A high-efficiency wire mesh separation tower
By employing a servo motor controller to control the movement of the wire blocks in a high-efficiency wire mesh separation tower, and combining it with a glass fiber filter and activated carbon filter layer, the inconvenience of gas purification and wire mesh replacement in existing technologies has been solved, achieving both convenience and efficiency in gas purification and wire mesh replacement.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU HUAI JIANG TECH CO LTD
- Filing Date
- 2025-06-12
- Publication Date
- 2026-06-30
Smart Images

Figure CN224422272U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of separation tower technology, specifically to a high-efficiency wire mesh separation tower. Background Technology
[0002] Wire mesh separators are core equipment for achieving efficient gas-liquid separation in chemical and related fields. They separate substances based on differences in their physical properties. When a gas-liquid mixture flows through the wire mesh layer, droplets larger than the mesh pore size are intercepted due to the mesh's porous structure. Simultaneously, after colliding and adhering to the mesh, the droplets converge into larger droplets due to surface tension and gravity, thus achieving gas-liquid separation. The core of a wire mesh separator is the wire mesh element, which is made of various materials, such as stainless steel or 904L wire mesh, to meet the separation requirements of different media. The wire mesh is typically stacked in multiple layers within the tower to increase separation efficiency and specific surface area.
[0003] Existing high-efficiency wire mesh separation towers are not convenient for purifying the gas after liquid separation, and are not convenient for cleaning or replacing wire mesh filter plates. Utility Model Content
[0004] To address the problems in the existing technology, this utility model provides a high-efficiency wire mesh separation tower. The high-efficiency wire mesh separation tower facilitates the purification of the gas after liquid separation and makes it easy to clean or replace the wire mesh filter plate.
[0005] The technical solution adopted by this utility model to solve its technical problem is a high-efficiency wire mesh separation tower, including a base, a pool, a tower body and a discharge cylinder. The top of the base is bolted to the pool, and the top of the pool is connected to the tower body. Servo motor controllers are mounted on both sides of the bottom of the tower body through mounting seats. The output shaft of the servo motor is connected to a lead screw through a coupling, and wire blocks are sleeved on the lead screw. A top cover is installed between the wire blocks by screws.
[0006] The bottom sides of the top cover are connected to wire mesh filter plates by hanging rods, and the wire mesh filter plates are located inside the main body of the tower. The outer ends of the wire mesh filter plates are fitted with elastic rubber sleeves. The top of the top cover is connected to a discharge cylinder welded together, and a cap is installed at the top of the discharge cylinder by screws. A limiting groove is provided in the cap, and a glass fiber filter is installed in the limiting groove by screws. An activated carbon filter layer is provided between the glass fiber filters.
[0007] By adopting the above technical solution, the high-efficiency wire mesh separation tower facilitates the purification of the gas after liquid separation and makes it easy to clean or replace the wire mesh filter plate.
[0008] Specifically, a servo motor controller is mounted on one end of the servo motor by screws, and the output end of the servo motor controller is electrically connected to the input end of the servo motor by wires.
[0009] By adopting the above technical solution, the forward and reverse rotation of the servo motor is controlled by the servo motor controller, thereby causing the lead block to move back and forth on the lead screw.
[0010] Specifically, L-shaped support plates are bolted to the top of the base and located on both sides of the pool body, and the top of the lead screw is connected to the L-shaped support plate via a bearing.
[0011] Specifically, the elastic sleeve is made of silicone rubber, and the wire mesh filter plate is made of layers of stainless steel wire mesh.
[0012] By adopting the above technical solution, due to the porous structure of the wire mesh, droplets larger than the wire mesh aperture will be intercepted. At the same time, after the droplets collide and adhere to the wire mesh, they will converge into large droplets due to surface tension and gravity and fall into the pool, thereby achieving gas-liquid separation.
[0013] Specifically, an air inlet pipe and a liquid outlet pipe are respectively provided at the top and bottom of one side of the pool.
[0014] Specifically, control valves are installed on both the air inlet pipe and the liquid outlet pipe.
[0015] The beneficial effects of this utility model are:
[0016] (1) The high-efficiency wire mesh separation tower of this utility model introduces chemical waste gas into the pool body through the inlet pipe and the gas gradually rises into the main body of the tower. The wire mesh filter plate is made of stainless steel wire mesh. When the gas-liquid mixture flows through the wire mesh layer, due to the porous structure of the wire mesh, droplets larger than the wire mesh aperture will be intercepted. At the same time, after the droplets collide and adhere to the wire mesh, they converge into large droplets due to surface tension and gravity and fall into the pool body, thereby realizing gas-liquid separation.
[0017] (2) The high-efficiency wire mesh separation tower of this utility model allows the gas after liquid separation to continue to enter the discharge cylinder. The glass fiber filter facilitates the filtration of small particles and impurities in the gas, and the activated carbon filter layer facilitates the adsorption of toxic and harmful substances in the gas, thereby purifying the gas before it is discharged. The servo motor controller controls the forward and reverse rotation of the servo motor, thereby causing the wire block to move back and forth on the screw, which facilitates the lifting of the top cover, thus exposing the wire mesh filter plate at the bottom of the top cover to the main body of the tower, making it easy to clean or replace the wire mesh filter plate. Attached Figure Description
[0018] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0019] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0020] Figure 2This is a schematic diagram of the internal structure of the wire mesh filter plate and cap of this utility model;
[0021] Figure 3 This is a schematic diagram of the glass fiber filter and activated carbon filter layer structure of this utility model.
[0022] In the diagram: 1. Pool body; 2. Servo motor controller; 3. Servo motor; 4. Tower body; 5. Top cover; 6. Discharge cylinder; 7. Cap; 8. Fiberglass filter screen; 9. Lead screw; 10. L-shaped support plate; 11. Wire block; 12. Base; 13. Drain pipe; 14. Air inlet pipe; 15. Elastic rubber sleeve; 16. Wire mesh filter plate; 17. Hanging rod; 18. Limiting groove; 19. Activated carbon filter layer. Detailed Implementation
[0023] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.
[0024] To facilitate the purification of the gas after liquid separation in the high-efficiency wire mesh separation tower, and to make it easy to clean or replace the wire mesh filter plate 16, such as... Figure 1-3 As shown, the high-efficiency wire mesh separation tower of this utility model includes a base 12, a pool body 1, a tower body 4, and a discharge cylinder 6. The top of the base 12 is bolted to the pool body 1, and the top of the pool body 1 is connected to the tower body 4. Both sides of the bottom end of the tower body 4 are mounted with servo motor controllers 2 via mounting seats. The output shaft of the servo motor 3 is connected to a lead screw 9 via a coupling, and wire blocks 11 are sleeved on the lead screw 9. A top cover 5 is installed between the wire blocks 11 by screws.
[0025] The bottom sides of the top cover 5 are connected to wire mesh filter plates 16 by hanging rods 17 and the wire mesh filter plates 16 are located inside the tower body 4. The outer ends of the wire mesh filter plates 16 are fitted with elastic rubber sleeves 15. The top of the top cover 5 is connected to a discharge cylinder 6 and a cap 7 is installed at the top of the discharge cylinder 6 by screws. The cap 7 is provided with a limiting groove 18 and a glass fiber filter 8 is installed in the limiting groove 18 by screws. An activated carbon filter layer 19 is provided between the glass fiber filter screens 8.
[0026] When in use, the high-efficiency wire mesh separation tower facilitates the purification of the gas after liquid separation and makes it easy to clean or replace the wire mesh filter plate 16.
[0027] For example, such as Figure 1 As shown, the present invention also includes a servo motor controller 2 mounted on one end of the servo motor 3 by screws, and the output end of the servo motor controller 2 and the input end of the servo motor 3 are electrically connected by wires.
[0028] In use, the servo motor controller 2 controls the forward and reverse rotation of the servo motor 3, thereby causing the lead block 11 to move back and forth on the lead screw 9.
[0029] For example, such as Figure 1 As shown, the present invention also includes an L-shaped support plate 10 bolted to the top of the base 12 and located on both sides of the pool body 1, and the top of the lead screw 9 is connected to the L-shaped support plate 10 by a bearing.
[0030] When using it, make the lead screw 9 rotate stably and reduce shaking.
[0031] For example, such as Figure 1 , 2 As shown, the present invention also includes, specifically, the elastic sleeve 15 is made of silicone rubber material, and the wire mesh filter plate 16 is specifically made of stainless steel wire mesh stacked together.
[0032] During use, due to the porous structure of the wire mesh, droplets larger than the mesh aperture will be intercepted. At the same time, after the droplets collide and adhere to the wire mesh, they converge into large droplets due to surface tension and gravity and fall into the pool 1, thereby achieving gas-liquid separation.
[0033] For example, such as Figure 1 , 2 As shown, the present invention also includes an air inlet pipe 14 and a liquid outlet pipe 13 respectively provided at the top and bottom of one side of the pool body 1.
[0034] In use, the air inlet pipe 14 facilitates the introduction of chemical waste gas, and the liquid outlet pipe 13 facilitates the discharge of the separated liquid.
[0035] For example, such as Figure 1 As shown, the present invention also includes control valves on both the air inlet pipe 14 and the liquid outlet pipe 13.
[0036] In use, the control valve facilitates the control of the air intake volume of the air intake pipe 14 and the liquid discharge volume of the liquid discharge pipe 13.
[0037] In use, chemical waste gas is introduced into the pool body 1 through the inlet pipe 14 and gradually rises into the tower body 4. The wire mesh filter plate 16 is made of stainless steel wire mesh. When the gas-liquid mixture flows through the wire mesh layer, due to the porous structure of the wire mesh, droplets larger than the wire mesh aperture will be intercepted. At the same time, after the droplets collide and adhere to the wire mesh, they converge into large droplets due to surface tension and gravity and fall into the pool body 1, thereby achieving gas-liquid separation.
[0038] After the liquid is separated, the gas continues to rise into the discharge cylinder 6. The glass fiber filter 8 facilitates the filtration of small particles and impurities in the gas, and the activated carbon filter layer 19 facilitates the adsorption of toxic and harmful substances in the gas, thereby purifying the gas before it is discharged.
[0039] The servo motor controller 2 controls the forward and reverse rotation of the servo motor 3, thereby causing the wire block 11 to move back and forth on the lead screw 9, which facilitates the lifting of the top cover 5, thus exposing the wire mesh filter plate 16 at the bottom of the top cover 5 to the tower body 4, making it easy to clean or replace the wire mesh filter plate 16. The elastic rubber sleeve 15 is made of silicone rubber material, which has high elasticity and good toughness, improving the sealing effect.
[0040] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The descriptions of the above embodiments and specifications are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of protection claimed by this utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A high-efficiency wire mesh separation tower, characterized in that, The system includes a base (12), a pool body (1), a tower body (4), and a discharge cylinder (6). The top of the base (12) is bolted to the pool body (1), and the top of the pool body (1) is connected to the tower body (4). Both sides of the bottom of the tower body (4) are mounted with servo motor controllers (2) via mounting seats. The output shaft of the servo motor (3) is connected to a lead screw (9) via a coupling, and a lead screw (9) is fitted with a lead screw block (11). A top cover (5) is installed between the lead screw blocks (11) via screws. The bottom sides of the top cover (5) are connected to wire mesh filter plates (16) by hanging rods (17), and the wire mesh filter plates (16) are located inside the main body of the tower (4). The outer ends of the wire mesh filter plates (16) are fitted with elastic rubber sleeves (15). The top of the top cover (5) is connected to a discharge cylinder (6) and a cap (7) is installed on the top of the discharge cylinder (6) by screws. A limiting groove (18) is provided in the cap (7), and a glass fiber filter (8) is installed in the limiting groove (18) by screws. An activated carbon filter layer (19) is provided between the glass fiber filter (8).
2. The high-efficiency wire mesh separation tower according to claim 1, characterized in that, One end of the servo motor (3) is fitted with a servo motor controller (2) by screws, and the output end of the servo motor controller (2) and the input end of the servo motor (3) are electrically connected by wires.
3. The high-efficiency wire mesh separation tower according to claim 1, characterized in that, The base (12) is topped with an L-shaped support plate (10) and located on both sides of the pool body (1) by bolts. The top of the lead screw (9) is connected to the L-shaped support plate (10) by a bearing.
4. The high-efficiency wire mesh separation tower according to claim 1, characterized in that, The elastic sleeve (15) is specifically made of silicone rubber, and the wire mesh filter plate (16) is specifically made of layers of stainless steel wire mesh.
5. The high-efficiency wire mesh separation tower according to claim 1, characterized in that, An air inlet pipe (14) and a liquid outlet pipe (13) are respectively provided at the top and bottom of one side of the pool body (1).
6. The high-efficiency wire mesh separation tower according to claim 5, characterized in that, Both the air inlet pipe (14) and the liquid outlet pipe (13) are equipped with control valves.