Electroplating hanger assembly and electroplating apparatus
By equipping each clamping component with a detection element in the electroplating hanger assembly, the position of the clamping component can be monitored and adjusted in real time, thus solving the problem of uneven current distribution and improving electroplating quality and production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HANS CNC SCI & TECH
- Filing Date
- 2025-06-27
- Publication Date
- 2026-06-05
AI Technical Summary
In the existing technology, the poor conductivity of the electroplating rack assembly leads to uneven current distribution on the rack assembly, affecting the electroplating quality. Furthermore, existing monitoring methods cannot accurately identify local conductivity anomalies.
Multiple clamping components are connected to the hanger, and each clamping component is equipped with a detection component to monitor the current in real time. An alarm signal is generated and the position of the clamping component is adjusted through a control device, so as to achieve independent and accurate detection of each clamping component.
It improves the uniformity of electroplated layers and the consistency of product quality, reduces plating defects caused by uneven current, shortens fault diagnosis and handling time, and improves production efficiency and yield.
Smart Images

Figure CN224325441U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of electroplating equipment technology, and in particular to an electroplating rack assembly and electroplating equipment. Background Technology
[0002] During electroplating, poor conductivity of the mounting bracket assembly can affect the current distribution within it, thus impacting electroplating quality. Therefore, monitoring the current in the mounting bracket assembly is necessary. Some technologies monitor the overall current of the mounting bracket assembly (e.g., at the connectors) to assess its conductivity. However, this method cannot effectively identify localized conductivity anomalies, making it difficult to guarantee electroplating quality in actual production. Utility Model Content
[0003] In order to overcome the problems existing in the prior art, the main objective of this application is to provide an electroplating rack assembly and an electroplating equipment.
[0004] To achieve the above objectives, this application specifically adopts the following technical solution:
[0005] According to a first aspect of the embodiments of this application, an electroplating hanger assembly is provided, comprising:
[0006] guide;
[0007] A mounting bracket, which is slidably connected to the guide rail;
[0008] Multiple clamping members are provided, each of which is connected to the end of the hanger away from the guide rail. The clamping members are used to clamp the workpiece to be plated and are configured to transmit current to the workpiece to be plated.
[0009] Multiple detection elements are provided, each of which is connected to one of the clamping elements, and each detection element is used to detect the current flowing through each clamping element.
[0010] Optionally, along the length of the guide rail, the guide rail is provided with a first sliding portion, and the hook is provided with a second sliding portion. The second sliding portion and the first sliding portion are adapted to achieve a sliding connection between the hook and the guide rail.
[0011] Optionally, the first sliding part is provided with sliding grooves on both sides, and the second sliding part is provided with sliding wheels on both sides, the sliding wheels being connected to the sliding grooves.
[0012] Optionally, the clamping member is provided with a first magnetic attraction part, and the detection member is provided with a second magnetic attraction part. The second magnetic attraction part and the first magnetic attraction part are adapted to achieve a magnetic connection between the detection member and the clamping member.
[0013] Optionally, the clamping member is provided with a first locking portion, and the detection member is provided with a second locking portion, the second locking portion and the first locking portion being adapted to achieve locking between the detection member and the clamping member.
[0014] Optionally, the electroplating rack assembly further includes a connector, the clamping member is provided with a first connecting hole, the detection member is provided with a second connecting hole, the second connecting hole and the first connecting hole are arranged opposite to each other, and the connector is sequentially inserted into the second connecting hole and the first connecting hole, the connector being used to detachably connect the detection member and the clamping member.
[0015] Optionally, the electroplating rack assembly further includes a control device, wherein the detection element and the control device are electrically connected, and the control device is configured to receive current information detected by the detection element and generate a corresponding current value, so as to compare the current value with a preset current threshold range, and, when the current value exceeds the preset current threshold range, the control device controls the issuance of an alarm signal.
[0016] Optionally, the clamping member is connected to the hook member via a drive rod. When the current value exceeds the preset current threshold range, the control device controls the drive rod to extend so that the corresponding clamping member extends to a preset position.
[0017] Optionally, the control device includes a storage unit for storing the current information.
[0018] According to a second aspect of the embodiments of this application, an electroplating apparatus is provided, including the electroplating rack assembly described in any of the above embodiments.
[0019] The embodiments of this application have at least the following beneficial effects:
[0020] In the technical solution of this application, multiple clamping components are used to connect the hanger components. Each clamping component connects to the workpiece to be plated. Corresponding to each clamping component, a detection component is provided. Each detection component directly measures the current flowing through its corresponding clamping component, allowing each component to directly reflect the actual current value transmitted from each clamping component to the workpiece to be plated. Therefore, during use, clamping components exhibiting abnormal current can be located promptly and accurately for subsequent processing. This structure solves the problem of ineffectively identifying localized conductive abnormalities in the hanger assembly, providing a reliable basis for precisely controlling the current density flowing through each workpiece to be plated. This significantly improves the uniformity of the electroplated layer and the consistency of product quality, reducing plating defects (such as burning or uneven thickness) caused by uneven current.
[0021] By using a structure in which multiple clamping components are connected to the hanger, multiple parts to be plated in the same batch can be clamped independently. Furthermore, by using a detection device to monitor the current of each clamping component in real time, independent and accurate detection of each clamping component in the electroplating hanger assembly is achieved, thereby improving the electroplating quality of the parts to be plated.
[0022] Electroplating equipment using the above-mentioned electroplating rack assembly can accurately identify abnormal clamping parts, which helps to ensure that the current flowing through each clamping part is within the normal processing range and improves the electroplating quality of the parts to be plated. Attached Figure Description
[0023] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0024] Figure 1 This is a schematic diagram of the overall structure of an electroplating hanger assembly provided in an embodiment of this application;
[0025] Figure 2 This is a schematic diagram of the assembly structure of the hanging parts and guide rails in an electroplating rack assembly provided in an embodiment of this application;
[0026] Figure 3 This is a schematic diagram of an assembly structure of a detection component and a clamping component in an electroplating hanger assembly provided in an embodiment of this application;
[0027] Figure 4 This is a schematic diagram of another assembly structure of the detection component and the clamping component in an electroplating hanger assembly provided in an embodiment of this application;
[0028] Figure 5 This is a schematic diagram of another assembly structure of the detection component and the clamping component in the electroplating hanger assembly provided in one embodiment of this application.
[0029] Explanation of icon numbers:
[0030] 10. Electroplating hanger assembly;
[0031] 100. Guide rail;
[0032] 110. First sliding part; 120. Sliding groove;
[0033] 200. Hook and connector;
[0034] 210. Second sliding part; 220. Pulley;
[0035] 300. Clamping components;
[0036] 310. First magnetic suction part; 320. First snap-fit part; 330. First connecting hole;
[0037] 400. Inspection items;
[0038] 410. Second magnetic suction part; 420. Second snap-fit part; 430. Second connecting hole;
[0039] 500. Connectors;
[0040] 600, conductive sheet.
[0041] The realization of the purpose, functional features and advantages of this application will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0042] 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 scope of protection of this application.
[0043] It should be noted that if the embodiments of this application involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.
[0044] Furthermore, if the embodiments of this application involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or," "and / or," or "and / or" throughout the text implies three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where A and B are simultaneously satisfied. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed in this application.
[0045] During electroplating, poor conductivity of the hanger assembly can affect the current distribution within it, thus impacting the plating quality. Therefore, monitoring the current in the hanger assembly is necessary. Currently, current monitoring is typically performed only on the overall hanger assembly (e.g., at the connectors). However, due to the distance between the hanger assembly and the clamps, the actual current flowing through each clamp can differ during transmission.
[0046] Therefore, current current monitoring of the entire mounting bracket assembly cannot accurately reflect the actual current in each clamp connected to the circuit board.
[0047] Based on this, in order to solve the technical problem that current current monitoring of the entire mounting bracket assembly cannot accurately reflect the actual current in each clamp connected to the circuit board, referring to... Figures 1 to 5 One embodiment of this application provides an electroplating rack assembly 10, which includes a guide rail 100, a mounting bracket 200, multiple clamping members 300, and multiple detection members 400. The mounting bracket 200 is slidably connected to the guide rail 100, and the guide rail 100 provides guidance for the mounting bracket 200, allowing the mounting bracket 200 to slide along the guide rail 100 to various workstations. Multiple clamping elements 300 are connected to the end of the hanger 200 away from the guide rail 100 (for example, the clamping elements 300 can be connected to the hanger 200 by detachable connection methods such as magnetic connection, snap-fit, or threaded connection to facilitate replacement of the clamping elements 300; or the clamping elements 300 can be connected to the hanger 200 by fixed connection methods such as welding or integral connection to improve the connection strength and stability between the clamping elements 300 and the hanger 200). The clamping elements 300 are used to clamp the workpiece to be plated (for example, the workpiece to be plated can be a circuit board) and are configured to transmit current to the workpiece to be plated (for example, the clamping element 300 may include a conductive sheet 600, which can uniformly transmit current to the workpiece to be plated) to achieve electroplating of the workpiece. Each detection element 400 is respectively connected to one clamping element 300, and each detection element 400 is used to detect the current flowing through each clamping element 300. For example, the detection component 400 can be a Hall sensor, a current transformer, etc.
[0048] It is understood that in this electroplating hanger assembly 10, the number of clamping components 300 can be 2, 3, 4, 5, or more, and the specific number of clamping components 300 can be reasonably configured according to actual production and installation needs. The number of detection components 400 corresponds to the number of clamping components 300. Among them, Figure 1 The following is an example using four clamping components (300).
[0049] Specifically, a detection element 400 is provided for each clamping component 300. Each detection element 400 directly measures the current flowing through its corresponding clamping component 300, so that each detection element 400 can most directly reflect the actual current value transmitted to the workpiece by each clamping component 300. This structure solves the problem in the prior art where only the overall current of the mounting assembly or the main circuit current is monitored, making it impossible to accurately know the specific current distribution of each clamping component 300. It provides a reliable basis for accurately controlling the current density flowing through each workpiece, thereby significantly improving the uniformity of the electroplated layer and the consistency of product quality, and reducing plating defects (such as burning, uneven thickness, etc.) caused by uneven current.
[0050] In practical applications, if a clamping component 300 experiences poor contact or abnormal current (too high, too low, or zero), the corresponding detection component 400 can promptly and independently reflect the abnormality of that clamping component 300. Operators or the control system can accurately locate the faulty clamping component 300 without needing to check or disassemble the entire electroplating rack assembly 10, significantly shortening fault diagnosis and handling time, reducing equipment downtime, and improving production efficiency and overall yield. For example, if the current applied to the electroplating rack assembly 10 is 100A, and one electroplating rack assembly 10 includes four clamping components 300, then theoretically, the current distributed in one clamping component 300 is 25A (100A / 4 = 25A). This current value is defined as the theoretical current value. Based on the theoretical current value, a threshold range for current abnormality is set. For example, 25A ± 3A can be set as the normal fluctuation range for current; clamping components 300 outside this range are considered to have abnormal current. For example, if a current of 20A is detected flowing through the clamping member 300, the current of the clamping member 300 is determined to be abnormal; if a current of 22A, 25A, 28A, etc. is detected flowing through the clamping member 300, the current of the clamping member 300 is determined to be normal; if a current of 30A is detected flowing through the clamping member 300, the current of the clamping member 300 is determined to be abnormal.
[0051] By detecting the structure of each clamping component 300 in real time corresponding to each detection component 400, independent and accurate detection of each clamping component 300 in the electroplating hanger assembly 10 is achieved. Abnormal clamping components 300 can be accurately identified during the production process for timely handling, such as replacing or repairing abnormal clamping components 300. This helps ensure that the current flowing through each clamping component 300 meets the electroplating processing requirements, thereby improving the electroplating quality of the workpiece to be plated by the clamping component 300.
[0052] Reference Figure 2It is understood that, along the length of the guide rail 100, the guide rail 100 is provided with a first sliding portion 110, and the hook member 200 is provided with a second sliding portion 210. The second sliding portion 210 and the first sliding portion 110 are adapted to achieve a sliding connection between the hook member 200 and the guide rail 100. For example, the first sliding portion 110 may be in the form of a groove, and the second sliding portion 210 may be in the form of a rail. Alternatively, if the first sliding portion 110 is in the form of a rail, the second sliding portion 210 may be in the form of a groove.
[0053] Specifically, through the mutual cooperation of the first sliding part 110 and the second sliding part 210, on the one hand, a stable and reliable constraint and guide are provided for the sliding of the hanger 200 on the guide rail 100, ensuring that the movement trajectory of the hanger 200 is precisely controllable when sliding along the length direction of the guide rail 100. This effectively prevents the hanger 200 from shaking, deviating, or getting stuck during the sliding process, significantly improving the stability and reliability of the hanger 200 during the sliding process, and ensuring that the hanger 200 can accurately transport the workpiece to be plated to the processing station. On the other hand, the first sliding part 110 and the second sliding part 210 are usually in surface contact, which effectively increases the contact area between the hanger 200 and the guide rail 100, improves the connection strength between the hanger 200 and the guide rail 100, effectively resists the lateral force or vibration that may be generated during the sliding process of the hanger 200, and ensures the stable progress of the electroplating process and the safe transport of the workpiece to be plated.
[0054] Reference Figure 2 It is understood that the first sliding part 110 has sliding grooves 120 on both sides, and the second sliding part 210 has sliding wheels 220 on both sides, with the sliding wheels 220 connected within the sliding grooves 120. When the hook 200 slides along the guide rail 100, the sliding wheels 220 can roll within the sliding grooves 120. One possible implementation is that the depth of the sliding groove 120 is greater than or equal to the diameter of the sliding wheel 220, ensuring that the sliding wheel 220 can be fully embedded within the sliding groove 120, thereby improving the connection stability between the sliding wheel 220 and the sliding groove 120.
[0055] Specifically, through the cooperation between the sliding wheel 220 and the sliding groove 120, some of the sliding friction between the hanger 200 and the guide rail 100 can be transformed into rolling friction, thereby effectively reducing the friction force when the hanger 200 slides on the guide rail 100, improving the sensitivity of the hanger 200 when sliding on the guide rail 100, and extending the service life of the electroplating hanger assembly 10.
[0056] Reference Figure 3It is understood that the clamping member 300 is provided with a first magnetic attraction portion 310, and the detection member 400 is provided with a second magnetic attraction portion 410. The second magnetic attraction portion 410 and the first magnetic attraction portion 310 are adapted to achieve a magnetic connection between the detection member 400 and the clamping member 300. For example, the clamping member 300 may include a rod body and a clamp, with the clamp connected to one end of the rod body and the first magnetic attraction portion 310 disposed on the rod body. The detection member 400 may include an annular clamp, and the second magnetic attraction portion 410 may be disposed on the inner sidewall of the annular clamp. Through the attraction effect of the second magnetic attraction portion 410 and the first magnetic attraction portion 310, the annular clamp can be stably connected to the rod body, thereby achieving a stable connection between the detection member 400 and the clamping member 300.
[0057] Specifically, a connection structure is provided between the detection element 400 and the clamping element 300, wherein the detection element 400 and the clamping element 300 are connected by magnetic attraction. This connection method saves time and effort; by bringing the first magnetic attraction part 310 and the second magnetic attraction part 410 close together, automatic attraction between the detection element 400 and the clamping element 300 can be achieved, further improving the installation accuracy and efficiency of the detection element 400 and the clamping element 300. Furthermore, it ensures a non-destructive connection between the detection element 400 and the clamping element 300, preventing physical damage during connection and improving the structural stability of the detection element 400 and the clamping element 300.
[0058] Reference Figure 4 It is understood that the clamping member 300 is provided with a first engaging portion 320, and the detection member 400 is provided with a second engaging portion 420. The second engaging portion 420 and the first engaging portion 320 are adapted to achieve engagement between the detection member 400 and the clamping member 300. For example, the first engaging portion 320 may be in the form of a engaging block, and the second engaging portion 420 may be in the form of a engaging groove. Alternatively, if the first engaging portion 320 is in the form of a engaging groove, the second engaging portion 420 may be in the form of a engaging block.
[0059] Specifically, another connection structure is provided between the detection element 400 and the clamping element 300, namely, the detection element 400 and the clamping element 300 adopt a snap-fit connection. With the above connection, on the one hand, the installation steps between the detection element 400 and the clamping element 300 can be simplified, the installation difficulty between the detection element 400 and the clamping element 300 can be reduced, and the installation efficiency between the detection element 400 and the clamping element 300 can be improved; on the other hand, the connection strength between the detection element 400 and the clamping element 300 can be improved, effectively reducing the probability of the detection element 400 and the clamping element 300 separating after being impacted, and improving the structural stability of the electroplating hanger assembly 10.
[0060] Reference Figure 5 It is understood that the electroplating hanger assembly 10 includes a connector 500, a clamping member 300 having a first connecting hole 330, and a detection member 400 having a second connecting hole 430. The second connecting hole 430 and the first connecting hole 330 are arranged opposite to each other. The connector 500 is sequentially inserted into the second connecting hole 430 and the first connecting hole 330, and the connector 500 is used to detachably connect the detection member 400 and the clamping member 300. For example, internal threads may be provided in the first connecting hole 330 and the second connecting hole 430, in which case the connector 500 can be a bolt or a screw.
[0061] Specifically, another connection structure is provided between the detection element 400 and the clamping element 300, namely, the detection element 400 and the clamping element 300 are connected by a thread. This connection method has two advantages: firstly, it is simple and allows for quick assembly and disassembly. When assembling the detection element 400 and the clamping element 300, the connector 500 is first inserted sequentially into the first connecting hole 330 and the second connecting hole 430, and then the connector 500 is screwed on until it is securely tightened within the first connecting hole 330 and the second connecting hole 430, thus achieving a tight connection between the detection element 400 and the clamping element 300. When disassembling the detection element 400 and the clamping element 300, the connector 500 is loosened and removed from the first connecting hole 330 and the second connecting hole 430. Secondly, it improves the connection strength between the detection element 400 and the clamping element 300, preventing the detection element 400 from detaching from the clamping element 300 and extending the service life of the detection element 400.
[0062] It is understood that the electroplating rack assembly 10 also includes a control device. The detection element 400 and the control device are electrically connected. The control device is configured to receive the current information detected by the detection element 400 and generate a corresponding current value so that the current value is compared with a preset current threshold range. When the current value exceeds the preset current threshold range, the control device controls the issuance of an alarm signal.
[0063] Specifically, through real-time monitoring of each detection element 400, the control device can receive the current information flowing through each clamping element 300 in real time and automatically generate a quantifiable current value. By automatically comparing the current value with a preset current threshold range, it can automatically determine whether the magnitude of the current flowing through any clamping element 300 is abnormal (e.g., the abnormality includes, but is not limited to, excessive current, insufficient current, or open circuit). If the current value exceeds the safe or process-permitted range (i.e., if the current value exceeds the preset current threshold range), the control device will immediately and actively trigger an alarm signal (e.g., the alarm signal may include audible and visual alarms, screen prompts, remote notifications, etc.) to promptly notify the operator. The operator, based on the prompt information, performs inspection and maintenance on the clamping element 300 with abnormal current. After processing, the current of the clamping element 300 is continuously monitored to ensure it is normal before it is re-inserted into the electroplating rack assembly 10 for electroplating and other operations.
[0064] By employing the aforementioned automatic monitoring method, the location of the faulty or abnormal clamping component 300 can be accurately pinpointed. Operators can quickly and directly locate the abnormal clamping component 300 without having to check all clamping components 300 one by one, and then replace or repair it. This significantly shortens the fault diagnosis and repair time, minimizes economic losses caused by scrapped parts, equipment damage, or production interruptions due to abnormal current, improves production efficiency, and saves production costs.
[0065] It is understood that the clamping member 300 is connected to the hanging member 200 via a drive rod. When the current value exceeds a preset current threshold range, the control device controls the drive rod to extend, causing the corresponding clamping member 300 to extend to a preset position. The clamping member 300 at the preset position will protrude beyond the other clamping members 300. For example, the drive rod can be driven by a drive motor, and the control device can control the drive motor to operate. When the current value exceeds the preset current threshold range, the control device will control the drive motor to operate, causing the drive motor to drive the drive rod to extend, thereby using the drive rod to move the clamping member 300 to the preset position.
[0066] Specifically, when an abnormal current flows through the clamping component 300, the control device will control the drive rod, causing the drive rod to extend the abnormal clamping component 300. This control method allows for a clear distinction between the abnormal clamping component 300 and the normal clamping component 300, facilitating precise location of the abnormal clamping component 300 by operators. This enables timely repair or replacement of the abnormal clamping component 300, ensuring the electroplating quality of the workpiece and reducing the rejection rate of the workpiece.
[0067] Understandably, the control device includes a storage unit for storing current information. This storage unit can store abnormal current information as well as normal current information. Based on the stored current information, the operator can obtain relevant information about the clamping component 300 corresponding to the current information, such as the component's serial number, production batch, processing time, etc. By storing current information, on the one hand, operators can quickly locate the malfunctioning clamping component 300, facilitating timely replacement and repair, thereby ensuring the electroplating quality of the workpiece. On the other hand, the stored abnormal information allows for tracing back to the specific production batch and the operating parameters of the clamping component 300 when the malfunction occurred, quickly pinpointing the source of the problem, improving production management efficiency, and saving production time costs.
[0068] Correspondingly, another embodiment of this application also provides an electroplating apparatus, which includes the electroplating rack assembly 10 of any of the above embodiments. The electroplating apparatus using the electroplating rack assembly 10 can accurately identify abnormal clamping components 300, ensuring that the current flowing through each clamping component 300 is within the normal processing range, thereby improving the electroplating quality of the clamping component 300 on the workpiece.
[0069] One possible implementation is that the electroplating equipment also includes a drive mechanism configured to drive the electroplating rack assembly 10 to move between the loading position, the electroplating position, and the unloading position. For example, firstly, the drive mechanism drives the electroplating rack assembly 10 to the loading position, where the workpiece to be plated can be clamped using the clamping member 300. Then, the drive mechanism drives the electroplating rack assembly 10 to the electroplating position, realizing the electroplating of the workpiece in the electroplating tank. Finally, the drive mechanism drives the electroplating rack assembly 10 to the unloading position, realizing the collection of the electroplated workpiece.
[0070] Thanks to the improvements to the electroplating rack assembly 10 described above, the electroplating equipment of this embodiment has the same technical effects as the electroplating rack assembly 10 described above, which will not be repeated here.
[0071] It should be noted that other contents of the electroplating rack assembly 10 and electroplating equipment not disclosed in this application can be found in the prior art, and will not be repeated here.
[0072] The above are merely preferred embodiments of this application and do not limit the patent scope of this application. Any equivalent structural transformations made based on the concept of this application and the contents of the specification and drawings of this application, or direct / indirect applications in other related technical fields, are included within the patent protection scope of this application.
Claims
1. An electroplating hanger assembly, characterized in that, include: guide; A mounting bracket, which is slidably connected to the guide rail; Multiple clamping members are provided, each of which is connected to the end of the hanger away from the guide rail. The clamping members are used to clamp the workpiece to be plated and are configured to transmit current to the workpiece to be plated. Multiple detection elements are provided, each of which is connected to one of the clamping elements, and each detection element is used to detect the current flowing through each clamping element.
2. The electroplating hanger assembly according to claim 1, characterized in that, Along the length of the guide rail, the guide rail is provided with a first sliding part, and the hook is provided with a second sliding part. The second sliding part and the first sliding part are adapted to achieve a sliding connection between the hook and the guide rail.
3. The electroplating hanger assembly according to claim 2, characterized in that, The first sliding part has sliding grooves on both sides, and the second sliding part has sliding wheels on both sides, with the sliding wheels connected to the sliding grooves.
4. The electroplating hanger assembly according to claim 1, characterized in that, The clamping member is provided with a first magnetic attraction part, and the detection member is provided with a second magnetic attraction part. The second magnetic attraction part and the first magnetic attraction part are adapted to achieve a magnetic connection between the detection member and the clamping member.
5. The electroplating hanger assembly according to claim 1, characterized in that, The clamping member is provided with a first locking part, and the detection member is provided with a second locking part. The second locking part and the first locking part are adapted to achieve the locking between the detection member and the clamping member.
6. The electroplating hanger assembly according to claim 1, characterized in that, The electroplating rack assembly also includes a connector. The clamping member is provided with a first connecting hole, and the detection member is provided with a second connecting hole. The second connecting hole and the first connecting hole are arranged opposite to each other. The connector is sequentially inserted into the second connecting hole and the first connecting hole. The connector is used to detachably connect the detection member and the clamping member.
7. The electroplating hanger assembly according to claim 1, characterized in that, The electroplating rack assembly also includes a control device. The detection element and the control device are electrically connected. The control device is configured to receive current information detected by the detection element and generate a corresponding current value so that the current value is compared with a preset current threshold range. When the current value exceeds the preset current threshold range, the control device controls the issuance of an alarm signal.
8. The electroplating hanger assembly according to claim 7, characterized in that, The clamping member is connected to the hanging member via a drive rod. When the current value exceeds the preset current threshold range, the control device controls the drive rod to extend so that the corresponding clamping member extends to a preset position.
9. The electroplating hanger assembly according to claim 7 or 8, characterized in that, The control device includes a storage unit for storing the current information.
10. Electroplating equipment, characterized in that, Includes the electroplating rack assembly as described in any one of claims 1 to 9.