Integrated busbar electrical property comprehensive testing device

By integrating a comprehensive electrical testing device for busbars, utilizing a design with detachable copper bars and probes, and combining it with automated drive components, the device solves the problems of limited functionality, high cost, and poor compatibility of existing testing equipment. It achieves high-precision, low-cost electrical testing, improving testing efficiency and versatility.

CN224500810UActive Publication Date: 2026-07-14DONGGUAN GUI XIANG INSULATION MATERIAL CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN GUI XIANG INSULATION MATERIAL CO LTD
Filing Date
2025-07-11
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing testing equipment is limited in function, costly, space-consuming, and difficult to adapt to product diversity. It also cannot accurately and comprehensively test electrical performance, and has poor compatibility between devices, affecting testing efficiency and quality.

Method used

Design an integrated busbar electrical comprehensive testing device, including the device body, platform and testing components, to perform high-precision electrical testing using detachable copper bars and probes, and combine automated drive components and electrical control system to achieve flexible adaptability and efficient testing of products with multiple specifications.

Benefits of technology

It achieves high-precision electrical testing, reduces equipment costs, improves testing efficiency and versatility, reduces human intervention and errors, and ensures the reliability and consistency of test results.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to the technical field of electrical property testing, and discloses an integrated busbar electrical property comprehensive testing device. The testing device comprises a device body, a carrier and a detection assembly; the device body is provided with a detection area, the carrier is placed in the detection area to place a product to be detected, and the detection assembly is slidably connected to the top of the detection area in the vertical direction; the detection assembly comprises a driving piece, a mounting plate and a plurality of copper bars; the driving piece is arranged at the top of the device body, the vertical driving end of the driving piece penetrates through the device body to connect the mounting plate, the plurality of copper bars are detachably connected to the mounting plate, and probes are arranged on each copper bar. The testing device in the application can adapt to integrated busbar products of various specifications and models, special testing devices do not need to be customized for each product, the equipment cost investment of an enterprise is reduced, and the universality and flexibility of the equipment are improved; the automatic driving function of the driving piece enables the detection process to realize automatic operation, and the detection efficiency is improved.
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Description

Technical Field

[0001] This application relates to the technical field of electrical testing, and in particular to an integrated busbar electrical comprehensive testing device. Background Technology

[0002] In the current field of electronics manufacturing and testing, the selection of testing equipment is crucial. Traditionally, the industry has often used specialized test fixtures and larger-scale testing equipment to perform electrical tests on various products. However, these existing testing methods have many significant drawbacks, severely restricting further improvements in testing efficiency and product quality.

[0003] On the one hand, specialized testing fixtures are typically designed for specific products, offering limited functionality and making it difficult to adapt to the trend of diversified product styles. This means that each new product launch often requires a redesign and remanufacturing of the corresponding fixture, resulting in high production costs. On the other hand, while larger testing equipment offers a degree of versatility, its bulky size occupies significant space. Furthermore, when products are redesigned or updated, the time required for equipment adjustment and reconfiguration greatly reduces production efficiency.

[0004] More importantly, existing testing equipment has shortcomings in electrical testing, failing to accurately and comprehensively detect the electrical performance of products. Especially as customers increasingly demand higher electrical performance from products with complex structures, traditional equipment struggles to meet the needs of multi-parameter, high-precision testing. The testing process faces significant challenges, leading to insufficient reliability of test results and impacting product quality control.

[0005] Furthermore, poor compatibility between different devices is also a prominent issue. Each device operates independently, making data sharing and collaborative work difficult. In multi-stage testing processes, this increases the complexity of integration and management, easily leading to gaps in testing procedures and affecting the overall continuity and efficiency of the testing process. Therefore, there is an urgent need for a new type of testing equipment that can solve these problems to meet the development needs of the modern electronics manufacturing industry. Utility Model Content

[0006] The technical problem to be solved by this application is to provide an integrated busbar electrical comprehensive testing device that can reduce manufacturing costs while ensuring test quality, be compatible with different products, and improve test efficiency.

[0007] To address the aforementioned issues, this application provides an integrated busbar electrical comprehensive testing device, comprising a device body, a stage, and a testing component. The device body has a testing area, the stage is placed within the testing area to hold the product to be tested, and the testing component is slidably connected above the testing area in a vertical direction. The testing component includes a driving component, a mounting plate, and several copper strips. The driving component is located at the top of the device body, and its vertical driving end penetrates the device body to connect to the mounting plate. Each copper strip is detachably mounted on the mounting plate, and each copper strip is equipped with a probe.

[0008] Preferably, the testing equipment further includes a testing fixture, which includes a base, a connecting seat, a testing device, and a translation device. The connecting seat, the testing device, and the translation device are all mounted on the base, which is disposed on the platform. The translation device includes a drive assembly and a guide rail. The testing device is slidably connected to the guide rail, and the drive end of the drive assembly is detachably connected to the testing device. The connecting seat is used to assemble the integrated busbar to be tested, and the testing device is provided with a connector for electrically connecting the integrated busbar.

[0009] Preferably, the drive assembly includes a base, a wrench, a connecting rod, and a drive rod. The base is fixed to the base, the wrench is rotatably connected to the base, and the wrench is rotatably connected to one end of the connecting rod. The other end of the connecting rod is connected to one end of the drive rod, and the other end of the drive rod is detachably connected to the testing device.

[0010] Preferably, the driving components are provided in two sets, and the two sets of driving components are located on the top of the device body.

[0011] Preferably, the driving component is an electric cylinder.

[0012] Preferably, the platform is provided with a conveying plane, and the product to be tested is placed on the conveying plane.

[0013] Preferably, a safety light curtain is provided around the detection area.

[0014] Preferably, the device body is equipped with an electrical control cabinet, and the drive component is signal-connected to the electrical control cabinet.

[0015] Preferably, the device body is equipped with a testing instrument cabinet.

[0016] Preferably, the device body is provided with several transparent windows.

[0017] Compared with the prior art, this application includes at least one of the following beneficial technical effects:

[0018] When performing electrical testing on integrated busbars, the product to be tested is placed on a platform, which serves to support and fix the product. When the drive unit operates, it moves the mounting plate vertically downwards. The probes on the copper strip approach and contact the corresponding test points on the integrated busbar as the mounting plate moves downwards. Through the contact between the probes and the product, an electrical circuit is formed, applying electrical signals such as current or voltage to the product. Electrical testing instruments connected to the copper strip (such as multimeters and oscilloscopes) are used to detect parameters such as current, voltage, and resistance in the circuit. Users can compare the detected parameter data with the product's normal electrical parameter standards to determine whether the product has manufacturing defects such as broken circuits, open circuits, short circuits, NTC sensor malfunctions, connector misalignment, and open or short circuits in connector soldering.

[0019] Here, precise control of the drive unit propels the mounting plate and probes vertically, ensuring accurate contact between the probes and product test points. The detachable copper strip and probe design allows for flexible adjustment of layout and spacing to suit different product characteristics, guaranteeing accurate signal transmission and achieving high-precision electrical testing. Because the copper strip is detachably connected to the mounting plate, and the probes can be adjusted as needed, the equipment can adapt to various specifications and models of integrated busbar products, eliminating the need for customized testing equipment for each product. This reduces equipment costs and enhances the equipment's versatility and flexibility. Furthermore, the automatic drive function of the drive unit automates the testing process, improving efficiency, reducing errors and risks associated with manual intervention, and lowering labor costs. Attached Figure Description

[0020] To more clearly illustrate the technical solutions of the embodiments of this application, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0021] Figure 1 This is a schematic diagram of the overall structure of the test equipment in the embodiments of this application.

[0022] Figure 2 This is a schematic diagram showing the assembly relationship between the detection component and the stage in an embodiment of this application.

[0023] Figure 3 This is a schematic diagram illustrating the assembly relationship between the mounting plate and the copper strip in an embodiment of this application.

[0024] Figure 4 This is a schematic diagram illustrating the assembly relationship between the test fixture and the integrated busbar product in an embodiment of this application.

[0025] Figure 5 This is a schematic diagram of the overall structure of the test fixture in the embodiments of this application.

[0026] Explanation of reference numerals in the attached drawings: 1. Equipment body; 2. Platform; 3. Detection component; 4. Safety light curtain; 5. Detection area; 6. Electrical control cabinet; 7. Test instrument cabinet; 8. Viewing window; 9. Drive component; 10. Mounting plate; 11. Copper strip; 12. Integrated busbar product; 13. Base; 14. Connecting seat; 15. Test device; 16. Translation device; 17. Drive component; 18. Base; 19. Wrench; 20. Linkage rod; 21. Drive rod; 22. Guide rail; 23. Test fixture. Detailed Implementation

[0027] 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 some embodiments of this application, not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0028] It should be understood that, when used in this specification and the appended claims, the terms "comprising" and "including" indicate the presence of the described features, integrals, steps, operations, elements and / or components, but do not exclude the presence or addition of one or more other features, integrals, steps, operations, elements, components and / or collections thereof.

[0029] It should also be understood that the terminology used in this application specification is for the purpose of describing particular embodiments only and is not intended to limit the application. As used in this application specification and the appended claims, the singular forms “a,” “an,” and “the” are intended to include the plural forms unless the context clearly indicates otherwise.

[0030] It should also be further understood that the term “and / or” as used in this application specification and the appended claims means any combination of one or more of the associated listed items and all possible combinations, and includes such combinations.

[0031] Please refer to Figures 1 to 5 This application provides an integrated busbar electrical comprehensive testing device, which is used to detect defects in the manufacturing process of the integrated busbar product 12, such as line breakage, open circuit, short circuit, NTC sensor malfunction, connector misalignment, and connector soldering open circuit or short circuit, etc.

[0032] The testing equipment includes a main body 1, a stage 2, and a testing component 3. The main body 1 has a testing area 5 in its center. The stage 2 is placed within the testing area 5 to hold the integrated busbar product 12 to be tested. The testing component 3 is vertically slidably connected to the top of the testing area 5. Specifically, the testing component 3 includes a drive component 9, a mounting plate 10, and several copper strips 11. The drive component 9 is fixedly mounted on the top of the main body 1, and its vertical drive end penetrates the main body 1 to connect to the mounting plate 10 located in the testing area 5. The copper strips 11 are detachably connected to the bottom of the mounting plate 10, and each copper strip 11 is equipped with a probe.

[0033] When performing electrical tests on the integrated busbar product 12, the product 12 to be tested is placed on the platform 2, which serves to support and fix the product. When the drive unit 9 operates, it drives the mounting plate 10 to move downwards in the vertical direction. The probes on the copper strip 11 approach and contact the corresponding test points on the integrated busbar product 12 as the mounting plate 10 moves downwards. Through the contact between the probes and the product, an electrical circuit is formed, and electrical signals such as current or voltage are applied to the product. Electrical testing instruments (such as multimeters, oscilloscopes, etc.) connected to the copper strip 11 are used to detect parameters such as current, voltage, and resistance in the circuit. In addition, the test data in this embodiment is connected to an external testing system for transmission. When the testing system receives the test data, it can determine whether the data is qualified according to preset standards, thereby determining whether the product has manufacturing defects such as broken circuits, open circuits, short circuits, abnormal NTC sensors, misaligned connectors, and open or short circuits in connector soldering.

[0034] Here, the precise control of the drive unit 9 drives the mounting plate 10 and probes to move vertically, ensuring that the probes accurately contact the product test points. Furthermore, the detachable copper strip 11 and probe design allow for flexible adjustment of the layout and spacing according to different product characteristics, ensuring accurate transmission of the detection signal and achieving high-precision electrical testing. Since the copper strip 11 is detachably connected to the mounting plate 10, and the probes can be adjusted as needed, the equipment can adapt to various specifications and models of integrated busbar products 12, eliminating the need for customized testing equipment for each product. This reduces equipment costs for enterprises and improves the equipment's versatility and flexibility. In addition, the automatic drive function of the drive unit 9 enables automated operation of the testing process, improving testing efficiency, reducing errors and risks caused by manual intervention, lowering labor costs, and saving space for storing dedicated testing equipment.

[0035] Please refer to Figure 2 In one specific embodiment, two sets of driving components 9 are provided, symmetrically arranged on the top of the device body 1, and the vertical driving ends of the two sets of driving components 9 respectively penetrate through the device body 1 to connect to the top of the mounting plate 10. In this embodiment, the driving component 9 is an electric cylinder.

[0036] Two sets of electric cylinders are symmetrically arranged on the top of the equipment body 1. This symmetrical layout ensures the balance and stability of the mounting plate 10 during vertical movement. When the integrated busbar product 12 needs to be tested, both sets of electric cylinders simultaneously receive control signals. The control signals start the motors of the electric cylinders, and the rotation of the motors drives the lead screw to rotate, which in turn moves the vertical drive end connected to the nut downward. Since the two sets of electric cylinders are controlled synchronously, their vertical drive ends can push the mounting plate 10 downward at the same speed and with the same stroke. A copper strip 11 with a probe is connected to the bottom of the mounting plate 10. The vertical downward movement of the mounting plate 10 allows the probe to accurately contact the test point of the integrated busbar product 12. After the test is completed, the electric cylinders reverse, and the vertical drive end moves upward, driving the mounting plate 10 and the probe upward, away from the product test point, making it easy to remove the tested product and place a new integrated busbar product 12 to be tested.

[0037] To address this, the vertical movement of the mounting plate 10 and the probe, driven by an electric cylinder, enables the probe to automatically contact and separate from the product's test points. This precise motion control is crucial for the entire testing equipment to efficiently and accurately detect the electrical performance of the integrated busbar product 12. The arrangement of two sets of symmetrical electric cylinders ensures that the probe can contact the product uniformly and stably, avoiding problems such as tilting of the mounting plate 10 and poor probe contact that might occur with a single set of drives. This ensures accurate transmission of the detection signal, improves the reliability of the test results, and enables the testing equipment to accurately detect various defects in the integrated busbar product during manufacturing.

[0038] In this embodiment, the platform 2 is a fixed platform 2. In another embodiment, the platform 2 is provided with a conveying plane, and the integrated busbar product 12 to be tested is placed on the conveying plane.

[0039] In this embodiment, when the detection component 3 moves vertically, the fixed stage 2 ensures that the product under test remains in a fixed position during the detection process. This stability is crucial for accurate electrical testing because if the product shifts during testing, it may lead to poor contact between the probe and the test point, thus affecting the accuracy of the test results. The fixed stage 2 allows the detection component 3 to perform detection operations on the product within a relatively fixed spatial range, and its simple and stable structure helps reduce the overall complexity of the equipment.

[0040] In another embodiment, the platform 2 uses a conveyor plane to place and transport the product under test. The conveyor plane can take various forms, such as a conveyor belt or roller conveyor. During testing, the integrated busbar product 12 under test is placed on the conveyor plane. Driven by a power unit (such as a motor), the conveyor plane automatically transports the product to a designated position within the testing area 5. This designated position typically corresponds to the location of the probes on the testing component 3, ensuring that the probes accurately contact the test points on the product.

[0041] Furthermore, the conveyor plane can also be equipped with a positioning device. When the integrated busbar product 12 is conveyed to the detection position, the positioning device (such as a stop mechanism or photoelectric sensor) will trigger a signal to stop the conveyor plane and simultaneously activate the drive component 9 of the detection assembly 3, causing the probe to press down and contact the product for detection. After the detection is completed, the conveyor plane can restart, conveying the detected product out and simultaneously conveying the next product to be tested to the detection position. This conveyor plane setup can further automate the detection process, reduce manual intervention, and improve detection efficiency. It can sequentially feed products into the detection area 5 according to a certain rhythm (time interval), realizing continuous detection operations and adapting to the detection needs of large-volume products.

[0042] In one specific embodiment, a safety light curtain 4 is provided around the detection area 5. In this embodiment, the safety light curtain 4 is located at the corners of the detection area 5. Around the detection area 5, the transmitter and receiver of the safety light curtain 4 are respectively installed at opposite positions at the corners, and the beam emitted by the transmitter crosses the detection area 5, forming an invisible "protective net".

[0043] When an object (such as an operator's hand or body part) enters the detection area 5 and blocks the light beam, the receiver cannot receive the light signal from the blocked part. At this time, the safety light curtain 4 will immediately detect the interruption of the light signal and generate an obstruction signal. This obstruction signal will be transmitted to the equipment's control system. Upon receiving the signal, the control system will react quickly, usually by immediately stopping the operation of the detection equipment, especially by the drive component 9 driving the movement of the detection component 3, to prevent injury to the operator and to prevent damage to the testing equipment due to accidental collisions.

[0044] In one specific embodiment, the bottom of the equipment body 1 is respectively provided with an electrical control cabinet 6 and a test instrument cabinet 7. The drive component 9 is connected to the electrical control cabinet 6 via a signal.

[0045] The electrical control cabinet 6 is the control center of the testing equipment. It houses various control components, such as a programmable logic controller (PLC), relays, and contactors. The electrical control cabinet 6 receives signals from various parts of the testing equipment, such as the blocking signal from the safety light curtain 4, the position feedback signal from the drive component 9, and the limit switch signal from the mounting plate 10. These signals are transmitted to the control components, and after logical judgment and processing, the control components issue corresponding instructions to drive the actuators. The electrical control cabinet 6 is also responsible for the equipment's power management. It has an internal power module that converts external power (such as AC mains power) into the appropriate voltage and current required by the various components inside the equipment. Simultaneously, the electrical control cabinet 6 is equipped with various safety protection devices, such as overload protection relays and short-circuit protectors. When the equipment experiences overload (such as excessive motor load) or short circuit (such as a short circuit in the circuit), these protection devices can quickly cut off the power supply to prevent equipment damage and safety accidents.

[0046] Test instrument cabinet 7 is mainly used to house various electrical testing instruments, such as high-precision multimeters, oscilloscopes, and insulation resistance testers. These instruments are used for the precise measurement and analysis of the electrical parameters of the integrated busbar product 12. The instruments in test instrument cabinet 7 are connected to the control elements in electrical control cabinet 6 via data acquisition cards or communication interfaces (such as USB, RS-232, etc.). During testing, the electrical parameter data collected by the testing instruments is transmitted to the control elements, which can further process and store this data. The instruments in test instrument cabinet 7 and electrical control cabinet 6 work together to display the test results on a human-machine interface for easy viewing by operators. The test results may include information such as whether the product is qualified, specific electrical parameter values, and fault location.

[0047] In one specific embodiment, the device body 1 is provided with a plurality of perspective windows 8.

[0048] The viewing window 8 is typically made of transparent materials (such as tempered glass or high-strength transparent plastic). Installed on the equipment body 1, it allows operators to visually observe the working status of various key components inside the equipment during operation, enabling them to quickly understand the equipment's operating status. During operation, the viewing window 8 also serves a safety monitoring function. If abnormalities such as smoke or sparks occur inside the equipment, operators can promptly detect them through the viewing window 8 and take swift action, such as emergency shutdown, to prevent the accident from escalating.

[0049] Please refer to Figure 4In one specific embodiment, the testing equipment further includes a testing fixture 23. The testing fixture 23 includes a base 13, a connecting seat 14, a testing device 15, and a translation device 16. The connecting seat 14, the testing device 15, and the translation device 16 are all mounted on the base 13. The translation device 16 includes a drive assembly 17 and a guide rail 22. The testing device 15 is slidably connected to the guide rail 22, and the drive end of the drive assembly 17 is detachably connected to the testing device 15. The connecting seat 14 is used to assemble the integrated busbar product 12 to be tested, and the testing device 15 is provided with a connector for electrically connecting the integrated busbar product 12.

[0050] The base 13 serves as a support platform, allowing the test fixture 23 to be mounted on the fixed platform 2. The base 13 also securely mounts the connecting seat 14, the translation device 16, and the test device 15, providing a stable mechanical structure. The connecting seat 14 secures the integrated busbar product 12 to be tested, ensuring its stable position during testing. The drive assembly 17 drives the test device 15 to move linearly along the guide rail 22, enabling contact or separation between the test device 15 and the busbar product. The test device 15 is connected to the guide rail 22 via a sliding structure (such as a slider), and its external connectors (such as plugs, conductive clips, etc.) are used to electrically connect to the tested portion of the busbar product. The drive end of the drive assembly 17 is detachably connected to the test device 15 (such as with bolts or clips), facilitating the replacement of test devices 15 with different specifications.

[0051] When performing insulation withstand voltage tests using the test fixture 23, the integrated busbar product 12 is first fixed on the connector 14. The drive assembly 17 pushes the test device 15 to move via the guide rail 22, ensuring that the connector of the test device 15 precisely aligns with the conductive parts (such as pins) of the busbar to form an electrical connection. The test program is then started, and the test device 15 applies high voltage to the integrated busbar product 12 through the connector to test its insulation performance (such as leakage current and breakdown voltage). During the test, the translation device 16 maintains stable contact of the test device 15, preventing test errors caused by vibration or displacement. After the test is completed, the drive assembly 17 reverses the drive to detach the test device 15 from the integrated busbar product 12, facilitating the replacement of the integrated busbar product 12 to be tested.

[0052] Here, the automatic docking and separation of the test device 15 and the integrated busbar product 12 is achieved by driving the translation device 16, reducing manual operation and improving test accuracy and efficiency. The guiding function of the guide rail 22 ensures that the connector of the test device 15 and the conductive part of the integrated busbar product 12 are precisely aligned, reducing wear on the conductive parts, extending the service life of the fixture, and avoiding test failures caused by poor contact or misalignment. The drive assembly 17 is detachably connected to the test device 15, the integrated busbar product 12, and the connector 14, facilitating quick replacement of different specifications of the integrated busbar product 12 or the test device 15 under test, improving the versatility and flexibility of the test fixture 23, adapting to the testing needs of multiple product models, and facilitating the maintenance of the test fixture 23.

[0053] Please refer to Figure 5 Furthermore, the drive assembly 17 includes a base 18, a wrench 19, a connecting rod 20, and a drive rod 21. The base 18 is fixedly connected to the base 13, the wrench 19 is rotatably connected to the base 18, and the wrench 19 is rotatably connected to one end of the connecting rod 20. The other end of the connecting rod 20 is rotatably connected to one end of the drive rod 21, and the other end of the drive rod 21 is detachably connected to the testing device 15.

[0054] The base 18 serves as a fixed fulcrum, mounted on the base 13, providing support and a reference for the wrench 19, connecting rod 20, and drive rod 21. The wrench 19, as the driving element, is rotatably connected to the base 18 (e.g., by a pin hinge). When the operator manually operates the wrench 19, it rotates around the fixed axis of the base 18. The connecting rod 20, as a transmission intermediate, is rotatably connected at both ends to the wrench 19 and drive rod 21 (e.g., via pins or spherical bearings). When the wrench 19 rotates clockwise or counterclockwise, the connecting rod 20 is pulled or pushed. The drive rod 21, as the driven element, reciprocates linearly along the guide rail 22 under the influence of the connecting rod 20, thereby driving the testing device 15 closer to or further away from the integrated busbar product 12.

[0055] By manually operating the wrench 19, operators can precisely control the moving speed and contact pressure of the testing device 15, avoiding connector impact damage that may occur due to excessive speed caused by electric drive. This is especially suitable for testing scenarios sensitive to contact accuracy and pressure (such as the mating of plugs and female pins). Manual drive requires no electricity or air supply, relying solely on mechanical linkage transmission, reducing equipment complexity and failure rate, and lowering maintenance costs. It is suitable for scenarios where high automation is not required but stable transmission is necessary (such as laboratory testing and small-batch production inspection). The rotation angle of the wrench 19 provides intuitive feedback on the position of the testing device 15, facilitating quick adjustment to the preset test position. Reversing the wrench 19 easily resets the device, improving testing efficiency.

[0056] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any person skilled in the art can easily conceive of various equivalent modifications or substitutions within the technical scope disclosed in this application, and these modifications or substitutions should all be covered within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of the claims.

Claims

1. An integrated busbar electrical comprehensive testing device, comprising a device body, characterized in that: It also includes a stage and a detection component; The device body has a detection area, the platform is placed in the detection area to place the product to be detected, and the detection component is slidably connected above the detection area in the vertical direction; The detection component includes a driver, a mounting plate, and several copper strips. The driver is located on the top of the device body, and the vertical driving end of the driver penetrates the device body to connect to the mounting plate. Each copper strip is detachably mounted on the mounting plate, and each copper strip is equipped with a probe.

2. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The testing equipment also includes a testing fixture, which comprises a base, a connecting seat, a testing device, and a translation device. The connecting seat, the testing device, and the translation device are all mounted on the base, which is located on the platform. The translation device includes a drive assembly and a guide rail. The testing device is slidably connected to the guide rail, and the drive end of the drive assembly is detachably connected to the testing device. The connecting seat is used to assemble the integrated busbar to be tested, and the testing device is provided with a connector for electrically connecting the integrated busbar.

3. The integrated busbar electrical comprehensive testing equipment according to claim 2, characterized in that, The drive assembly includes a base, a wrench, a connecting rod, and a drive rod. The base is fixed to the base, the wrench is rotatably connected to the base, and the wrench is rotatably connected to one end of the connecting rod. The other end of the connecting rod is connected to one end of the drive rod, and the other end of the drive rod is detachably connected to the testing device.

4. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The drive unit is provided in two sets, and the two sets of drive units are located on the top of the device body.

5. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The driving component is an electric cylinder.

6. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The platform is equipped with a conveying plane, and the product to be tested is placed on the conveying plane.

7. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The detection area is surrounded by a safety light curtain.

8. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The device body is equipped with an electrical control cabinet, and the drive component is signal-connected to the electrical control cabinet.

9. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The device itself is equipped with a testing instrument cabinet.

10. The integrated busbar electrical comprehensive testing equipment according to claim 1, characterized in that, The device body has several transparent windows.