A nozzle device for cooling of metalized nickel anode plates
By designing a nozzle device with multiple rotating connections and a quick-release mechanism, the problems of low cooling efficiency and inconvenient maintenance of nickel anode plates were solved, achieving efficient and stable cooling and convenient maintenance, and extending the service life of the nozzle.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JINCHUAN GROUP NICKEL COBALT CO LTD
- Filing Date
- 2025-07-09
- Publication Date
- 2026-07-14
AI Technical Summary
Traditional nickel anode plate cooling nozzle devices have low cooling efficiency, cannot provide uniform cooling in all directions, are inconvenient to maintain, have a short service life, are difficult to adapt to dynamic changes, and increase operating costs.
A nozzle device including multiple rotating connection mechanisms and quick-release mechanisms was designed. The nozzle is stably connected and quickly disassembled through a telescopic cylinder and a rotating water spray mechanism, ensuring uniform cooling and convenient maintenance.
This improves the efficiency and stability of nickel anode plate cooling, reduces maintenance time, extends nozzle lifespan, and lowers equipment maintenance costs.
Smart Images

Figure CN224498922U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of nickel anode plate cooling technology, specifically to a nozzle device for cooling metallized nickel anode plates. Background Technology
[0002] In the metal processing industry, especially in the production of nickel anode plates, efficient and stable cooling processes play a decisive role in ensuring product quality and improving production efficiency. With the continuous expansion of industrial scale and increasingly stringent performance requirements for nickel anode plates, the cooling process is facing unprecedented challenges. Traditional cooling nozzle devices for metallized nickel anode plates have revealed numerous drawbacks in practical applications. Their cooling structures are mostly simple single-nozzle designs, which cannot achieve comprehensive and uniform cooling coverage of the nickel anode plate. In large-scale production, the cooling efficiency of a single nozzle is severely insufficient, resulting in lengthy cooling times and significantly limiting production efficiency. This makes it difficult to meet the ever-growing market demand and lacks the ability to adapt to dynamic changes during production. Furthermore, traditional nozzle devices often employ an integrated design, requiring extensive disassembly and repair of the entire device when components malfunction, which is time-consuming and labor-intensive, hindering rapid equipment maintenance and upgrades and impeding efficient production line operation. Simultaneously, traditional nozzles cannot operate stably for extended periods in the high-temperature and highly corrosive environment of nickel anode plate cooling, leading to short nozzle lifespans, frequent equipment replacements, and further increasing operating costs. Therefore, it is necessary to further optimize the cooling structure for nickel anode plate production. Utility Model Content
[0003] This invention provides a nozzle device for cooling a metallized nickel anode plate, in order to solve the problems mentioned above.
[0004] To achieve the above objectives, the present invention adopts the following technical solution:
[0005] A nozzle device for cooling a metallized nickel anode plate includes a connecting support head, a plurality of rotating connecting mechanisms fixedly disposed on the outer side of the connecting support head, a quick-release mechanism fixedly disposed on the bottom of the connecting support head, and a rotating water spray mechanism rotatably disposed on the inner side of the connecting support head. Each rotating connecting mechanism includes a first connecting support block, a rotating clamping assembly fixedly disposed on the outer side of the first connecting support block, and a first telescopic cylinder. The output end of the first telescopic cylinder is fixedly connected to a first connecting fixing block, and a first connecting rotating column is fixedly disposed on the outer side of the first connecting fixing block. The quick-release mechanism includes a second telescopic cylinder, the output end of which is fixedly connected to a connecting rotating block, and a second connecting fixing block fixedly disposed on the outer side of the second telescopic cylinder.
[0006] Furthermore, a first connecting rotating plate is rotatably provided on the outer front side of the second connecting fixing block, and a second connecting rotating plate is rotatably provided on the outer rear side of the connecting rotating block.
[0007] Furthermore, the end of the first connecting rotating plate away from the connecting rotating block is rotatably connected to the outside of the second connecting fixed block. The end of the second connecting rotating plate away from the connecting rotating block is rotatably provided with a connecting sliding post. A fixed connecting block is fixedly connected to the outside of the connecting sliding post. A connecting sliding ring is fixedly connected to the outside of the fixed connecting block. The connecting sliding ring is slidably connected to the outside of the connecting support head, and the second connecting fixed block is fixedly connected to the outside of the connecting support head.
[0008] Furthermore, a connecting sliding rod is rotatably provided on the outer side of the first connecting rotating column, and a second connecting rotating column is fixedly provided on the inner side of the connecting sliding rod. Rotating fixing blocks are fixedly provided at both ends of the second connecting rotating column, and a rotating connecting ring is fixedly provided at the bottom of the rotating fixing blocks.
[0009] Furthermore, a rotating connecting shaft is rotatably provided on the inner side of the rotating connecting ring, and a second connecting support block is fixedly provided on the outer side of the rotating connecting shaft, and the rotating connecting ring is fixedly connected to the outer side of the connecting support head.
[0010] Furthermore, the rotating water spraying mechanism includes a connecting nozzle, the top of which is fixedly connected to the inner side of the connecting support head, a connecting threaded block is threadedly connected to the outer side of the connecting nozzle, and a rotating fan is rotatably connected to the outer side of the connecting threaded block.
[0011] This utility model has the following beneficial effects:
[0012] The first telescopic cylinder of this utility model starts and drives the first connecting fixing block to move. The first connecting fixing block then drives the connecting sliding rod to move, providing stable support for the first connecting rotating column. The connecting sliding rod rotates outside the second connecting rotating column, which also provides reliable support for it. At the same time, the rotating fixing block starts to rotate. The rotating fixing block and the rotating connecting ring together form the rotation center axis, thereby ensuring the overall stability of the rotation. The rotating fixing block stably rotates and fixes the connecting support head, making it firmly connected to the equipment, thereby enhancing the overall stability of the nozzle device installation.
[0013] The second telescopic cylinder of this utility model starts and drives the connecting rotating block to move, thereby causing the first connecting rotating plate and the second connecting rotating plate to rotate synchronously. This ensures that the connecting sliding column slides smoothly inside the second connecting fixed block and drives the connecting sliding ring to move, realizing a quick fixed connection between the components. When the nozzle needs maintenance or replacement, it can be quickly reversed to achieve quick disassembly, greatly shortening maintenance time and improving work efficiency. At the same time, the stable connection structure effectively ensures the stability of the nozzle during operation. Attached Figure Description
[0014] Figure 1 This is a three-dimensional schematic diagram of the overall structure of this utility model.
[0015] Figure 2 This is a cross-sectional schematic diagram of the rotating fan structure of this utility model.
[0016] Figure 3 This is a schematic diagram of the overall structure of the rotating fixing block of this utility model.
[0017] Figure 4 In this utility model Figure 3 An enlarged schematic diagram of the structure at point A.
[0018] The meanings of the reference numerals in the attached figures are as follows:
[0019] 1. Connecting support head; 2. Rotating connecting mechanism; 201. First connecting support block; 202. First telescopic cylinder; 203. First connecting fixing block; 204. First connecting rotating column; 205. Connecting sliding rod; 206. Rotating connecting shaft; 207. Second connecting rotating column; 208. Rotating fixing block; 209. Second connecting support block; 2010. Rotating connecting ring; 3. Quick release mechanism; 301. Second telescopic cylinder; 302. Second connecting fixing block; 303. Connecting rotating block; 304. First connecting rotating plate; 305. Second connecting rotating plate; 306. Connecting sliding column; 307. Fixing connecting block; 308. Connecting sliding ring; 4. Rotating water spraying mechanism; 401. Connecting nozzle; 402. Connecting threaded block; 403. Rotating fan. Detailed Implementation
[0020] The present invention will be further described below with reference to the accompanying drawings and specific embodiments.
[0021] like Figure 1-4 As shown, a nozzle device for cooling a metallized nickel anode plate includes a connecting support head 1. Three rotating connecting mechanisms 2 are fixedly installed on the outer side of the connecting support head 1. A quick-release mechanism 3 is fixedly installed at the bottom of the connecting support head 1. A rotating water spraying mechanism 4 is rotatably installed on the inner side of the connecting support head 1. The rotating connecting mechanism 2 includes a first connecting support block 201. A rotating clamping assembly is fixedly installed on the outer side of the first connecting support block 201. The rotating clamping assembly includes a first telescopic cylinder 202. A first connecting fixing block 203 is fixedly connected to the output end of the first telescopic cylinder 202. A first connecting rotating column 204 is fixedly installed on the outer side of the first connecting fixing block 203. The quick-release mechanism 3 includes a second telescopic cylinder 301. A connecting rotating block 303 is fixedly connected to the output end of the second telescopic cylinder 301. A second connecting fixing block 302 is fixedly installed on the outer side of the second telescopic cylinder 301.
[0022] The first connecting rotating plate 304 is rotatably provided on the outer front side of the second connecting fixing block 302, and the second connecting rotating plate 305 is rotatably provided on the outer rear side of the connecting rotating block 303.
[0023] The first connecting rotating plate 304 is rotatably connected to the outside of the second connecting fixing block 302 at one end away from the connecting rotating block 303. The second connecting rotating plate 305 is rotatably provided with a connecting sliding post 306 at one end away from the connecting rotating block 303. A fixing connecting block 307 is fixedly connected to the outside of the connecting sliding post 306. A connecting sliding ring 308 is fixedly connected to the outside of the fixing connecting block 307. The connecting sliding ring 308 is slidably connected to the outside of the connecting support head 1, and the second connecting fixing block 302 is fixedly connected to the outside of the connecting support head 1.
[0024] A connecting sliding rod 205 is rotatably provided on the outer side of the first connecting rotating column 204, and a second connecting rotating column 207 is fixedly provided on the inner side of the connecting sliding rod 205. Rotating fixing blocks 208 are fixedly provided at both ends of the second connecting rotating column 207, and a rotating connecting ring 2010 is fixedly provided at the bottom of the rotating fixing block 208.
[0025] A rotating connecting shaft 206 is rotatably provided on the inner side of the rotating connecting ring 2010, and a second connecting support block 209 is fixedly provided on the outer side of the rotating connecting shaft 206. The rotating connecting ring 2010 is fixedly connected to the outer side of the connecting support head 1.
[0026] The rotating water spray mechanism 4 includes a connecting nozzle 401, the top of which is fixedly connected to the inner side of the connecting support head 1. A connecting threaded block 402 is threadedly connected to the outer side of the connecting nozzle 401, and a rotating fan 403 is rotatably connected to the outer side of the connecting threaded block 402. The rotating fan 403 rotates synchronously.
[0027] A quick-release mechanism 3 is fixedly connected to the bottom of the connecting support head 1. A rotating water spray mechanism 4 is rotatably connected inside the connecting support head 1. The rotating connecting mechanism 2 includes a first connecting support block 201, which provides a platform for mounting and supporting the rotating clamping assembly. A rotating clamping assembly for clamping and fixing is fixedly connected to the outside of the first connecting support block 201. The rotating clamping assembly for clamping and fixing includes a first telescopic cylinder 202. A first connecting fixing block 203 is fixedly connected to the output end of the first telescopic cylinder 202, controlling its telescopic movement and adjusting the position of the first connecting fixing block 203. A connecting rotating column 204 is fixedly connected to the outside of the first connecting fixing block 203, connecting the output end of the first telescopic cylinder 202 and supporting the first connecting rotating column 204, converting the linear motion of the first telescopic cylinder 202 into the rotational motion of the first connecting rotating column 204. The first connecting rotating column 204 and the second connecting rotating column 207 cooperate in... Under the same action, it can rotate and slide. The inner part of the connecting sliding rod 205 is fixedly connected to the second connecting rotating column 207, which provides stable support for the connecting sliding rod 205 and ensures the stability of the connecting sliding rod 205 during rotation. The bottom of the rotating fixed block 208 is fixedly connected to the rotating connecting ring 2010, which is connected to the rotating connecting ring 2010 and rotates under the drive of the connecting sliding rod 205 and other components. The inner part of the rotating connecting ring 2010 is rotatably connected to the rotating connecting shaft 206, which connects the rotating connecting ring 2010 and the second connecting support block 209, so that the second connecting support block 209 can rotate around the rotating connecting ring 2010, further enhancing the connection flexibility of the entire nozzle device. The outer part of the rotating connecting shaft 206 is fixedly connected to the second connecting support block 209, which assists the first connecting support block 201 and jointly supports and fixes the rotating clamping assembly, enhancing the stability of the entire rotating connection mechanism 2.
[0028] The second telescopic cylinder 301 quickly drives the connecting rotating block 303 to move, thereby realizing the rapid opening and closing of the quick-release mechanism 3, improving the efficiency of nozzle device disassembly and installation, and reducing the time required for equipment maintenance and component replacement. The end of the first connecting rotating plate 304 away from the connecting rotating block 303 is rotatably connected to the outside of the second connecting fixed block 302, playing a transmission and support role between the connecting rotating block 303 and the second connecting fixed block 302. The end of the second connecting rotating plate 305 away from the connecting rotating block 303 is rotatably connected to the connecting sliding column 306. Driven by the second telescopic cylinder 301, the first connecting rotating plate 304 and the second connecting rotating plate 305 are driven to rotate, thereby controlling the sliding of the connecting sliding column 306. The outside of the connecting sliding column 306 is fixedly connected to the fixed connecting block 307, which securely connects the connecting sliding column 306 and the connecting sliding ring 308, ensuring the connection of the connecting sliding column 306. The motion can be transmitted to the connecting sliding ring 308, enabling the connecting sliding ring 308 to slide stably on the outside of the connecting support head 1, realizing the operation of quickly fixing and disassembling the nozzle device; the connecting sliding ring 308 is fixedly connected to the outside of the fixed connecting block 307, and the connecting sliding ring 308 is slidably connected to the outside of the connecting support head 1. The second connecting fixing block 302 is fixedly connected to the outside of the connecting support head 1. The connecting nozzle 401 directly and evenly sprays the cooling medium onto the surface of the nickel anode plate. The top of the connecting nozzle 401 is fixedly connected to the inside of the connecting support head 1. The connecting threaded block 402 is threadedly connected to the outside of the connecting nozzle 401, and is tightly connected to the connecting nozzle 401 through the threaded connection. It not only serves to fix the connecting nozzle 401, but also provides a rotation support point for the rotating fan 403. The rotating fan 403 is rotatably connected to the outside of the connecting threaded block 402, and the rotating fan 403 rotates synchronously.
[0029] In practical use, when the first telescopic cylinder 202 starts running, it drives the first connecting fixing block 203 to move, thereby driving the connecting sliding rod 205 to move. Simultaneously, the first connecting fixing block 203 provides support for the first connecting rotating column 204, while the connecting sliding rod 205 rotates outside the second connecting rotating column 207, which in turn provides support for the connecting sliding rod 205. This drives the rotation of the rotating fixing block 208, and the rotating fixing block 208 and the rotating connecting ring 2010 provide a rotation center axis for the rotation of the rotating fixing block 208, thus achieving stability of the rotating fixing block 208 in fixing the connecting support head 1 on the connecting device. When the second telescopic cylinder 301 starts running, it drives the connecting rotating block 303 to move, thereby driving the first connecting rotating plate 304 and the second connecting rotating plate 305 to rotate. This causes the connecting sliding column 306 to slide inside the second connecting fixing block 302, thereby driving the connecting sliding ring 308 to move. Ultimately, this achieves a fixed connection and convenient assembly / disassembly. Therefore, this nozzle device has good practicality.
Claims
1. A nozzle device for cooling a metallized nickel anode plate, characterized in that: The device includes a connecting support head (1), a plurality of rotating connecting mechanisms (2) are fixedly provided on the outer side of the connecting support head (1), a quick-release mechanism (3) is fixedly provided at the bottom of the connecting support head (1), and a rotating water spray mechanism (4) is rotatably provided on the inner side of the connecting support head (1). The rotating connecting mechanism (2) includes a first connecting support block (201), a rotating clamping assembly is fixedly provided on the outer side of the first connecting support block (201), the rotating clamping assembly includes a first telescopic cylinder (202), a first connecting fixing block (203) is fixedly connected to the output end of the first telescopic cylinder (202), a first connecting rotating column (204) is fixedly provided on the outer side of the first connecting fixing block (203), and a second telescopic cylinder (301) includes a second telescopic cylinder (301), a connecting rotating block (303) is fixedly connected to the output end of the second telescopic cylinder (301), and a second connecting fixing block (302) is fixedly provided on the outer side of the second telescopic cylinder (301).
2. The nozzle device for cooling a metallized nickel anode plate according to claim 1, characterized in that: The second connecting fixing block (302) has a first connecting rotating plate (304) rotatably mounted on its outer front side, and the connecting rotating block (303) has a second connecting rotating plate (305) rotatably mounted on its outer rear side.
3. A nozzle device for cooling a metallized nickel anode plate according to claim 2, characterized in that: The first connecting rotating plate (304) is rotatably connected to the outside of the second connecting fixing block (302) at one end away from the connecting rotating block (303). The second connecting rotating plate (305) is rotatably provided with a connecting sliding column (306) at one end away from the connecting rotating block (303). A fixing connecting block (307) is fixedly connected to the outside of the connecting sliding column (306). A connecting sliding ring (308) is fixedly connected to the outside of the fixing connecting block (307). The connecting sliding ring (308) is slidably connected to the outside of the connecting support head (1). The second connecting fixing block (302) is fixedly connected to the outside of the connecting support head (1).
4. A nozzle device for cooling a metallized nickel anode plate according to claim 1, characterized in that: A connecting sliding rod (205) is rotatably provided on the outer side of the first connecting rotating column (204), and a second connecting rotating column (207) is fixedly provided on the inner side of the connecting sliding rod (205). Rotating fixing blocks (208) are fixedly provided at both ends of the second connecting rotating column (207), and a rotating connecting ring (2010) is fixedly provided at the bottom of the rotating fixing block (208).
5. A nozzle device for cooling a metallized nickel anode plate according to claim 4, characterized in that: The inner side of the rotating connecting ring (2010) is provided with a rotating connecting shaft (206), and the outer side of the rotating connecting shaft (206) is fixedly provided with a second connecting support block (209). The rotating connecting ring (2010) is fixedly connected to the outer side of the connecting support head (1).
6. A nozzle device for cooling a metallized nickel anode plate according to claim 1, characterized in that: The rotating water spraying mechanism (4) includes a connecting nozzle (401), the top of which is fixedly connected to the inner side of the connecting support head (1), and a connecting threaded block (402) is threadedly connected to the outer side of the connecting nozzle (401), and a rotating fan (403) is rotatably connected to the outer side of the connecting threaded block (402).