A storage device for electrode paste production
By introducing a flow chamber and a spiral guide plate into the electrode paste storage device, combined with the flow rate adjustment of the stirring rack and regulating rack, the problems of uneven cooling and flow rate incompatibility during the electrode paste storage process are solved, ensuring the uniformity of electrode paste raw materials and the stability of the production process.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NINGXIA YUFENG CARBON CO LTD
- Filing Date
- 2025-07-21
- Publication Date
- 2026-07-03
AI Technical Summary
Existing electrode paste storage devices experience uneven cooling at high temperatures, leading to raw material quality issues. Furthermore, the fixed flow rate cooling system cannot adapt to varying operating conditions, and the adjustment mechanism is prone to loosening, affecting product quality and production stability.
The system employs a flow cavity between the storage tank and the inner cylinder, along with a spiral guide plate design. Combined with a motor-driven stirring rack, it achieves uniform cooling. The conical structure of the delivery pipe and regulating rack allows for flexible adjustment of the cooling water flow rate. A multi-locking mechanism using a limiting sleeve and a limiting rod ensures flow rate stability.
It achieves uniform cooling of electrode paste raw materials, solves the problem of uneven cooling, adapts to the needs of changing working conditions, improves the applicability of equipment and the consistency of product quality, and reduces production risks and maintenance workload.
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Figure CN224448895U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of electrode paste storage technology, and more specifically, to a storage device for electrode paste production. Background Technology
[0002] In existing technologies, electrode paste, as an important raw material in the electrometallurgical industry, involves multiple high-temperature treatment processes in its production. These processes can cause the temperature of raw materials or semi-finished products to reach hundreds of degrees Celsius or even higher. Under such high temperatures, the physical and chemical properties of electrode paste raw materials are unstable. If effective cooling is not carried out, the high temperature will cause irreversible changes in the internal structure of the raw materials, affecting the quality and performance of the final product. Traditional storage devices usually use natural cooling or simple air cooling methods for cooling. Natural cooling relies entirely on ambient temperature and air convection for heat dissipation, and the cooling rate is extremely slow and greatly affected by external environmental factors. It is almost impossible to achieve effective cooling in hot weather or in a confined space. Although simple air cooling can provide a certain cooling effect, the uneven distribution of airflow often leads to significant differences in the cooling effect in different parts of the storage container, forming an obvious temperature gradient. This uneven cooling process will generate thermal and temperature stress inside the raw materials, leading to quality problems such as cracking, deformation, and component separation.
[0003] Secondly, although some equipment uses water bath heat exchange to achieve cooling, these devices have revealed obvious defects in control systems and insufficient adaptability in practical applications. The fixed flow rate cooling water delivery system cannot adapt to the changing working conditions in the electrode paste production process. Different batches of raw materials have significantly different cooling requirements due to differences in proportions, processing history, initial temperature, and other factors. High-temperature raw materials require a large flow rate of cooling water for rapid cooling, while relatively low-temperature raw materials only require a small flow rate of cooling water for gentle cooling. The fixed flow rate design obviously cannot meet these differentiated needs. The fixed flow rate system also cannot be dynamically adjusted according to external factors such as ambient temperature, seasonal changes, and equipment load. In the high-temperature environment of summer, the cooling capacity may be insufficient, while in the low-temperature environment of winter, there may be problems with over-cooling. This lack of flexibility in design seriously limits the applicability and economy of the equipment.
[0004] Furthermore, while some equipment addresses the limitations of fixed flow rates by adding regulating mechanisms, these simple flow rate regulating structures, although capable of altering the cooling water flow rate to some extent, lack sufficient structural strength and anti-interference capabilities. In the actual industrial environment of electrode paste production, the cooling water piping system is subjected to complex and variable working loads, including pressure shocks during pump start-up and shutdown, mechanical disturbances transmitted from equipment vibrations, and other adverse factors. When the pump suddenly starts or stops, a momentary high-pressure shock wave is generated inside the piping. The peak value of this pressure shock often far exceeds the normal operating pressure, causing strong impact loads on the fixed components of the regulating mechanism. Simple regulating structures are prone to loosening under such impact loads. Displacement can cause deviations in the originally precisely adjusted flow rate parameters. More seriously, once the regulating mechanism shifts, operators often fail to detect it in time, leading to the cooling system operating under incorrect flow rate parameters for extended periods. This not only affects the cooling effect but may also cause irreversible damage to the quality of raw materials. Furthermore, external factors such as environmental vibrations, personnel operations, and equipment movement in the production site can have a cumulative impact on the stability of the regulating mechanism. Especially during long-term use, these minor disturbances can gradually weaken the fixing strength of the regulating mechanism, eventually leading to regulation failure. At the same time, an unreliable regulating system can increase the uncertainty and risk of the production process, affecting the consistency of product quality and the stable execution of production plans. Utility Model Content
[0005] (a) Technical problems to be solved
[0006] In view of the problems existing in the prior art, the present invention provides a storage device for electrode paste production to solve the technical problems mentioned in the background art.
[0007] (II) Technical Solution
[0008] To achieve the above objectives, this utility model provides the following technical solution: a storage device for electrode paste production, comprising a storage tank, a detachable conveying pump on one side of the storage tank, a conveying pipe connected to the output end of the conveying pump, an adjusting sleeve and a connecting pipe on one side of the conveying pipe, the two ends of the adjusting sleeve being rotatably connected to the conveying pipe and the connecting pipe respectively, a limiting sleeve on the outer side of the connecting pipe, the inner wall of the limiting sleeve being movably connected to the outer wall of the connecting pipe via threads, a threaded sleeve fixedly connected to the inner wall of the adjusting sleeve, a plurality of adjusting blocks movably disposed in the conveying pipe, and an adjusting frame movably disposed in the conveying pipe. One end of the adjusting frame is fixedly connected to a screw rod, the outer wall of which is movably connected to the inner wall of the screw sleeve via threads. Multiple limiting grooves are opened on the outer side of the connecting pipe. A limiting frame is fixedly installed on one side of the adjusting sleeve. A limiting rod is slidably installed in the limiting frame. A limiting spring is movably sleeved on the outer side of the limiting rod. A limiting plate is fixedly connected to one end of the limiting rod. The other end of the limiting rod is inserted into the limiting groove. The two ends of the limiting spring are respectively connected to the limiting plate and the limiting frame. The adjusting frame has a conical structure design. An adjusting groove is opened at an angle in the adjusting block. The adjusting frame is slidably connected to the adjusting block through the adjusting groove.
[0009] The present invention is further configured such that an inner cylinder is detachably provided on the inner side of the storage tank, a flow cavity is provided between the storage tank and the inner cylinder, and a guide plate is spirally installed in the flow cavity.
[0010] The present invention is further configured such that the output end of the connecting pipe is connected to the input end of the flow cavity, the output end of the flow cavity is connected to an output pipe, the input end of the delivery pump is connected to an input pipe, the other end of the input pipe is connected to the output end of the external cooling component, and the other end of the output pipe is connected to the input end of the external cooling component.
[0011] The present invention is further configured such that a pneumatic component is detachably provided on one side of the storage tank, a movable frame is rotatably provided on one side of the storage tank, a tank cover is detachably provided on one side of the movable frame, the two ends of the pneumatic component are rotatably connected to the storage tank and the movable frame respectively, a motor is detachably provided on the top of the tank cover, and a stirring frame is detachably connected to the output end of the motor.
[0012] The present invention is further configured such that a bracket is detachably provided at the bottom of the storage tank, a discharge valve is connected to the bottom of the storage tank, a feed pipe is detachably provided at the top of the tank cover, and a pipe cap is detachably connected to the top of the feed pipe by means of threads.
[0013] The present invention is further configured such that the adjusting block has multiple adjusting holes.
[0014] The present invention is further configured such that a mating groove is provided on one side of the adjusting block, and a mating block is fixedly provided inside the conveying pipe, and the adjusting block is slidably connected to the mating block through the mating groove.
[0015] The present invention is further provided that the outer walls of the adjusting sleeve and the limiting sleeve are both fixedly connected with multiple anti-slip strips.
[0016] (III) Beneficial Effects
[0017] Compared with the prior art, the present invention provides a storage device for electrode paste production, which has the following advantages:
[0018] 1. By using a flow cavity between the storage tank and the inner cylinder, along with a spirally installed guide plate and a motor-driven stirring rack to agitate the electrode paste stored inside the inner cylinder, uniform and effective cooling of the electrode paste raw material is achieved. This solves the problem of uneven cooling in traditional natural cooling and simple air cooling methods. The spiral guide plate creates a spiral flow trajectory for the cooling water in the flow cavity, significantly increasing the contact area and contact time between the cooling water and the storage container wall, thus improving heat exchange efficiency. At the same time, the agitation of the stirring rack ensures that all parts of the electrode paste raw material inside the inner cylinder receive sufficient heat transfer, avoiding local overheating or underheating, effectively eliminating temperature gradient distribution, and preventing the generation of internal thermal and temperature stresses in the raw material. This fundamentally avoids quality problems such as cracking, deformation, and component separation of the raw material, ensuring that the electrode paste raw material maintains good uniformity and stability during the cooling process, providing a high-quality raw material foundation for subsequent processing.
[0019] 2. Through the sliding connection design of the conveying pipe, connecting pipe, and the conical structure of the adjusting frame with the adjusting block's adjusting groove, flexible adjustment and precise control of the cooling water conveying flow rate are achieved. This effectively solves the problem that fixed flow rate systems cannot adapt to varying working conditions. When different batches of electrode paste raw materials have significantly different cooling requirements due to differences in proportion, processing history, initial temperature, etc., the operator can rotate the adjusting sleeve to drive the threaded transmission of the screw sleeve and screw, causing the adjusting frame to slide up or down. This, in turn, drives the adjusting block to move inward or outward through the adjusting groove, changing the distribution position of the adjusting holes in the conveying pipe and the distribution position of the adjusting block. This allows for precise adjustment of the actual flow area inside the delivery pipe, enabling stepless regulation of the cooling water flow rate. High-temperature raw materials can be rapidly cooled by increasing the flow area to obtain a large flow of cooling water, while relatively low-temperature raw materials can be gently cooled by reducing the flow area to obtain a small flow of cooling water. Furthermore, the system can dynamically adjust based on external factors such as ambient temperature, seasonal changes, and equipment load, providing sufficient cooling capacity in high-temperature summer environments and avoiding over-cooling in low-temperature winter environments. This significantly improves the applicability and economy of the equipment, ensuring the stability of the electrode paste production process and the consistency of product quality.
[0020] 3. A multi-locking mechanism is formed by the threaded connection between the limiting sleeve and the outer wall of the connecting pipe, the limiting rod slidingly installed inside the limiting frame, the limiting spring movably sleeved on the outside of the limiting rod, the limiting plate fixedly connected to one end of the limiting rod, and multiple limiting grooves opened on the outside of the connecting pipe. This mechanism achieves high stability and strong anti-interference capability of the flow rate adjustment structure, effectively solving the technical problem of easy loosening or displacement in simple adjustment mechanisms. When the cooling water delivery flow rate is adjusted to the appropriate parameters, the limiting rod achieves precise positioning of the limiting frame through the limiting groove, and the limiting sleeve forms an outer wall limit on the limiting plate through the threaded connection, constituting double locking protection. This multi-locking mechanism can effectively resist the instantaneous high-pressure shock wave generated when the water pump starts and stops, even if the peak value of the internal pressure shock in the pipeline exceeds... Under normal operating pressure, the fixed components of the regulating mechanism will not loosen, deform, or shift, ensuring that the originally precisely adjusted flow rate parameters remain stable. Simultaneously, this locking mechanism possesses excellent vibration and external force resistance, effectively resisting the cumulative effects of environmental vibrations, personnel operations, equipment movement, and other external forces in the production environment. Even during long-term use, there will be no weakening of the regulating mechanism's fixing strength or regulation failure, significantly improving the reliability and service life of the regulating system, reducing maintenance workload and human error, and significantly reducing uncertainty and risk in the production process. This ensures consistent product quality and stable execution of production plans, providing strong support for the company's economic benefits and market competitiveness. Attached Figure Description
[0021] Figure 1This is a schematic diagram of the overall structure of a storage device for electrode paste production according to the present invention;
[0022] Figure 2 This is a cross-sectional view of the storage tank and inner cylinder in this utility model.
[0023] Figure 3 This is a cross-sectional structural diagram of the connecting pipe, limiting sleeve, adjusting sleeve and conveying pipe in this utility model;
[0024] Figure 4 This is a schematic diagram of the dispersed structure of the connecting pipe, limiting sleeve, adjusting block, adjusting frame, adjusting sleeve and conveying pipe in this utility model;
[0025] Figure 5 This is a schematic diagram of the dispersed structure of the connecting pipe, adjusting sleeve, adjusting frame and adjusting block in this utility model.
[0026] In the diagram: 1. Storage tank; 2. Transfer pump; 3. Transfer pipe; 4. Adjusting sleeve; 5. Connecting pipe; 6. Limiting sleeve; 7. Screw sleeve; 8. Adjusting block; 9. Adjusting frame; 10. Screw; 11. Limiting groove; 12. Limiting frame; 13. Limiting rod; 14. Limiting spring; 15. Limiting plate; 16. Adjusting groove; 17. Inner cylinder; 18. Flow chamber; 19. Guide plate; 20. Output pipe; 21. Input pipe; 22. Pneumatic assembly; 23. Movable frame; 24. Tank lid; 25. Motor; 26. Stirring frame; 27. Support; 28. Discharge valve; 29. Feed pipe; 30. Pipe cover; 31. Adjusting hole; 32. Mating groove; 33. Mating block; 34. Anti-slip strip. Detailed Implementation
[0027] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. The present invention will now be described in detail with reference to the accompanying drawings and embodiments.
[0028] It should be noted that, unless otherwise specified, all technical and scientific terms used in this application have the same meaning as commonly understood by one of ordinary skill in the art to which this application pertains.
[0029] In this utility model, unless otherwise stated, the orientations used, such as "up" and "down", usually refer to the direction shown in the accompanying drawings, or to the vertical, perpendicular, or gravitational direction; similarly, for ease of understanding and description, "left" and "right" usually refer to the left and right shown in the accompanying drawings; "inner" and "outer" refer to the inner and outer contours of each component itself, but the above directional terms are not used to limit this utility model.
[0030] Please see Figures 1-5A storage device for electrode paste production includes a storage tank 1. A conveying pump 2 is detachably mounted on one side of the storage tank 1. A conveying pipe 3 is connected to the output end of the conveying pump 2. An adjusting sleeve 4 and a connecting pipe 5 are mounted on one side of the conveying pipe 3. The two ends of the adjusting sleeve 4 are rotatably connected to the conveying pipe 3 and the connecting pipe 5, respectively. A limiting sleeve 6 is mounted on the outside of the connecting pipe 5. The inner wall of the limiting sleeve 6 is movably connected to the outer wall of the connecting pipe 5 by threads. A screw sleeve 7 is fixedly connected to the inner wall of the adjusting sleeve 4. Multiple adjusting blocks 8 are movably mounted in the conveying pipe 3. An adjusting frame 9 is movably mounted in the conveying pipe 3. A screw 10 is fixedly connected to one end of the adjusting frame 9. The outer wall of the connecting pipe 5 is movably connected to the inner wall of the screw sleeve 7 via threads. Multiple limiting grooves 11 are provided on the outer side of the connecting pipe 5. A limiting frame 12 is fixedly provided on one side of the adjusting sleeve 4. A limiting rod 13 is slidably provided in the limiting frame 12. A limiting spring 14 is movably sleeved on the outer side of the limiting rod 13. A limiting plate 15 is fixedly connected to one end of the limiting rod 13. The other end of the limiting rod 13 is inserted into the limiting groove 11. The two ends of the limiting spring 14 are respectively connected to the limiting plate 15 and the limiting frame 12. The adjusting frame 9 has a conical structure design. An adjusting groove 16 is inclinedly provided in the adjusting block 8. The adjusting frame 9 is slidably connected to the adjusting block 8 through the adjusting groove 16.
[0031] The storage tank 1 has a detachable inner cylinder 17, and a flow cavity 18 is provided between the storage tank 1 and the inner cylinder 17. A guide plate 19 is spirally installed in the flow cavity 18.
[0032] The output end of the connecting pipe 5 is connected to the input end of the flow chamber 18. The output end of the flow chamber 18 is connected to the output pipe 20. The input end of the delivery pump 2 is connected to the input pipe 21. The other end of the input pipe 21 is connected to the output end of the external cooling component. The other end of the output pipe 20 is connected to the input end of the external cooling component.
[0033] A pneumatic component 22 is detachably provided on one side of the storage tank 1, and a movable frame 23 is rotatably provided on one side of the storage tank 1. A tank cover 24 is detachably provided on one side of the movable frame 23. The two ends of the pneumatic component 22 are rotatably connected to the storage tank 1 and the movable frame 23 respectively. A motor 25 is detachably provided on the top of the tank cover 24, and a stirring frame 26 is detachably connected to the output end of the motor 25.
[0034] The storage tank 1 is detachably equipped with a bracket 27 at the bottom end, and a discharge valve 28 is connected to the bottom end of the storage tank 1. The top of the tank cover 24 is detachably equipped with a feed pipe 29, and the top of the feed pipe 29 is detachably connected with a pipe cap 30 by a thread.
[0035] In this embodiment, when the device is needed, the pneumatic assembly 22 is first driven forward, causing it to push the movable frame 23 to move, which in turn causes the can lid 24 to close. Then, the pipe cover 30 is removed, and the feed pipe 29 is connected to the external feeding device. The electrode paste is then conveyed to the inner cylinder 17 inside the storage tank 1. The external cooling assembly is then turned on to cool the cooling water. The delivery pump 2 is then turned on, and the cooled water is drawn out through the input pipe 21 connected to the input end of the delivery pump 2. The cooled water is then discharged through the output pipe connected to the output end of the delivery pump 2. The delivery pipe 3 delivers the extracted cooling water to the connecting pipe 5, and then through the connecting pipe 5 to the flow chamber 18, so that the cooling water flows along the spiral structure guide plate 19 to achieve heat exchange and cooling. At the same time, the motor 25 is turned on, and the motor 25 drives the stirring rack 26 to turn the electrode paste stored in the inner cylinder 17, further promoting cooling efficiency and cooling uniformity, and avoiding local insufficient cooling. Then, the cooled water after heat exchange is finally discharged to the outside of the flow chamber 18 through the output pipe 20, and then delivered to the external cooling component again through the delivery pipe 3 for cooling, realizing the recycling of cooling water.
[0036] Please see Figures 3-5 As a further implementation of the overall equipment: the adjusting block 8 is provided with multiple adjusting holes 31.
[0037] The adjusting block 8 has a mating groove 32 on one side, and a mating block 33 is fixed inside the conveying pipe 3. The adjusting block 8 is slidably connected to the mating block 33 through the mating groove 32.
[0038] Multiple anti-slip strips 34 are fixedly connected to the outer walls of both the adjusting sleeve 4 and the limiting sleeve 6.
[0039] More specifically, when the cooling water delivery flow rate needs to be adjusted according to usage requirements, firstly, the limiting sleeve 6 is rotated forward. The limiting sleeve 6 will move along the thread on the outer wall of the connecting pipe 5, so that the inner wall of the limiting sleeve 6 gradually no longer limits the outer wall of the limiting plate 15. Then, the adjusting sleeve 4 is rotated forward. The adjusting sleeve 4 will drive the limiting frame 12 on one side to rotate forward. Then, the inner wall of the limiting groove 11 presses against one end of the limiting rod 13. Due to the rounded corner design of the inner wall edge of the limiting groove 11 and one end of the limiting rod 13, one end of the limiting rod 13 will slide out of the limiting groove 11, and the limiting rod 13... The other end will cause the limiting plate 15 to slide outward, causing the limiting plate 15 to pull the limiting spring 14 outward. At the same time, the adjusting sleeve 4 will cause the inner threaded sleeve 7 to rotate in the forward direction. Since the screw 10 and the threaded sleeve 7 are connected by threads, and the mating block 33 and the mating groove 32 limit the adjusting block 8, the adjusting block 8 will then limit the adjusting frame 9 through the adjusting groove 16, so that the adjusting frame 9 and the screw 10 will not rotate. Then the screw 10 will cause the adjusting frame 9 to slide downward, and then the adjusting frame 9 will cause the adjusting block 8 to slide outward through the adjusting groove 16, so that the adjusting... The segment 8 drives the mating groove 32 to slide outward along the mating block 33, and the adjusting block 8 drives multiple adjusting holes 31 to move outward. The movement of the adjusting holes 31, combined with the outward sliding of the adjusting block 8, changes the actual flow area inside the conveying pipe 3, thereby achieving the purpose of adjusting the cooling water conveying flow rate. When the cooling water conveying flow rate is adjusted appropriately, the adjusting sleeve 4 is stopped from rotating, and the limiting frame 12 drives the limiting rod 13 and other components to rotate to the position corresponding to the corresponding limiting groove 11. Then, the limiting spring 14 resets and pulls the limiting plate 15, causing the limiting plate 15 to drive the limiting rod 13 inward. The sliding motion allows one end of the limiting rod 13 to be inserted into the corresponding limiting groove 11. Then, the limiting sleeve 6 is rotated in the opposite direction, and the limiting sleeve 6 moves and resets along the thread on the outer wall of the connecting pipe 5. This causes the inner wall of the limiting sleeve 6 to re-limit the outer wall of the limiting plate 15, preventing the limiting plate 15 and the limiting rod 13 from sliding outward. Then, the limiting rod 13 and the limiting groove 11 cooperate to lock the limiting frame 12, preventing the limiting frame 12 and the adjusting sleeve 4 from rotating accidentally. This ensures the structural stability after the flow rate adjustment, ensures the stable delivery of cooling water, and thus ensures the stable operation of the cooling process.
[0040] In summary, when using or operating the entire equipment: First, drive the pneumatic assembly 22 in the forward direction, causing it to push the movable frame 23 to move, which in turn causes the tank cover 24 to close. Then, remove the pipe cover 30, connect the feed pipe 29 to the external feeding device, and then transport the electrode paste to the inner cylinder 17 inside the storage tank 1. Next, turn on the external cooling assembly to cool the cooling water. Then, turn on the delivery pump 2, which draws out the cooled water through the input pipe 21 connected to the input end, and then outputs the cooled water through the delivery pump 2. The end-connected conveying pipe 3 delivers the extracted cooling water to the connecting pipe 5, and then through the connecting pipe 5 to the flow chamber 18, so that the cooling water flows along the spiral structure guide plate 19 to achieve heat exchange and cooling. At the same time, the motor 25 is turned on, and the motor 25 drives the stirring rack 26 to turn over the electrode paste stored in the inner cylinder 17, further promoting cooling efficiency and cooling uniformity, and avoiding local insufficient cooling. Then, the cooled water after heat exchange is finally discharged to the outside of the flow chamber 18 through the output pipe 20, and then transported again to the external cooling component through the conveying pipe 3 for cooling, realizing the recycling of cooling water.
[0041] When the cooling water delivery flow rate needs to be adjusted according to usage requirements, firstly, rotate the limiting sleeve 6 in the forward direction. The limiting sleeve 6 will move along the thread on the outer wall of the connecting pipe 5, so that the inner wall of the limiting sleeve 6 gradually no longer limits the outer wall of the limiting plate 15. Then, rotate the adjusting sleeve 4 in the forward direction. The adjusting sleeve 4 will drive the limiting frame 12 on one side to rotate in the forward direction. Then, the inner wall of the limiting groove 11 will press against one end of the limiting rod 13. Due to the rounded corner design of the inner wall edge of the limiting groove 11 and one end of the limiting rod 13, one end of the limiting rod 13 will slide out of the limiting groove 11, and the other end of the limiting rod 13 will... The limiting plate 15 slides outward, causing the limiting spring 14 to stretch outward. Simultaneously, the adjusting sleeve 4 causes the inner threaded sleeve 7 to rotate forward. Since the screw 10 and threaded sleeve 7 are connected by threads, and the mating block 33 and mating groove 32 limit the adjusting block 8, the adjusting block 8 then limits the adjusting frame 9 through the adjusting groove 16, preventing the adjusting frame 9 and screw 10 from rotating. The screw 10 then causes the adjusting frame 9 to slide downward, and the adjusting frame 9 then causes the adjusting block 8 to slide outward through the adjusting groove 16, thus preventing the adjusting block 8 from rotating. The adjusting block 8 causes the mating groove 32 to slide outward along the mating block 33, and also causes multiple adjusting holes 31 to move outward. The movement of the adjusting holes 31, combined with the outward sliding of the adjusting block 8, changes the actual flow area inside the conveying pipe 3, thereby adjusting the cooling water conveying speed. When the cooling water conveying speed is adjusted appropriately, the adjusting sleeve 4 is stopped from rotating, and the limiting frame 12 drives the limiting rod 13 and other components to rotate to the position corresponding to the limiting groove 11. Then, the limiting spring 14 resets and pulls the limiting plate 15, causing the limiting plate 15 to drive the limiting rod 13 to slide inward. The movement causes one end of the limiting rod 13 to be inserted into the corresponding limiting groove 11. Then, the limiting sleeve 6 is rotated in the opposite direction. The limiting sleeve 6 moves and resets along the thread on the outer wall of the connecting pipe 5, so that the inner wall of the limiting sleeve 6 re-limits the outer wall of the limiting plate 15, preventing the limiting plate 15 and the limiting rod 13 from sliding outward. Then, the limiting rod 13 and the limiting groove 11 cooperate to lock the limiting frame 12, so that the limiting frame 12 and the adjusting sleeve 4 will not rotate accidentally, thereby ensuring the structural stability after the conveying flow rate is adjusted, ensuring the stable delivery of cooling water, and thus ensuring the stable operation of the cooling work.
[0042] Of all the solutions mentioned above, those involving the connection between two components can be selected according to the actual situation, such as welding, bolt and nut connection, bolt or screw connection, or other known connection methods, which will not be elaborated here. For all the fixed connections mentioned above, welding is preferred. Although embodiments of this utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and variations can be made to these embodiments without departing from the principles and spirit of this utility model. The scope of this utility model is defined by the appended claims and their equivalents.
Claims
1. A storage device for electrode paste production, comprising a storage tank (1), characterized in that: A conveying pump (2) is provided on one side of the storage tank (1). The output end of the conveying pump (2) is provided with a conveying pipe (3). An adjusting sleeve (4) and a connecting pipe (5) are provided on one side of the conveying pipe (3). A limiting sleeve (6) is provided on the outside of the connecting pipe (5). The inner wall of the limiting sleeve (6) is movably connected to the outer wall of the connecting pipe (5) by a thread. A screw sleeve (7) is fixedly provided on the inner wall of the adjusting sleeve (4). Multiple adjusting blocks (8) are movably provided in the conveying pipe (3). An adjusting frame (9) is movably provided in the conveying pipe (3). A screw rod (10) is fixedly connected to one end of the adjusting frame (9). The screw rod (10) is connected to the screw sleeve (7) by a thread. The connecting pipe (5) has multiple limiting grooves (11) on its outer side. The adjusting sleeve (4) has a limiting frame (12) on one side. A limiting rod (13) is slidably provided in the limiting frame (12). A limiting spring (14) is movably sleeved on the outer side of the limiting rod (13). A limiting plate (15) is fixedly provided at one end of the limiting rod (13). The limiting spring (14) is connected to the limiting plate (15) and the limiting frame (12). The adjusting frame (9) has a conical structure design. An adjusting groove (16) is inclinedly provided in the adjusting block (8). The adjusting frame (9) is slidably connected to the adjusting block (8) through the adjusting groove (16).
2. The storage device for electrode paste production according to claim 1, characterized in that: The storage tank (1) is provided with a detachable inner cylinder (17) on the inside. A flow cavity (18) is provided between the storage tank (1) and the inner cylinder (17). A guide plate (19) is spirally installed in the flow cavity (18).
3. The storage device for electrode paste production according to claim 2, characterized in that: The output end of the connecting pipe (5) is connected to the input end of the flow chamber (18), the output end of the flow chamber (18) is connected to an output pipe (20), and the input end of the delivery pump (2) is connected to an input pipe (21).
4. The storage device for electrode paste production according to claim 3, characterized in that: A pneumatic component (22) is detachably provided on one side of the storage tank (1). A movable frame (23) is rotatably provided on one side of the storage tank (1). A tank cover (24) is detachably provided on one side of the movable frame (23). The two ends of the pneumatic component (22) are rotatably connected to the storage tank (1) and the movable frame (23) respectively. A motor (25) is detachably provided at the top of the tank cover (24). A stirring rack (26) is detachably connected to the output end of the motor (25).
5. The storage device for electrode paste production according to claim 4, characterized in that: The storage tank (1) is detachably provided with a bracket (27) at the bottom end, and a discharge valve (28) is connected to the bottom end of the storage tank (1). The top of the tank cover (24) is detachably provided with a feed pipe (29), and the top of the feed pipe (29) is detachably connected with a pipe cap (30) by a thread.
6. The storage device for producing an electrode paste according to any one of claims 1 to 5, characterized by: The adjusting block (8) has multiple adjusting holes (31).
7. The storage device for electrode paste production according to claim 6, characterized in that: The adjusting block (8) has a mating groove (32) on one side, and a mating block (33) is fixedly installed inside the conveying pipe (3). The adjusting block (8) is slidably connected to the mating block (33) through the mating groove (32).
8. The storage device for electrode paste production according to claim 1, characterized in that: The outer walls of the adjusting sleeve (4) and the limiting sleeve (6) are both fixedly connected with multiple anti-slip strips (34).