A plating bath for memory wire
By designing the guiding components and winding mechanism in the memory steel wire electroplating tank, the problem of repeated accumulation of steel wires during the rotation of the winding roller was solved, achieving uniform winding and improved neatness of the steel wires, thus improving electroplating efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENHANG TITANIUM TECH (SHENZHEN) CO LTD
- Filing Date
- 2025-04-15
- Publication Date
- 2026-06-05
AI Technical Summary
In the existing technology, the winding roller of the memory steel wire electroplating tank fails to move horizontally when rotating, causing the steel wire to repeatedly accumulate in the same position, resulting in uneven tension and reduced uniformity.
Design a memory steel wire electroplating tank that ensures uniform winding of steel wire and avoids repeated accumulation by moving horizontally while the winding roller rotates, using a guiding component, winding mechanism and drying component.
It achieves uniform winding of steel wire, avoids uneven tension and reduced uniformity, and improves electroplating efficiency and winding uniformity.
Smart Images

Figure CN224325433U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to an electroplating tank, specifically an electroplating tank for memory steel wire, belonging to the AAA technical field. Background Technology
[0002] Memory steel wire has shape memory effect and super elasticity, and can be used in a variety of precision control fields. Electroplating tanks are used to form a coating on the surface of memory steel wire to improve its corrosion resistance and conductivity, combined with the characteristics of memory steel wire.
[0003] Chinese Patent Publication CN217709713U discloses an electroplating galvanizing steel wire trough. Multiple steel wires are simultaneously fed into the electroplating tank via multiple feed rollers. The wires are then wound onto a take-up roller by a conveyor roller. Tension rollers tension the wires and lay them taut in the electroplating tank. The electroplating solution in the tank allows for simultaneous galvanizing of multiple wires, improving work efficiency. After galvanizing, the wires pass through a drying cylinder where hot air is evenly sprayed out through the vents, ensuring a more comprehensive drying process on the wire surface.
[0004] The aforementioned patented technology involves winding steel wire onto a winding roller. However, in practical applications, it has been found that the winding roller in this patented technology winds the steel wire by rotating rather than moving horizontally. This causes the steel wire to be repeatedly wound into the same position. Because the steel wire is always overlapping in the same position, it easily forms uneven piles, resulting in uneven winding tension and affecting the overall neatness. Therefore, a memory steel wire electroplating tank is proposed here. Utility Model Content
[0005] This invention proposes a memory steel wire electroplating tank, which enables the winding roller to move horizontally while rotating, so that the steel wire is wound evenly and avoids uneven tension and reduced uniformity caused by repeated accumulation.
[0006] This utility model is achieved through the following technical solution: an electroplating tank for memory steel wire, including an electrolytic tank, wherein a guiding component is provided on the electrolytic tank, the guiding component includes a first guiding roller and a second guiding roller, the height of the first guiding roller is higher than that of the second guiding roller, and the guiding component also includes a feed port and a discharge port opened at both ends of the electrolytic tank.
[0007] The guiding component is equipped with a drying component, which includes a heating cylinder and a fixing rod. The fixing rod is fixed inside the discharge port. The heating cylinder and the fixing rod are fixed together. The heating cylinder has an installation cavity inside, and a heating wire is installed inside the installation cavity.
[0008] The electrolytic cell is provided with a winding mechanism, which includes a fixing plate fixed to the electrolytic cell. A motor is mounted on the fixing plate via a motor mount, and a winding shaft is fixed to the output end of the motor.
[0009] A winding roller assembly is mounted on the winding shaft. The winding roller assembly includes a mounting plate, which is fixed to the top surface of the electrolytic cell. The mounting plate is rotatably connected to the winding shaft. The winding roller assembly also includes a stop block and a winding drum.
[0010] The stop block is fixed on the take-up shaft, the take-up cylinder is slidably sleeved on the take-up shaft, the right end of the take-up shaft is threaded, and the take-up roller assembly also includes a fixing bolt for threaded connection with the right end of the take-up shaft.
[0011] The winding mechanism further includes a reciprocating screw mechanism, which includes a vertical plate fixed to the top surface of the electrolytic cell. A reciprocating screw is rotatably connected to the vertical plate, and a slider is mounted on the reciprocating screw. A guide post is fixed to the top surface of the slider.
[0012] The bottom surface of the slider is fixed with a guide block, and the reciprocating screw mechanism also includes a guide rod fixed on the vertical plate. The guide block and the guide rod are slidably connected.
[0013] The take-up shaft is also provided with a transmission assembly for driving the reciprocating screw mechanism. The transmission assembly includes a driving wheel and a driven wheel. The driving wheel is fixed on the take-up shaft, and a belt is installed between the driving wheel and the driven wheel. A guide column is fixed on the reciprocating screw mechanism.
[0014] This utility model provides a memory steel wire electroplating tank, which has the following beneficial effects:
[0015] 1. The motor used for the electroplating tank of memory steel wire can drive the winding drum to rotate through the winding shaft. At the same time, the winding shaft will also drive the drive wheel, driven wheel and reciprocating screw to rotate. The rotation of the reciprocating screw causes the slider to drive the guide column to move back and forth. The reciprocating movement of the guide column will cause the steel wire to move axially relative to the winding drum. With the rotation of the winding drum, the steel wire can be evenly wound on the winding drum, avoiding uneven tension and reduced uniformity caused by repeated accumulation. Attached Figure Description
[0016] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0017] Figure 2 This is a schematic diagram of the winding mechanism of this utility model;
[0018] Figure 3 This is a cross-sectional view of the internal structure of the electrolytic cell of this utility model;
[0019] Figure 4 This is a cross-sectional view of the internal structure of the heating cylinder of this utility model.
[0020] Explanation of reference numerals in the attached figures
[0021] 1. Electrolytic cell;
[0022] 2. Rewinding mechanism; 201. Fixing plate; 202. Motor; 203. Rewinding shaft;
[0023] 204. Take-up roller assembly; 2041. Mounting plate; 2042. Stop block; 2043. Take-up drum; 2044. Fixing bolts;
[0024] 205. Transmission assembly; 2051. Driving wheel; 2052. Driven wheel;
[0025] 206. Reciprocating lead screw mechanism; 2061. Vertical plate; 2062. Reciprocating lead screw; 2063. Slider; 2064. Guide block; 2065. Guide rod; 207. Guide column;
[0026] 3. Guiding assembly; 301. First guide roller; 302. Second guide roller; 303. Feed inlet; 304. Discharge outlet;
[0027] 4. Drying assembly; 401. Heating cylinder; 402. Fixing rod; 403. Heating wire. Detailed Implementation
[0028] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of the embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of this application.
[0029] Please see Figures 1-4 The present invention proposes the following implementation scheme: an electroplating tank for memory steel wire, including an electrolytic tank 1, a guide component 3 is provided on the electrolytic tank 1, the guide component 3 includes a first guide roller 301 and a second guide roller 302, the height of the first guide roller 301 is higher than that of the second guide roller 302, and the guide component 3 also includes a feed port 303 and a discharge port 304 opened at both ends of the electrolytic tank 1.
[0030] Please refer to this carefully. Figure 1 and Figure 4 The guide component 3 is equipped with a drying component 4, which includes a heating cylinder 401 and a fixing rod 402. The fixing rod 402 is fixed inside the discharge port 304, and the heating cylinder 401 and the fixing rod 402 are fixed together.
[0031] The heating cylinder 401 has an installation cavity inside, and a heating wire 403 is installed in the installation cavity. The heating wire 403 can heat the steel wire. Furthermore, a fan is installed on the heating cylinder 401, and the output end of the fan points to the right end of the heating cylinder 401. The heating wire 403 and the fan work together to improve the drying effect.
[0032] Please refer to this carefully. Figure 1 and Figure 2 An electrolytic cell 1 is provided with a winding mechanism 2. The winding mechanism 2 includes a fixing plate 201 fixed to the electrolytic cell 1. A motor 202 is mounted on the fixing plate 201 via a motor mount. A winding shaft 203 is fixed to the output end of the motor 202.
[0033] A winding roller assembly 204 is mounted on the winding shaft 203. The winding roller assembly 204 includes a mounting plate 2041, which is fixed to the top surface of the electrolytic cell 1. The mounting plate 2041 is rotatably connected to the winding shaft 203. The winding roller assembly 204 also includes a stop block 2042 and a winding drum 2043.
[0034] The stop block 2042 is fixed on the take-up shaft 203, and the take-up cylinder 2043 is slidably sleeved on the take-up shaft 203. The right end of the take-up shaft 203 is threaded. The take-up roller assembly 204 also includes a fixing bolt 2044 for threaded connection with the right end of the take-up shaft 203. After removing the fixing bolt 2044, the take-up cylinder 2043 can be removed.
[0035] Please refer to this carefully. Figure 2 The winding mechanism 2 also includes a reciprocating screw mechanism 206, on which a guide post 207 is fixed. The reciprocating screw mechanism 206 includes a vertical plate 2061, which is fixed to the top surface of the electrolytic cell 1. A reciprocating screw 2062 is rotatably connected to the vertical plate 2061, and a slider 2063 is installed on the reciprocating screw 2062. The guide post 207 is fixed to the top surface of the slider 2063.
[0036] The bottom surface of the slider 2063 is fixed with a guide block 2064, and the reciprocating screw mechanism 206 also includes a guide rod 2065 fixed on the vertical plate 2061. The guide block 2064 and the guide rod 2065 are slidably connected.
[0037] The take-up shaft 203 is also provided with a transmission assembly 205 for driving the reciprocating screw mechanism 206. The transmission assembly 205 includes a driving wheel 2051 and a driven wheel 2052. The driving wheel 2051 is fixed on the take-up shaft 203. A belt is installed between the driving wheel 2051 and the driven wheel 2052. The driving wheel 2051 can drive the driven wheel 2052 to rotate through the belt. The driven wheel 2052 will drive the reciprocating screw 2062 to rotate.
[0038] Working principle: When winding up the electroplated steel wire, the motor 202 of the steel wire electroplating tank drives the winding drum 2043 to rotate via the winding shaft 203. At the same time, the winding shaft 203 also drives the drive wheel 2051, the driven wheel 2052, and the reciprocating screw 2062 to rotate. The rotation of the reciprocating screw 2062 causes the slider 2063 to drive the guide column 207 to move back and forth. The reciprocating movement of the guide column 207 causes the steel wire to move axially relative to the winding drum 2043. Combined with the rotation of the winding drum 2043, the steel wire can be evenly wound on the winding drum 2043, avoiding uneven tension and reduced uniformity caused by repeated accumulation.
[0039] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claims. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A memory steel wire electroplating tank, comprising an electrolytic tank (1), wherein a guiding component (3) is disposed on the electrolytic tank (1), and a drying component (4) is disposed on the guiding component (3), characterized in that: The electrolytic cell (1) is provided with a winding mechanism (2); The winding mechanism (2) includes a fixed plate (201) fixed to the electrolytic cell (1), a motor (202) is mounted on the fixed plate (201) via a motor mount, a winding shaft (203) is fixed to the output end of the motor (202), and a winding roller assembly (204) is mounted on the winding shaft (203); The winding mechanism (2) further includes a reciprocating screw mechanism (206), and the winding shaft (203) is also provided with a transmission assembly (205) for driving the reciprocating screw mechanism (206), and a guide column (207) is fixed on the reciprocating screw mechanism (206).
2. The electroplating tank for memory steel wire according to claim 1, characterized in that: The guiding assembly (3) includes a first guiding roller (301) and a second guiding roller (302), wherein the height of the first guiding roller (301) is higher than that of the second guiding roller (302). The guiding assembly (3) also includes a feed inlet (303) and a discharge outlet (304) located at both ends of the electrolytic cell (1).
3. The electroplating tank for memory steel wire according to claim 2, characterized in that: The drying assembly (4) includes a heating cylinder (401) and a fixing rod (402). The fixing rod (402) is fixed inside the discharge port (304). The heating cylinder (401) and the fixing rod (402) are fixed together. The heating cylinder (401) has an installation cavity inside, and a heating wire (403) is installed in the installation cavity.
4. The electroplating tank for memory steel wire according to claim 1, characterized in that: The take-up roller assembly (204) includes a mounting plate (2041) fixed to the top surface of the electrolytic cell (1) and rotatably connected to the take-up shaft (203). The take-up roller assembly (204) also includes a stop block (2042) and a take-up cylinder (2043). The stop block (2042) is fixed on the take-up shaft (203), and the take-up cylinder (2043) is slidably sleeved on the take-up shaft (203). The right end of the take-up shaft (203) is threaded. The take-up roller assembly (204) also includes a fixing bolt (2044) for threaded connection with the right end of the take-up shaft (203).
5. A memory steel wire electroplating tank according to claim 1, characterized in that: The transmission assembly (205) includes a drive wheel (2051) and a driven wheel (2052). The drive wheel (2051) is fixed on the take-up shaft (203), and a belt is installed between the drive wheel (2051) and the driven wheel (2052).
6. A memory steel wire electroplating tank according to claim 1, characterized in that: The reciprocating screw mechanism (206) includes a vertical plate (2061) fixed on the top surface of the electrolytic cell (1), a reciprocating screw (2062) rotatably connected to the vertical plate (2061), a slider (2063) mounted on the reciprocating screw (2062), and a guide post (207) fixed on the top surface of the slider (2063).
7. A memory steel wire electroplating tank according to claim 6, characterized in that: The bottom surface of the slider (2063) is fixed with a guide block (2064), and the reciprocating screw mechanism (206) also includes a guide rod (2065) fixed on the vertical plate (2061). The guide block (2064) and the guide rod (2065) are slidably connected.