A tooling platform
By designing a tooling platform that includes X, Y, and Z axis moving structures and pressing modules, the problem of the inability to adjust existing tooling platforms was solved, enabling durability and sliding durability testing of display products and improving testing efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUIZHOU DESAY SV AUTOMOTIVE
- Filing Date
- 2025-06-20
- Publication Date
- 2026-06-09
Smart Images

Figure CN224339789U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of tooling platform technology, and in particular to a tooling platform. Background Technology
[0002] Car manufacturers have requirements for touch / press life and sliding life tests on the screens of automotive electronic products such as displays. However, most existing tooling platforms have relatively fixed structures and cannot be adjusted and tested according to the size of the display products and test conditions (force magnitude, point position, trajectory, etc.) of different projects. Utility Model Content
[0003] The purpose of this utility model is to provide a tooling platform to solve the technical problem that most existing tooling platforms have relatively fixed structures and cannot be adjusted and tested according to the size of the display screen products and test conditions (force magnitude, point position, trajectory, etc.) of different projects.
[0004] To achieve the above objectives, the present invention provides a tooling platform, including a base. The base has an X-axis moving structure and a product fixing slide. The X-axis moving structure includes two first X-axis slide rail modules, which are respectively disposed on the two side edges of the base. A gantry structure is slidably connected above the two first X-axis slide rail modules. The gantry structure has a Y-axis moving structure, and the Y-axis moving structure has a Z-axis moving structure. The Z-axis moving structure has a pressing module, which can move along the X, Y, and Z axes. The pressing module includes a detachable and replaceable weight. The product fixing slide is disposed between the two first X-axis slide rail modules, and the weight can contact the product on the product fixing slide for testing.
[0005] Furthermore, the base includes a fixed panel and several side plates, the several side plates are respectively disposed on several side edges of the bottom of the fixed panel, two first X-axis slide rail modules are respectively disposed on the two side edges of the fixed panel, and the product fixing slide is slidably engaged with the fixed panel along the X-axis direction.
[0006] Furthermore, the fixed panel and the side panel are made of aluminum alloy, and the fixed panel and the side panel are provided with air vents. One side panel is provided with an aviation interface module, and the bottom of several side panels is provided with anti-slip feet.
[0007] Furthermore, the product fixing slide includes a product fixing platform, and two second X-axis slide rail modules are slidably connected between the product fixing platform and the fixing panel. A first opening is provided on one side edge of the fixing panel, and a second opening is provided in the middle of the product fixing platform. The second opening cooperates with the first opening, and the first opening and the second opening are located between the two second X-axis slide rail modules.
[0008] Furthermore, a push-pull handle is provided on one side edge of the product fixing platform, and a rotating fixing pin is provided between the other side edge of the product fixing platform and the fixing panel. Several threaded holes are opened on the product fixing platform in a matrix distribution, and the threaded holes can be connected to the product fixing clamp.
[0009] Furthermore, the X-axis moving structure also includes a first lead screw module and a first motor. The first lead screw module is located above one of the first X-axis slide rail modules, and the first motor is located below the fixed panel. One end of the first lead screw module is connected to the top end of the first motor, and the first lead screw module is drivenly connected to the gantry structure.
[0010] Furthermore, the X-axis moving structure also includes a first limit sensor, a heat insulation cover, a first wiring tank chain, and a limit block. The first limit sensor and the limit block are respectively located at both ends of another first X-axis slide rail module. The heat insulation cover is located above the fixed panel and covers the top of the first motor.
[0011] Furthermore, the Y-axis moving structure includes a second lead screw module, a second motor, a second limit sensor, a second cable guide chain, a lubricating oil collection tank, and a Y-axis slide rail module. The Z-axis moving structure is slidably mounted on the Y-axis slide rail module. One end of the second lead screw module is connected to the second motor, and the second lead screw module is drivenly connected to the Z-axis moving structure. The second limit sensor is located at one end of the gantry structure, and the lubricating oil collection tank is located above the second motor.
[0012] Furthermore, the Z-axis moving structure includes a third motor, a third lead screw module, a third limit sensor, a Z-axis slide rail module, and a slider. The slider is slidably mounted on the Z-axis slide rail module. The third motor is connected to one end of the third lead screw module, and the third lead screw module is drivenly connected to the slider. The pressing module is detachably mounted on the slider, and the third limit sensor is located at one end of the Z-axis slide rail module.
[0013] Furthermore, the pressing module also includes a fixing block and a weight fixing structure. The length of the weight fixing structure extends along the X-axis direction. The top of the weight fixing structure is detachably mounted on the fixing block, and a plurality of weights are detachably mounted on the bottom of the weight fixing structure. The plurality of weights are distributed sequentially along the X-axis direction.
[0014] In summary, the technical solution of this utility model has the following beneficial effects: The structural design of this utility model is reasonable. (1) By setting a base, an X-axis moving structure and a product fixing slide are provided on the base. The X-axis moving structure includes two first X-axis slide rail modules, which are respectively set on the two sides of the base. A gantry structure is slidably connected above the two first X-axis slide rail modules. A Y-axis moving structure is provided on the gantry structure, and a Z-axis moving structure is provided on the Y-axis moving structure. The structure includes a pressing module that can move along the X, Y, and Z axes. A gantry structure can be used to move the Y-axis moving structure, the Z-axis moving structure, and the pressing module along the X-axis; the Y-axis moving structure can move the Z-axis moving structure and the pressing module along the Y-axis; and the Z-axis moving structure can move the pressing module along the Z-axis. Therefore, the pressing module can be adjusted to the desired pressing point via the X-axis and Y-axis moving structures, and then the Z-axis moving structure drives the pressing module to press the required point. (2) By setting a pressing module including detachable and replaceable weights, and setting the product fixing slide between two first X-axis slide rail modules, the weights can contact the product on the product fixing slide for testing. Thus, weights of different weights can be installed on the pressing module to transmit pressing force to the pressing point, allowing for repeated pressing of the product (e.g., display screen product) on the product fixing slide to achieve the purpose of durability testing. Furthermore, by moving the pressing module along the X, Y, and Z axes until the pressing module touches the sliding start position, and then controlling the X and Y axes to perform trajectory movement, the sliding durability test is achieved. From the above analysis, it can be seen that this utility model, by moving the pressing module along the X, Y, and Z axes and installing weights of different weights to transmit pressing force to the pressing point, can be adjusted and tested according to the size of the display screen product and the test conditions (force magnitude, point, trajectory, etc.) for different projects. Attached Figure Description
[0015] Figure 1 This is a three-dimensional structural schematic diagram of the present invention;
[0016] Figure 2 This is a three-dimensional structural diagram of the base of this utility model;
[0017] Figure 3 This is a three-dimensional structural diagram of the gantry structure of this utility model;
[0018] Figure 4 This is a three-dimensional structural diagram of the present invention when the product fixing clamp is installed;
[0019] Figure 5 This is a three-dimensional structural diagram of the present invention from another perspective when the product fixing clamp is installed;
[0020] Explanation of reference numerals in the attached drawings: base (1), X-axis moving structure (2), Y-axis moving structure (3), Z-axis moving structure (4), pressing module (5), product fixing slide (6), product fixing clamp (7); fixing panel (101), side plate (102), air vent (103), aviation interface module (104), anti-slip foot cup (105), first opening (106); first X-axis slide rail module (201), gantry structure (202), first lead screw module (203), first motor (204), first limit sensor (205), heat preservation cover (206), first cable routing tank chain (207), limit block (208); Second lead screw module (301), second motor (302), second limit sensor (303), second cable guide chain (304), lubricating oil collection tank (305), Y-axis slide rail module (306); third motor (401), third lead screw module (402), third limit sensor (403), Z-axis slide rail module (404), slider (405); fixed block (501), weight fixing structure (502), weight (503); product fixing platform (601), second X-axis slide rail module (602), second opening (603), push-pull handle (604), rotating fixing pin (605), threaded hole (606). Detailed Implementation
[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model, but this does not constitute a limitation on the scope of protection of the present utility model.
[0022] In this utility model, for clearer description, the following explanation is provided: The observer faces the attached... Figure 1 When observing, the observer above is designated as "up" and the observer below as "down." It should be noted that the terms "front end," "rear end," "left side," "right side," "middle," "above," and "below," etc., used in this document to indicate orientation or positional relationships are based on the accompanying drawings and are solely for the purpose of clearly describing this utility model. They do not indicate or imply that the structure or component referred to must have a specific orientation or be constructed in a specific orientation, and therefore should not be construed as a limitation of this utility model. Furthermore, the terms "first," "second," "third," and "fourth" are used only for the purpose of clarity or simplification of description and should not be construed as indicating or implying relative importance or quantity.
[0023] See Figures 1 to 5 This embodiment provides a tooling platform, including a base 1. The base 1 is provided with an X-axis moving structure 2 and a product fixing slide 6. The X-axis moving structure 2 includes two first X-axis slide rail modules 201, which are respectively disposed on the two side edges of the base 1. A gantry structure 202 is slidably connected above the two first X-axis slide rail modules 201. The gantry structure 202 is provided with a Y-axis moving structure 3, and the Y-axis moving structure 3 is provided with a Z-axis moving structure 4. The Z-axis moving structure 4 is provided with a pressing module 5, which can move along the X, Y, and Z axes. The pressing module 5 includes a detachable and replaceable weight 503. The product fixing slide 6 is disposed between the two first X-axis slide rail modules 201, and the weight 503 can contact the product on the product fixing slide 6 for testing. Function: (1) By setting a base, the base is provided with an X-axis moving structure and a product fixing slide. The X-axis moving structure includes two first X-axis slide rail modules. The two first X-axis slide rail modules are respectively set on the two sides of the base. A gantry structure is slidably connected above the two first X-axis slide rail modules. The gantry structure is provided with a Y-axis moving structure, the Y-axis moving structure is provided with a Z-axis moving structure, and the Z-axis moving structure is provided with a pressing module. The pressing module can move along the X, Y, and Z axes. Thus, the gantry structure can be used to move the Y-axis moving structure, the Z-axis moving structure, and the pressing module along the X-axis. The Y-axis moving structure can move the Z-axis moving structure and the pressing module along the Y-axis. The Z-axis moving structure can move the pressing module along the Z-axis. Therefore, the pressing module can be adjusted to the point to be pressed by the X-axis moving structure and the Y-axis moving structure. Then, the pressing module can be driven to press the required point by the Z-axis moving structure. (2) By setting a pressing module including detachable and replaceable weights, and setting the product fixing slide between two first X-axis slide rail modules, the weights can contact the product on the product fixing slide for testing. Thus, weights of different weights can be installed on the pressing module to transmit pressing force to the pressing point, allowing for repeated pressing of the product (e.g., display screen product) on the product fixing slide to achieve the purpose of durability testing. Furthermore, by moving the pressing module along the X, Y, and Z axes until the pressing module touches the sliding start position, and then controlling the X and Y axes to perform trajectory movement, the sliding durability test is achieved. From the above analysis, it can be seen that this utility model, by moving the pressing module along the X, Y, and Z axes and installing weights of different weights to transmit pressing force to the pressing point, can be adjusted and tested according to the size of the display screen product and the test conditions (force magnitude, point, trajectory, etc.) for different projects.
[0024] Specifically, the base 1 includes a fixed panel 101 and several side plates 102. The side plates 102 are respectively disposed on several side edges of the bottom of the fixed panel 101. Two first X-axis slide rail modules 201 are respectively disposed on the two side edges of the fixed panel 101. The product fixing slide 6 slides and engages with the fixed panel 101 along the X-axis direction. Function: The engagement of the fixed panel 101 and the several side plates 102 allows the fixed panel 101 to be supported upwards to a certain height by the side plates 102.
[0025] Specifically, the fixed panel 101 and side panels 102 are made of aluminum alloy. Ventilation holes 103 are provided on the fixed panel 101 and side panels 102. One side panel 102 has an aviation interface module 104, and the bottom of several side panels 102 has anti-slip feet 105. Function: Using high and low temperature resistant aluminum alloy, the fixed panel has ventilation holes, which reduces the overall weight and allows airflow through the structure under fluctuating temperatures, preventing condensation and freezing at low temperatures. Condensation at higher temperatures can also be drained through the ventilation holes, preventing rust. Ventilation holes (such as rectangular holes) on the side panels also serve a ventilation function. The aviation interface module 104 is preferably a three-axis aviation interface module, which can be electrically connected to an external source. The bottom is designed with four high and low temperature resistant feet with anti-slip properties to prevent movement caused by condensation during operation in high and low temperature environments.
[0026] Specifically, the product fixing slide 6 includes a product fixing platform 601. Two second X-axis slide rail modules 602 are slidably connected between the product fixing platform 601 and the fixing panel 101. A first opening 106 is provided on one edge of the fixing panel 101, and a second opening 603 is provided in the middle of the product fixing platform 601. The second opening 603 cooperates with the first opening 106, and the first opening 106 and the second opening 603 are located between the two second X-axis slide rail modules 602. Function: The product fixing platform 601 moves in the X-axis direction through the second X-axis slide rail modules 602, thereby facilitating the fixing of products of different sizes.
[0027] Specifically, a push-pull handle 604 is provided on one side edge of the product fixing platform 601, and a rotating fixing pin 605 is provided between the other side edge of the product fixing platform 601 and the fixing panel 101. Several threaded holes 606 arranged in a matrix are provided on the product fixing platform 601, which can be connected to the product fixing fixture 7. Function: The push-pull handle 604 and the rotating fixing pin 605 facilitate the pushing, pulling, and fixing of the product fixing platform 601. The product fixing platform can have a 50x50 (mm) matrix of threaded holes for connecting product fixing fixtures for different products, such as… Figure 4The image shows one example of a product fixing fixture that can simulate tilting the display screen product. Of course, other product fixing fixtures can also be used as needed.
[0028] Specifically, the X-axis moving structure 2 also includes a first lead screw module 203 and a first motor 204. The first lead screw module 203 is located above one of the first X-axis slide rail modules 201, and the first motor 204 is located below the fixed panel 101. One end of the first lead screw module 203 is connected to the top end of the first motor 204, and the first lead screw module 203 is driven by the gantry structure 202. Function: Driven by the first motor, the first lead screw module 203 drives the gantry structure 202 to move along the first X-axis slide rail module 201.
[0029] Specifically, the X-axis moving structure 2 also includes a first limit sensor 205, a heat insulation cover 206, a first cable routing tank chain 207, and a limit block 208. The first limit sensor 205 and the limit block 208 are located at opposite ends of another first X-axis slide rail module 201. The heat insulation cover 206 is located above the fixed panel 101, covering the top of the first motor 204. Function: The first limit sensor 205 serves as a safety protection device, detecting the movement position of the gantry structure 202 along the X-axis to ensure it operates within a safe range and prevent test failure. The limit block 208 limits the movement of the gantry structure 202. Preferably, the first motor 204, the first limit sensor 205, and the first lead screw module 203 are respectively a high-low temperature motor, a high-low temperature limit sensor, and a high-low temperature lead screw module. Using high-low temperature resistant motors, high-low temperature limit sensors, and high-low temperature lead screw modules is to meet environmental requirements and prevent standard components from failing due to long-term exposure to high and low temperatures.
[0030] Specifically, the Y-axis moving structure 3 includes a second lead screw module 301, a second motor 302, a second limit sensor 303, a second cable guide 304, a lubricating oil collection tank 305, and a Y-axis slide rail module 306. The Z-axis moving structure 4 is slidably mounted on the Y-axis slide rail module 306. One end of the second lead screw module 301 is connected to the second motor 302, and the second lead screw module 301 is driven by the Z-axis moving structure 4. The second limit sensor 303 is located at one end of the gantry structure 202, and the lubricating oil collection tank 305 is located above the second motor 302. Function: Driven by the second motor 302, the second lead screw module 301 drives the Z-axis moving structure 4 to move along the Y-axis slide rail module 306. The second limit sensor 303 serves as a safety protection device; its function is to detect the movement position of the Z-axis moving structure 4 along the Y-axis, ensuring its movement within a safe range and preventing test failure. As a preferred embodiment, the second motor 302, the second limit sensor 303, and the second lead screw module 301 are respectively a high-low temperature motor, a high-low temperature limit sensor, and a high-low temperature lead screw module. The use of high-low temperature resistant motors, high-low temperature limit sensors, and high-low temperature lead screw modules is to meet environmental requirements and avoid failure of standard components due to long-term exposure to high and low temperature environments.
[0031] Specifically, the Z-axis moving structure 4 includes a third motor 401, a third lead screw module 402, a third limit sensor 403, a Z-axis slide rail module 404, and a slider 405. The slider 405 is slidably mounted on the Z-axis slide rail module 404. The third motor 401 is connected to one end of the third lead screw module 402, and the third lead screw module 402 is driven by the slider 405. The pressing module 5 is detachably mounted on the slider 405. The third limit sensor 403 is located at one end of the Z-axis slide rail module 404. Function: Driven by the third motor 401, the third lead screw module 402 drives the slider 405 to move along the Z-axis slide rail module 404. The third limit sensor 403, as a safety protection device, detects the movement position of the slider 405 along the Z-axis, ensuring its movement within a safe range and preventing test failure. As a preferred embodiment, the third motor 401, the third limit sensor 403, and the third lead screw module 402 are respectively a high-low temperature motor, a high-low temperature limit sensor, and a high-low temperature lead screw module. The use of high-low temperature resistant motors, high-low temperature limit sensors, and high-low temperature lead screw modules is to meet environmental requirements and avoid failure of standard components due to long-term exposure to high and low temperature environments.
[0032] Specifically, the pressing module 5 also includes a fixing block 501 and a weight fixing structure 502. The length of the weight fixing structure 502 extends along the X-axis direction. The top of the weight fixing structure 502 is detachably mounted on the fixing block 501, and several weights 503 are detachably mounted on the bottom of the weight fixing structure 502. The several weights 503 extend along the X-axis direction and are distributed sequentially. Function: The fixing block 501 can be installed on the Z-axis moving structure 4. The arrangement of several weights 503 allows one weight 503 to work independently (similar to...). Figure 4 Multiple weights can also work together. For example, when the display product is placed horizontally, it can improve work efficiency by replacing weights of different weights with those fixed on the pressing module to achieve different pressing pressure requirements.
[0033] In summary, this technical solution, through the selection and application of high and low temperature resistant materials and the design of the mechanical structure, realizes a tooling platform that can meet the durability requirements of touch / press and slide at both normal and high / low temperatures. It can be applied to different displays and products requiring touch / press and slide testing, performing touch / press and slide durability tests under normal temperature or high / low temperature conditions. This achieves the touch / press life and slide life of products at both normal and high / low temperatures, while improving testing efficiency.
[0034] The above description is the preferred embodiment of this utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the principle of this utility model, and these improvements and modifications are also considered to be within the protection scope of this utility model.
Claims
1. A tooling platform, comprising a base (1), characterized in that: The base (1) is provided with an X-axis moving structure (2) and a product fixing slide (6). The X-axis moving structure (2) includes two first X-axis slide rail modules (201). The two first X-axis slide rail modules (201) are respectively arranged on the two sides of the base (1). A gantry structure (202) is slidably connected above the two first X-axis slide rail modules (201). The gantry structure (202) is provided with a Y-axis moving structure (3). The Y-axis moving structure (3) is provided with a Z-axis moving structure (4). The Z-axis moving structure (4) is provided with a pressing module (5). The pressing module (5) can move along the X, Y, and Z axes. The pressing module (5) includes a detachable and replaceable weight (503). The product fixing slide (6) is arranged between the two first X-axis slide rail modules (201). The weight (503) can contact the product on the product fixing slide (6) downwards for testing.
2. The tooling platform according to claim 1, characterized in that: The base (1) includes a fixed panel (101) and several side plates (102). The several side plates (102) are respectively disposed on several side edges of the bottom of the fixed panel (101). Two first X-axis slide rail modules (201) are respectively disposed on the two side edges of the fixed panel (101). The product fixing slide (6) and the fixed panel (101) slide together along the X-axis direction.
3. The tooling platform according to claim 2, characterized in that: The fixed panel (101) and the side panel (102) are made of aluminum alloy. The fixed panel (101) and the side panel (102) are provided with air vents (103). One side of the side panel (102) is provided with an aviation interface module (104). The bottom of several side panels (102) is provided with anti-slip feet (105).
4. The tooling platform according to claim 2, characterized in that: The product fixing slide (6) includes a product fixing platform (601), and two second X-axis slide rail modules (602) are slidably connected between the product fixing platform (601) and the fixing panel (101). A first opening (106) is provided on one side edge of the fixing panel (101), and a second opening (603) is provided in the middle of the product fixing platform (601). The second opening (603) cooperates with the first opening (106), and the first opening (106) and the second opening (603) are located between the two second X-axis slide rail modules (602).
5. The tooling platform according to claim 4, characterized in that: The product fixing platform (601) has a push-pull handle (604) on one side edge, and a rotating fixing pin (605) between the other side edge of the product fixing platform (601) and the fixing panel (101). The product fixing platform (601) has a number of threaded holes (606) arranged in a matrix, and the threaded holes (606) can be connected to the product fixing fixture (7).
6. The tooling platform according to claim 2, characterized in that: The X-axis moving structure (2) further includes a first lead screw module (203) and a first motor (204). The first lead screw module (203) is located above one of the first X-axis slide rail modules (201), and the first motor (204) is located below the fixed panel (101). One end of the first lead screw module (203) is connected to the top end of the first motor (204), and the first lead screw module (203) is driven to be connected to the gantry structure (202).
7. The tooling platform according to claim 6, characterized in that: The X-axis moving structure (2) also includes a first limit sensor (205), a heat insulation cover (206), a first cable routing tank chain (207), and a limit block (208). The first limit sensor (205) and the limit block (208) are located at the two ends of another first X-axis slide rail module (201). The heat insulation cover (206) is located above the fixed panel (101) and covers the top of the first motor (204).
8. The tooling platform according to any one of claims 1 to 7, characterized in that: The Y-axis moving structure (3) includes a second lead screw module (301), a second motor (302), a second limit sensor (303), a second cable track (304), a lubricating oil collection tank (305), and a Y-axis slide rail module (306). The Z-axis moving structure (4) is slidably mounted on the Y-axis slide rail module (306). One end of the second lead screw module (301) is connected to the second motor (302). The second lead screw module (301) is driven to connect with the Z-axis moving structure (4). The second limit sensor (303) is located at one end of the gantry structure (202). The lubricating oil collection tank (305) is located above the second motor (302).
9. The tooling platform according to any one of claims 1 to 7, characterized in that: The Z-axis moving structure (4) includes a third motor (401), a third lead screw module (402), a third limit sensor (403), a Z-axis slide rail module (404), and a slider (405). The slider (405) is slidably mounted on the Z-axis slide rail module (404). The third motor (401) is connected to one end of the third lead screw module (402). The third lead screw module (402) is driven to connect with the slider (405). The pressing module (5) is detachably mounted on the slider (405). The third limit sensor (403) is located at one end of the Z-axis slide rail module (404).
10. The tooling platform according to any one of claims 1 to 7, characterized in that: The pressing module (5) further includes a fixing block (501) and a weight fixing structure (502). The length of the weight fixing structure (502) extends along the X-axis direction. The top of the weight fixing structure (502) is detachably mounted on the fixing block (501). Several weights (503) are detachably mounted on the bottom of the weight fixing structure (502). The several weights (503) extend along the X-axis direction and are distributed sequentially.