A continuous plating solution supply device for a silicon steel strip continuous production line
By designing a continuous plating solution supply device with lint removal, oil removal, degassing, and supply mechanisms, the problem of separating lint and oil stains in the plating solution is solved, ensuring coating quality and stable supply, and adapting to different weather conditions.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- 湖南宏旺新材料科技有限公司
- Filing Date
- 2023-07-25
- Publication Date
- 2026-06-09
AI Technical Summary
During the continuous supply of silicon steel strip plating solution, oil and lint are difficult to separate from the solution, and may drip or affect the quality of the coating after treatment, especially in low temperature weather. Existing technology cannot effectively solve this problem.
A continuous plating solution supply device was designed, which includes a lint removal, oil removal, degassing and supply mechanism. The device separates lint and oil through components such as a spiral shell and scraper, and ensures a stable supply of liquid through components such as a liquid delivery pipe and a nozzle scraper.
It effectively separates and treats lint and oil in the plating solution, prevents plating solution dripping and bubbling, ensures coating quality, and provides a stable supply to suit different weather conditions.
Smart Images

Figure CN116943921B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of silicon steel strip, and more specifically to a continuous plating solution supply device for a continuous silicon steel strip production line. Background Technology
[0002] Silicon steel strip is a soft magnetic alloy of silicon and iron with extremely low carbon content, typically containing 0.5% to 4.5% silicon. Adding silicon increases the resistivity and maximum permeability of iron, while reducing coercivity, core loss (iron loss), and magnetic aging. It is mainly used to manufacture the cores of various transformers, motors, and generators. To improve the appearance and oxidation resistance of the silicon steel strip coating, a plating solution is applied to its surface.
[0003] When continuously supplying plating solution to silicon steel strip, the plating solution contains oil and lint that are difficult to separate. During separation, the oil often sticks to the lint and is difficult to remove. Even after removing the oil and lint, air may still be present in the plating solution. In addition, the treated plating solution may drip and contaminate the parts. Especially in low-temperature weather, the plating solution contaminated on the parts is very easy to dry and solidify. Therefore, we propose a continuous plating solution supply device for a continuous silicon steel strip production line. Summary of the Invention
[0004] To solve the above-mentioned technical problems, the present invention provides a continuous plating solution supply device for a continuous silicon steel strip production line, including an electric motor. The output end of the electric motor is fixedly connected to a first receiving shaft. A transmission chain is sleeved on the outer surface of the first receiving shaft. Two transmission chains are provided. One transmission chain is sleeved on the outer surface of the first receiving shaft, and the two ends of the other transmission chain are respectively sleeved on a second receiving shaft and a third receiving shaft. A lint removal mechanism is fixedly connected to the end of the first receiving shaft away from the electric motor. An oil removal mechanism is fixedly connected to the bottom of the lint removal mechanism. A degassing mechanism is fixedly connected to the bottom of the oil removal mechanism. A supply mechanism is fixedly connected to the bottom of the degassing mechanism.
[0005] The lint removal mechanism includes a top outer shell, with a spiral shell rotatably connected to the inner wall of the top outer shell. The outer surface of the spiral shell has a circular slot. A triangular prism is fixedly connected to the inner wall of the spiral shell, and an inner tension spring is fixedly connected to the outer surface of the triangular prism. A spiral scraper is sleeved on and slidably connected to the outer surface of the inner tension spring. A double-headed disc is fixedly connected to the top of the inner tension spring. A lint-winding plate is rotatably connected to the inner wall of the double-headed disc via a rotating bolt. A rectangular pull plate is slidably connected to the inner wall of the top outer shell. A telescopic rod is fixedly connected to the end of the rectangular pull plate near the spiral shell, and a spiked plate is fixedly connected to the end of the telescopic rod away from the rectangular pull plate. A return spring is fixedly connected to the side of the spiked plate near the telescopic rod. A receiving curved plate is slidably connected to the inner wall of the top outer shell, and a [missing information - likely a device or component] is fixedly connected to the bottom of the receiving curved plate near the spiral shell. The telescopic plate consists of three rectangular pull plates evenly distributed on the spiral shell. The bottom of the spiral scraper is fixedly connected to the side of the triangular prism near the inner tension spring. The end of the return spring away from the barbed plate is fixedly connected to the inner wall of the spiral shell. The system collects lint on the surface of the spiral shell to prevent lint from being scattered throughout the plating solution and difficult to separate. The flow of the plating solution drives the lint-winding plate to rotate, entangles and accumulates lint on the surface of the double-headed disc for treatment, preventing excessive lint accumulation inside the plating solution from affecting the plating quality. The spiral scraper removes lint from the surface of the inner tension spring to prevent excessive lint accumulation inside the inner tension spring from causing blockage. The barbed plate cleans lint from the surface of the triangular prism and the double-headed disc to prevent incomplete lint removal from affecting the next use. Loosening the rectangular pull plates causes the return spring to reset, thereby driving the telescopic plate to open and close through the receiving curved plate, transporting the delinted plating solution to the degreasing mechanism.
[0006] Furthermore, the degreasing mechanism includes a middle outer shell, an inner hollow cylinder fixedly connected to the inner wall of the middle outer shell, a circular through hole on the outer surface of the inner hollow cylinder, a spiral column rotatably connected to the inner wall of the middle outer shell, a four-slot hollow shell sleeved and fixedly connected to the spiral column, inner hollow shells fixedly connected to all four sides of the four-slot hollow shell, a long scraper slidably connected to the inner wall of the inner hollow shell, a return spring fixedly connected to the side of the long scraper near the four-slot hollow shell, an oil outlet cylinder fixedly connected to the inner wall of the middle outer shell, and four inner hollow shells evenly distributed on the four-slot hollow shell. Eight springs are evenly distributed on the four-slot shell. The oil-absorbing mesh on the inner wall of the inner shell draws oil from the plating solution into the inner wall of the inner shell, preventing oil from affecting the plating quality during the plating process. At the same time, the inner shell sends the degreased plating solution out through the circular through-hole at the bottom, thus improving the degreasing efficiency. The long scraper scrapes the oil accumulated inside the inner shell into the four-slot shell, preventing the oil from accumulating in the inner shell for a long time, drying into clumps, and becoming difficult to remove. The spiral column spirally pushes the oil inside the four-slot shell into the oil outlet cylinder for discharge, preventing excessive oil accumulation in the four-slot shell that is difficult to remove and causes blockage.
[0007] Furthermore, the degassing mechanism includes a bottom outer shell, an inner spring fixedly connected to the inner wall of the bottom outer shell, an inner sliding plate fixedly connected to the end of the inner spring away from the bottom outer shell, a pull rod fixedly connected to the side of the inner sliding plate away from the inner spring, a double-layer clamping shell slidably connected to the outer surface of the inner sliding plate, a partition plate fixedly connected to the bottom of the double-layer clamping shell, a hollow cylinder fixedly connected to the inner wall of the partition plate, a discharge hole opened on the outer surface of the hollow cylinder, a spiral block movably connected to the inner wall of the discharge hole, a fixed circle rotatably connected to the end of the spiral block away from the discharge hole, an inner moving plate slidably connected to the inner wall of the hollow cylinder, and a fixed circle fixedly connected to one side of the inner moving plate. The inner wall of the inner moving plate is threaded with a long threaded shaft. Two inner moving plates are evenly distributed on the inner wall of the hollow cylinder. A partition plate divides the inner shell into a feeding area and a discharging area. The inner sliding plate slides inward to allow the plating solution to enter the feeding area. The receiving shaft drives the long spiral shaft to rotate, which causes the inner moving plate to move the plating solution to the discharging area. The arc-shaped baffle blocks the feeding port of the hollow cylinder to prevent the plating solution from seeping into the gap between the hollow cylinder and the inner moving plate, which would prevent the inner moving plate from moving. The plating solution is screened out from the discharging hole. With the cooperation of the rotating spiral block, the plating solution is separated and discharged, thereby removing the air inside the plating solution and preventing the formation of bubbles on the surface of the plating solution during plating.
[0008] Furthermore, the supply mechanism includes a sprayer, with an infusion tube extending through and fixedly connected to the bottom of the sprayer. The bottom of the infusion tube is connected to a leak-proof sleeve, and a tightening ring is fixedly connected to the bottom of the leak-proof sleeve. A push plate is slidably connected to the inner wall of the sprayer, and a scraper is fixedly connected to the side of the push plate closest to the sprayer. A processing table is slidably connected to the bottom of the scraper, and a heater is fixedly connected to the bottom of the processing table. A storage tank is fixedly connected to the side of the heater furthest from the scraper, and a water pump is fixedly connected to the inner wall of the storage tank. The outlet of the water pump is connected to a water pipe. The anti-drip sleeve has three sleeves evenly distributed on the sprayer. The plastic infusion tube allows the operator to adjust the infusion position close to the processing table, preventing the plating solution from splashing everywhere and causing uneven spraying that affects the plating quality. The tightening ring tightens inward to prevent plating solution remaining in the anti-drip sleeve from dripping onto the surface of the processing table. The scraper blade scrapes the plating solution off the processing table into the storage tank, preventing plating solution remaining on the processing table from affecting subsequent plating operations. The sharp corner at the bottom of the scraper blade prevents the plating solution remaining in the gap between the scraper blade and the processing table from drying and sticking to the scraper blade and processing table. The plating solution is pumped to the de-flocculation mechanism for recycling.
[0009] The beneficial effects of this invention are as follows:
[0010] 1. This invention uses a rotating filament-winding plate to wrap and accumulate lint on the surface of the double-headed disc, preventing excessive lint accumulation inside the plating solution from affecting the plating quality. A long scraper scrapes away oil accumulated inside the inner shell into the four-slot shell, preventing the oil from drying and becoming difficult to remove due to long-term accumulation inside the inner shell. Air is removed from the plating solution through the discharge hole and the rotation of the spiral block, preventing bubbles from appearing on the surface of the plating solution during plating. The tightening ring tightens inward to prevent plating solution remaining in the anti-drip sleeve from dripping onto the processing table surface.
[0011] 2. This invention, by setting up a lint removal mechanism, collects lint on the surface of the spiral shell, preventing lint from being dispersed throughout the plating solution and difficult to separate. The flow of the plating solution drives the lint-removing plate to rotate, entangles and accumulates lint on the surface of the double-headed disc for processing, preventing excessive lint accumulation inside the plating solution from affecting the plating quality. After the rotation stops, when the inner pull spring is pulled back, its outer surface contacts the spiral scraper. The spiral scraper removes lint from the surface of the inner pull spring, preventing excessive lint accumulation inside the inner pull spring from causing blockage. Pulling the rectangular pull plate causes the telescopic rod to drive the spike plate to clean the lint from the triangular prism and the surface of the double-headed disc, preventing incomplete lint removal from affecting the next use.
[0012] 3. This invention incorporates an oil removal mechanism. An oil-absorbing screen draws oil from the plating solution into the inner wall of the inner shell and, under centrifugal force, throws it to the top of the inner shell, preventing oil from affecting the plating quality during the plating process. The inner shell then discharges the degreased plating solution through a circular through-hole at the bottom, thus improving the oil removal efficiency. A long scraper scrapes away the oil accumulated inside the inner shell into the four-slot shell, preventing the oil from drying and becoming difficult to remove due to prolonged accumulation. A spiral column propels the oil inside the four-slot shell into the oil outlet cylinder for discharge, preventing excessive oil accumulation and blockage.
[0013] 4. This invention, by setting up a degassing mechanism, divides the bottom outer shell into a feeding area and a discharging area by a partition plate. The inner spring contracts inward, allowing the plating solution, after removing oil stains, to enter the feeding area. The plating solution enters the area between two inner moving discs in the hollow cylinder from the feeding area. The inner moving discs drive the plating solution to move towards the discharging area. An arc-shaped baffle blocks the feeding port of the hollow cylinder, preventing the plating solution from seeping into the interlayer between the hollow cylinder and the inner moving discs, thus preventing the inner moving discs from moving. The plating solution is screened out from the discharging hole. With the cooperation of the rotating spiral block, the plating solution is separated and discharged, thereby removing air from the inside of the plating solution and preventing the appearance of bubbles on the surface of the plating solution during plating.
[0014] 5. This invention features a supply mechanism where a plastic infusion tube allows workers to easily adjust the infusion position close to the processing table, preventing the plating solution from splashing and unevenly spraying, thus affecting the plating quality. A tightening ring inwards prevents plating solution remaining in the anti-leak sleeve from dripping onto the processing table surface. A scraper blade scrapes plating solution from the processing table into a storage tank, preventing plating solution from remaining on the processing table and affecting subsequent plating operations. The sharp corner at the bottom of the scraper blade prevents plating solution remaining in the gap between the scraper blade and the processing table from drying and causing the scraper blade to stick to the processing table. A heater heats the processing table, preventing the plating solution from drying too quickly in extremely cold weather, thus preventing it from affecting the plating operation. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the continuous plating solution supply device of the present invention;
[0016] Figure 2 This is a schematic diagram of the internal structure of the continuous plating solution supply device of the present invention;
[0017] Figure 3 This is a schematic diagram of the internal structure of the continuous plating solution supply device of the present invention;
[0018] Figure 4 This is a schematic diagram of the internal structure of the lint removal mechanism of the present invention;
[0019] Figure 5 This is an enlarged structural diagram of point A in the present invention;
[0020] Figure 6 This is a schematic diagram of the internal structure of the oil removal mechanism of the present invention;
[0021] Figure 7 This is a schematic diagram of the internal structure of the degassing mechanism of the present invention;
[0022] Figure 8 This is a schematic diagram of the internal structure of the supply mechanism of the present invention;
[0023] Figure 9 This is a schematic diagram of the internal structure of the supply mechanism of the present invention;
[0024] In the diagram: 1. Electric motor; 2. First receiving shaft; 21. Second receiving shaft; 22. Third receiving shaft; 3. Transmission chain; 4. Floss removal mechanism; 5. Oil removal mechanism; 6. Degassing mechanism; 7. Supply mechanism; 401. Top shell; 402. Spiral shell; 403. Circular slot; 404. Triangular prism; 405. Internal tension spring; 406. Spiral scraper; 407. Double-headed disc; 408. Floss winding plate; 409. Rectangular pull plate; 410. Telescopic rod; 411. Spike plate; 412. Return spring; 413. Receiving curved plate; 414. Telescopic plate; 501. Middle shell; 502. Hollow cylinder; 503. Circular through hole; 504. Spiral prism; 505. Four-slot hollow shell; 506. 507. Return spring; 508. Long scraper; 509. Inner hollow shell; 5000. Oil suction screen; 510. Oil outlet cylinder; 601. Bottom outer shell; 602. Inner retraction spring; 603. Inner sliding plate; 604. Pull rod; 605. Double-layer clamping shell; 606. Divider plate; 607. Hollow cylinder; 608. Discharge hole; 609. Spiral block; 610. Fixing circle; 611. Inner moving plate; 612. Arc-shaped baffle; 613. Threaded long shaft; 701. Injector; 702. Infusion pipe; 703. Leak-proof sleeve; 704. Tightening ring; 705. Push slide plate; 706. Scraper blade; 707. Processing table; 708. Heater; 709. Liquid storage tank; 710. Water pump; 711. Water pipe. Detailed Implementation
[0025] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments. The embodiments of the present invention are given for illustrative and descriptive purposes only, and are not intended to be exhaustive or to limit the invention to the forms disclosed. Many modifications and variations will be apparent to those skilled in the art. The embodiments were chosen and described to better illustrate the principles and practical application of the invention, and to enable those skilled in the art to understand the invention and design various embodiments with various modifications suitable for a particular purpose.
[0026] Please see Figures 1-9 The present invention is a continuous plating solution supply device for a continuous silicon steel strip production line, comprising a motor 1, a first receiving shaft 2 fixedly connected to the output end of the motor 1, a transmission chain 3 sleeved on the outer surface of the first receiving shaft 2, two transmission chains 3 being provided, one of which is sleeved on the outer surface of the first receiving shaft 2, and the other two ends of which are respectively sleeved on a second receiving shaft 21 and a third receiving shaft 22, a lint removal mechanism 4 fixedly connected to the end of the first receiving shaft 2 away from the motor 1, an oil removal mechanism 5 fixedly connected to the bottom of the lint removal mechanism 4, a degassing mechanism 6 fixedly connected to the bottom of the oil removal mechanism 5, and a supply mechanism 7 fixedly connected to the bottom of the degassing mechanism 6;
[0027] The lint removal mechanism 4 includes a top outer shell 401, a spiral shell 402 rotatably connected to the inner wall of the top outer shell 401, a circular slot 403 formed on the outer surface of the spiral shell 402, a triangular prism 404 fixedly connected to the inner wall of the spiral shell 402, an inner tension spring 405 fixedly connected to the outer surface of the triangular prism 404, a spiral scraper 406 sleeved and slidably connected to the outer surface of the inner tension spring 405, and a double-headed disc 407 fixedly connected to the top of the inner tension spring 405. The inner wall of the double-headed disc 407 is open to... A rotatable winding plate 408 is rotatably connected via a rotating bolt. A rectangular pull plate 409 is slidably connected to the inner wall of the top shell 401. A telescopic rod 410 is fixedly connected to one end of the rectangular pull plate 409 near the spiral shell 402. A barbed plate 411 is fixedly connected to the other end of the telescopic rod 410 away from the rectangular pull plate 409. A return spring 412 is fixedly connected to the side of the barbed plate 411 near the telescopic rod 410. A receiving curved plate 413 is slidably connected to the inner wall of the top shell 401. The receiving curved plate 413 is located near the spiral shell 402. A telescopic plate 414 is fixedly connected to one bottom side of the spiral shell 402. Three rectangular pull plates 409 are evenly distributed on the spiral shell 402. The bottom of the spiral scraper 406 is fixedly connected to the side of the triangular prism 404 near the inner tension spring 405. The end of the return spring 412 away from the spike plate 411 is fixedly connected to the inner wall of the spiral shell 402. When the motor 1 is turned on, the first receiving shaft 2 is rotated, thereby rotating the spiral shell 402. The spiral shell 402 drives the triangular prism 404. The rotation causes the inner tension spring 405 to stretch outward under centrifugal force, thereby causing the double-headed disc 407 to extend outward into the circular slot 403. The flow of plating solution drives the swirling plate 408 to rotate. After the rotation stops, when the inner tension spring 405 pulls back, its outer surface contacts the spiral scraper 406, pulling the rectangular pull plate 409, which causes the telescopic rod 410 to move the barbed plate 411. Loosening the rectangular pull plate 409 causes the reset spring 412 to reset, thereby driving the telescopic plate 414 to open and close through the receiving curved plate 413.
[0028] The oil removal mechanism 5 includes a middle outer shell 501. An inner hollow cylinder 502 is fixedly connected to the inner wall of the middle outer shell 501. A circular through hole 503 is opened on the outer surface of the inner hollow cylinder 502. A spiral column 504 is rotatably connected to the inner wall of the middle outer shell 501. A four-slot hollow shell 505 is sleeved and fixedly connected to the spiral column 504. Inner hollow shells 508 are fixedly connected to all four sides of the four-slot hollow shell 505. A long scraper 507 is slidably connected to the inner wall of the inner hollow shell 508. A return spring 506 is fixedly connected to the side of the long scraper 507 near the four-slot hollow shell 505. An oil outlet cylinder 510 is fixedly connected to the inner wall of the middle outer shell 501. Four oil outlet cylinders 510 are provided in the inner hollow shell 508. Eight return springs 506 are evenly distributed on the four-slot hollow shell 505. The plating solution enters the inner hollow cylinder 502 through the circular through hole 503 for degreasing. The second receiving shaft 21 drives the four-slot hollow shell 505 to rotate, so that the inner hollow shell 508 rotates and stirs the plating solution. The oil suction net 509 sucks the oil in the plating solution into the inner wall of the inner hollow shell 508. The return springs 506 tighten inward, driving the long scraper 507 to scrape the oil accumulated inside the inner hollow shell 508 into the four-slot hollow shell 505. When it rotates again, the spiral column 504 spirally pushes the oil inside the four-slot hollow shell 505 into the oil outlet cylinder 510 for discharge.
[0029] The degassing mechanism 6 includes a bottom outer shell 601. An inner spring 602 is fixedly connected to the inner wall of the bottom outer shell 601. An inner sliding plate 603 is fixedly connected to the end of the inner spring 602 away from the bottom outer shell 601. A pull rod 604 is fixedly connected to the side of the inner sliding plate 603 away from the inner spring 602. A double-layer clamping shell 605 is slidably connected to the outer surface of the inner sliding plate 603. A partition plate 606 is fixedly connected to the bottom of the double-layer clamping shell 605. A hollow cylinder 607 is fixedly connected to the inner wall of the partition plate 606. A discharge hole 608 is opened on the outer surface of the hollow cylinder 607. A spiral block 609 is movably connected to the inner wall of the discharge hole 608. A fixed circle 610 is rotatably connected to the end of the spiral block 609 away from the discharge hole 608. The inner wall of the hollow cylinder 607 is slidably connected to... An inner transfer plate 611 is connected to the hollow cylinder 607. An arc-shaped baffle 612 is fixedly connected to one side of the inner transfer plate 611. A threaded long shaft 613 is threadedly connected to the inner wall of the inner transfer plate 611. Two inner transfer plates 611 are provided and evenly distributed on the inner wall of the hollow cylinder 607. A partition plate 606 divides the bottom outer shell 601 into a feeding area and a discharging area. Pushing the pull rod 604 inward causes the inner slide plate 603 to slide inward, so that the plating solution for removing oil stains enters the feeding area. The plating solution enters the hollow cylinder 607 from the feeding area. The third receiving shaft 22 drives the spiral long shaft to rotate, so that the inner transfer plate 611 moves the plating solution to the discharging area. The plating solution is screened out from the discharge hole 608. With the cooperation of the rotating spiral block 609, the plating solution is separated and discharged, thereby removing the air inside the plating solution.
[0030] The supply mechanism 7 includes a sprayer 701, with an infusion tube 702 connected through and fixedly connected to the bottom of the sprayer 701. A leak-proof sleeve 703 is connected to the bottom of the infusion tube 702, and a tightening ring 704 is fixedly connected to the bottom of the leak-proof sleeve 703. A push plate 705 is slidably connected to the inner wall of the sprayer 701. A scraper 706 is fixedly connected to the side of the push plate 705 closest to the sprayer 701. A processing table 707 is slidably connected to the bottom of the scraper 706. A heater 708 is fixedly connected to the bottom of the processing table 707. A liquid storage tank 709 is fixedly connected to the side of the heater 708 furthest from the scraper 706. A water pump 710 is fixedly connected to the inner wall of the liquid storage tank 709. The water pump 710 outputs water... A water pipe 711 is connected to the nozzle. Three anti-drip sleeves 703 are evenly distributed on the sprayer 701. The plating solution falls into the sprayer 701 for continuous spraying. The plastic infusion tube 702 makes it easy for the operator to adjust the infusion position close to the processing table 707. At the same time, the plating solution passes through the tightening ring 704 of the anti-drip sleeve 703 for spraying. When spraying stops, the tightening ring 704 tightens inward, pushing the sliding plate 705 to drive the scraper 706 to scrape the plating solution off the processing table 707 into the storage tank 709. The heater 708 at the bottom of the processing table 707 heats the processing table 707. The water pump 710 is started to pump the plating solution inside the storage tank 709 through the water pipe 711 to the de-flocculation mechanism 4.
[0031] When operating this invention, the motor 1 is turned on, which drives the first receiving shaft 2 to rotate, thereby driving the spiral shell 402 to rotate. The spiral shell 402 drives the triangular prism 404 to rotate, causing the inner tension spring 405 to stretch outward under centrifugal force, thereby causing the double-headed disc 407 to extend outward into the circular slot 403. The plating solution flows, causing the swirling plate 408 to rotate. After the rotation stops, when the inner tension spring 405 is pulled back, its outer surface contacts the spiral scraper 406, pulling the rectangular pull plate 409, causing the telescopic rod 410 to drive the barbed plate 411 to move horizontally. Loosening the rectangular pull plate 409 causes the reset spring 412 to reset, thereby driving the telescopic plate 414 to open and close through the receiving curved plate 413.
[0032] The plating solution enters the inner hollow cylinder 502 through the circular through hole 503 for degreasing. The second receiving shaft 21 drives the four-slot hollow shell 505 to rotate, so that the inner hollow shell 508 rotates and stirs the plating solution. The oil suction net 509 sucks the oil in the plating solution into the inner wall of the inner hollow shell 508. The return spring 506 returns inward and drives the long scraper 507 to scrape the oil accumulated inside the inner hollow shell 508 into the four-slot hollow shell 505. When it rotates again, the spiral column 504 spirally pushes the oil inside the four-slot hollow shell 505 into the oil outlet cylinder 510 for discharge.
[0033] The partition plate 606 divides the bottom shell 601 into a feeding area and a discharging area. Pushing the pull rod 604 inward causes the inner slide plate 603 to slide inward, allowing the plating solution to enter the feeding area. The plating solution enters the hollow cylinder 607 from the feeding area. The third receiving shaft 22 drives the spiral shaft to rotate, which causes the inner moving plate 611 to move the plating solution to the discharging area. The plating solution is screened out from the discharge hole 608. With the cooperation of the rotating spiral block 609, the plating solution is separated and discharged, thereby removing the air inside the plating solution.
[0034] The plating solution falls into the sprayer 701 for continuous spraying. The plastic infusion tube 702 makes it easy for the operator to adjust the infusion position close to the processing table 707. At the same time, the plating solution passes through the tightening ring 704 of the anti-leakage sleeve 703 for spraying. When spraying stops, the tightening ring 704 tightens inward, pushing the push plate 705 to drive the scraper 706 to scrape the plating solution off the processing table 707 into the storage tank 709. The heater 708 at the bottom of the processing table 707 heats the processing table 707. The water pump 710 is started to pump the plating solution inside the storage tank 709 to the de-flocculation mechanism 4 through the water pipe 711.
[0035] Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all of them. All other embodiments obtained by those skilled in the art and related fields based on the embodiments of the present invention without inventive effort should fall within the scope of protection of the present invention. Structures, devices, and operating methods not specifically described and explained in the present invention, unless otherwise specified or limited, shall be implemented according to conventional means in the art.
Claims
1. A continuous plating solution supply device for a silicon steel strip continuous production line, comprising an electric motor (1), characterized in that: The output end of the motor (1) is fixedly connected to a first receiving shaft (2). A transmission chain (3) is sleeved on the outer surface of the first receiving shaft (2). There are two transmission chains (3). One transmission chain (3) is sleeved on the outer surface of the first receiving shaft (2). The two ends of the other transmission chain (3) are respectively sleeved on a second receiving shaft (21) and a third receiving shaft (22). The end of the first receiving shaft (2) away from the motor (1) is fixedly connected to a lint removal mechanism (4). The bottom of the lint removal mechanism (4) is fixedly connected to an oil removal mechanism (5). The bottom of the oil removal mechanism (5) is fixedly connected to a degassing mechanism (6). The bottom of the degassing mechanism (6) is fixedly connected to a supply mechanism (7). The lint removal mechanism (4) includes a top outer shell (401), a spiral shell (402) rotatably connected to the inner wall of the top outer shell (401), a circular slot (403) on the outer surface of the spiral shell (402), a triangular prism (404) fixedly connected to the inner wall of the spiral shell (402), an inner tension spring (405) fixedly connected to the outer surface of the triangular prism (404), a spiral scraper (406) sleeved and slidably connected to the outer surface of the inner tension spring (405), a double-headed disc (407) fixedly connected to the top of the inner tension spring (405), and a lint-winding plate rotatably connected to the inner wall of the double-headed disc (407) via a rotating bolt. (408) A rectangular pull plate (409) is slidably connected to the inner wall of the top shell (401). A telescopic rod (410) is fixedly connected to one end of the rectangular pull plate (409) near the spiral shell (402). A spike plate (411) is fixedly connected to one end of the telescopic rod (410) away from the rectangular pull plate (409). A return spring (412) is fixedly connected to one side of the spike plate (411) near the telescopic rod (410). A receiving curved plate (413) is slidably connected to the inner wall of the top shell (401). A telescopic plate (414) is fixedly connected to the bottom of the receiving curved plate (413) near the spiral shell (402).
2. The continuous plating solution supply device for a continuous silicon steel strip production line according to claim 1, characterized in that: Three rectangular pull plates (409) are provided and evenly distributed on the spiral shell (402).
3. The continuous plating solution supply device for a continuous silicon steel strip production line according to claim 1, characterized in that: The bottom of the spiral scraper (406) is fixedly connected to the side of the triangular prism (404) near the inner tension spring (405), and the end of the return spring (412) away from the spike plate (411) is fixedly connected to the inner wall of the spiral shell (402).
4. The continuous plating solution supply device for a continuous silicon steel strip production line according to claim 1, characterized in that: The oil removal mechanism (5) includes a middle outer shell (501), an inner hollow cylinder (502) is fixedly connected to the inner wall of the middle outer shell (501), a circular through hole (503) is opened on the outer surface of the inner hollow cylinder (502), a spiral column (504) is rotatably connected to the inner wall of the middle outer shell (501), a four-slot hollow shell (505) is sleeved and fixedly connected to the spiral column (504), an inner hollow shell (508) is fixedly connected to the four slot hollow shell (505) on all four sides, a long scraper (507) is slidably connected to the inner wall of the inner hollow shell (508), a return spring (506) is fixedly connected to the side of the long scraper (507) near the four slot hollow shell (505), and an oil outlet cylinder (510) is fixedly connected to the inner wall of the middle outer shell (501).
5. A continuous plating solution supply device for a continuous silicon steel strip production line according to claim 4, characterized in that: The inner shell (508) is provided in four parts and is evenly distributed on the four-slot shell (505).
6. A continuous plating solution supply device for a continuous silicon steel strip production line according to claim 4, characterized in that: The return springs (506) are provided in eight parts and are evenly distributed on the four-slot hollow shell (505).
7. A continuous plating solution supply device for a continuous silicon steel strip production line according to claim 1, characterized in that: The degassing mechanism (6) includes a bottom outer shell (601), an inner spring (602) fixedly connected to the inner wall of the bottom outer shell (601), an inner sliding plate (603) fixedly connected to the end of the inner spring (602) away from the bottom outer shell (601), a pull rod (604) fixedly connected to the side of the inner sliding plate (603) away from the inner spring (602), a double-layer clamping shell (605) slidably connected to the outer surface of the inner sliding plate (603), and a partition plate (606) fixedly connected to the bottom of the double-layer clamping shell (605). A hollow cylinder (607) is fixedly connected to the inner wall of the hollow cylinder (607). A discharge hole (608) is opened on the outer surface of the hollow cylinder (607). A spiral block (609) is movably connected to the inner wall of the discharge hole (608). A fixed circle (610) is rotatably connected to one end of the spiral block (609) away from the discharge hole (608). An inner moving plate (611) is slidably connected to the inner wall of the hollow cylinder (607). An arc-shaped baffle (612) is fixedly connected to one side of the inner moving plate (611). A threaded long shaft (613) is threadedly connected to the inner wall of the inner moving plate (611).
8. A continuous plating solution supply device for a continuous silicon steel strip production line according to claim 7, characterized in that: Two inner moving disks (611) are provided and are evenly distributed on the inner wall of the hollow cylinder (607).
9. A continuous plating solution supply device for a continuous silicon steel strip production line according to claim 1, characterized in that: The supply mechanism (7) includes a spray nozzle (701), with an infusion tube (702) connected through and fixedly connected to the bottom of the spray nozzle (701). The bottom of the infusion tube (702) is connected to a leak-proof sleeve (703), and a tightening ring (704) is fixedly connected to the bottom of the leak-proof sleeve (703). A push plate (705) is slidably connected to the inner wall of the spray nozzle (701), and the side of the push plate (705) near the spray nozzle (701) is... A scraper blade (706) is fixedly connected, and a processing table (707) is slidably connected to the bottom of the scraper blade (706). A heater (708) is fixedly connected to the bottom of the processing table (707). A liquid storage tank (709) is fixedly connected to the side of the heater (708) away from the scraper blade (706). A water pump (710) is fixedly connected to the inner wall of the liquid storage tank (709). A water pipe (711) is connected to the outlet of the water pump (710).
10. A continuous plating solution supply device for a continuous silicon steel strip production line according to claim 9, characterized in that: The anti-drip sleeve (703) is provided in three parts and is evenly distributed on the sprayer (701).