter section (1).
2. The activated carbon filtration device according to claim 1, characterized in that, The filter section (1) includes a power assembly (11) for providing power to the device; A reinforcing component (12), which is installed inside the power assembly (11), is used for secondary filtration of the activated carbon material; and: A filter assembly (13) is installed inside the power assembly (11) and is used to filter activated carbon material. In this process, after the activated carbon material enters the power component (11), it is filtered by the filter component (13), and then the filtered material is filtered again by the reinforcement component (12).
3. The activated carbon filtration device according to claim 2, characterized in that, The anti-clogging part (2) includes a pushing component (21) for clearing the activated carbon material; A transmission assembly (22) is mounted on the right side of the push assembly (21) and is used to provide power to the push assembly (21); The transmission component (22) drives the push component (21) to move, and then the push component (21) drives the feed inlet to be cleared.
4. The activated carbon filtration device according to claim 3, characterized in that, The power assembly (11) includes a processing box (111), a connecting plate (112) is fixedly connected to the right side of the processing box (111), a motor (113) is fixedly connected to the top of the connecting plate (112), and a rotating shaft (114) is fixedly connected to the left output end of the motor (113) through a coupling. The left side of the rotating shaft (114) extends into the processing box (111), and a rotating block (115) is fixedly connected to the outer surface of the rotating shaft (114). The reinforcing component (12) includes a slide (122) inside the processing box (111). There are two slides (122). The inner walls of the slides (122) are slidably connected to support blocks (123). The inner walls of the support blocks (123) are fixedly connected to springs (124). The top of the springs (124) is fixedly connected to the inner walls of the slides (122). The side of the support blocks (123) that are close to each other is fixedly connected to filter plate two (121). A collection frame (125) is inserted into the front of the processing box (111). A baffle plate one (126) is hinged to the left side of the processing box (111). When the motor (113) drives the rotating shaft (114) to rotate, it will synchronously drive the rotating block (115) to rotate.
5. An activated carbon filtration device according to claim 4, characterized in that, The filter assembly (13) includes a fixing plate (135) fixedly connected to the inner wall of the processing box (111). The top of the fixing plate (135) contacts the filter plate (131). A spring (134) is fixedly connected to the top of the filter plate (131). A guide plate (133) is fixedly connected to the top of the spring (134). The outer surface of the guide plate (133) is fixedly connected to the inner wall of the processing box (111). A protrusion (136) is fixedly connected to the bottom of the filter plate (131). A baffle (132) is hinged to the left side of the processing box (111). After filtration is completed, the baffle (132) is opened to clean the activated carbon material located above the filter plate (131).
6. An activated carbon filtration device according to claim 5, characterized in that, The pushing assembly (21) includes a feed hopper (211) fixedly connected to the top of the processing box (111). A support frame (212) is fixedly connected to the inner wall of the feed hopper (211). A spring (213) is fixedly connected to the top of the support frame (212). A movable rod (214) is slidably connected to the inner wall of the support frame (212). The movable rod (214) and the spring (213) are sleeved together. The bottom of the movable rod (214) passes through the support frame (212). A rack (215) is fixedly connected to the back of the movable rod (214). A drain plate (216) is fixedly connected to the bottom of the movable rod (214). When the movable rod (214) moves downward, it will simultaneously drive the unblocking plate (216) to move, and then the unblocking plate (216) will move to unblock the feed hopper (211).
7. An activated carbon filtration device according to claim 6, characterized in that, The transmission assembly (22) includes a connecting rod (221) rotatably connected inside the feed hopper (211). A pulley (223) is fixedly connected to the outer surface of the right side of the connecting rod (221). A belt (222) is drivenly connected to the outer surface of the pulley (223). A pulley (225) is drivenly connected to the other end of the belt (222). The inner wall of the pulley (225) is fixedly connected to the outer surface of the rotating shaft (114). A half gear (224) is fixedly connected to the outer surface of the connecting rod (221). The front of the half gear (224) meshes with the back of the rack (215). When the movable rod (214) moves downward, it will squeeze the second spring (213). After the rack (215) disengages from the half gear (224), the second spring (213) will rebound to reset the movable rod (214).