CN211926936U - Multifunctional probe comprehensive test machine convenient for probe multi-attribute test - Google Patents
Multifunctional probe comprehensive test machine convenient for probe multi-attribute test Download PDFInfo
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- CN211926936U CN211926936U CN202020567176.6U CN202020567176U CN211926936U CN 211926936 U CN211926936 U CN 211926936U CN 202020567176 U CN202020567176 U CN 202020567176U CN 211926936 U CN211926936 U CN 211926936U
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Abstract
The utility model discloses a multi-functional probe comprehensive test machine convenient to test of probe multiattribute, including machine shell, Z axle motor, X axle motor and Y axle motor, the inside fixed mounting of machine shell has Z axle guide bar, be fixed with first cantilever beam and second cantilever beam on the Z axle guide bar, and on the outer wall of first cantilever beam and second cantilever beam respectively the first load sensor of fixedly connected with and second load sensor, the bottom fixedly connected with insulated column of second load sensor, and the lower extreme fixed mounting of insulated column has the test head, the X axle motor is fixed in on the base bottom plate, and the base bottom plate installs in the bottom of machine shell. The multifunctional probe comprehensive test machine convenient for the multi-attribute test of the probe facilitates the test work of different stages of the service life, elasticity and impedance of the probe, improves the efficiency of experimental test conversion, and effectively improves the number of probe tests.
Description
Technical Field
The utility model relates to a probe test technical field specifically is a multifunctional probe comprehensive test machine convenient to test of probe multiattribute.
Background
The probe testing machine is a tool product for carrying out service life pre-pressing test and elasticity and impedance test on the probe, and tests are executed through the work of a preset program, so that the testing action of the probe is directly controlled by the machine to work and use, the whole operation is convenient and fast, and meanwhile, the probe testing efficiency and the data accuracy of a testing experiment can be improved.
However, the existing probe tester has the following problems when in use:
when the service life and the elasticity and the impedance of the probe are tested, the test experiment at different stages needs to be carried out on different machines for use, the efficiency of the test conversion is low, the arrangement of the probe is easy to break, the number of the test at each time is small, and the serious use defect exists.
Aiming at the problems, innovative design is urgently needed on the basis of the original probe tester.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a multifunctional probe comprehensive testing machine convenient to test of probe multiattribute to solve above-mentioned background art and propose current probe testing machine when carrying out the life-span and elasticity and the impedance test of probe, the test experiment in different stages need carry out work use on different machines, the inefficiency of experiment test conversion, and arranging of probe is still broken up easily moreover, and the quantity of testing at every turn is also not many, has serious use defects's problem.
In order to achieve the above object, the utility model provides a following technical scheme: a multifunctional probe comprehensive test machine convenient for multi-attribute test of a probe comprises a machine shell, a Z-axis motor, an X-axis motor and a Y-axis motor, wherein a Z-axis guide rod is fixedly arranged in the machine shell, a Z-axis guide block is sleeved outside the Z-axis guide rod, the lower end of the Z-axis guide rod is fixedly provided with the Z-axis motor, a first cantilever beam and a second cantilever beam are fixed on the Z-axis guide rod, the outer walls of the first cantilever beam and the second cantilever beam are respectively and fixedly connected with a first load sensor and a second load sensor, the bottom of the first load sensor is vertically provided with a probe pressing plate, the bottom of the second load sensor is fixedly connected with an insulating column, the lower end of the insulating column is fixedly provided with a test head, the X-axis motor is fixed on a base bottom plate, the base bottom plate is arranged at the bottom of the machine shell, and the end part of the X-axis motor is connected with an X-, and X axle guide rail is installed to the avris of X axle screw rod, slidable mounting has X axle guide block on X axle screw rod and the X axle guide rail, and the top of X axle guide block is fixed with Y axle screw rod and Y axle guide rail and Y axle motor, through synchronizing wheel and hold-in range interconnect between Y axle guide rail and the Y axle motor, and the avris of Y axle guide rail is fixed with limit position switch, movable mounting has Y axle guide block on Y axle screw rod and the Y axle guide rail, and the top of Y axle guide block is fixed with the insulation board to the top fixed mounting of insulation board has probe tool, all is provided with the impedance collection wire interface on probe tool and the test head moreover, and probe tool's top fixedly connected with probe body simultaneously.
Preferably, the first cantilever beam and the second cantilever beam are arranged in parallel, and the first cantilever beam and the second cantilever beam and the machine shell are of a penetrating sliding installation structure.
Preferably, the X-axis screw and the Y-axis screw are vertically distributed, and the surfaces of the X-axis screw and the Y-axis screw are staggered with each other.
Preferably, the X-axis guide block and the Y-axis guide block are respectively in threaded connection with the X-axis screw rod and the Y-axis screw rod in a penetrating manner, and the bottom edges of the X-axis guide block and the Y-axis guide block are respectively in sliding connection with the X-axis guide rail and the Y-axis screw rod in a penetrating manner.
Preferably, the top of the Y-axis guide block is arranged to penetrate through the machine housing, and the edge side of the penetrating connection between the machine housing and the Y-axis guide block is arranged to be corrugated net-shaped.
Preferably, the probe bodies are uniformly distributed on the probe jig at equal intervals, and the probe bodies are arranged on the probe jig in a specification of 8 × 10.
Compared with the prior art, the beneficial effects of the utility model are that: the multifunctional probe comprehensive test machine convenient for the multi-attribute test of the probe facilitates the test work of different stages of the service life, elasticity and impedance of the probe, improves the efficiency of experimental test conversion, and effectively improves the number of probe tests;
1. the probes (8 × 10 — 80) of the whole plate are firstly subjected to life test at a prepressing station according to the parameters (test times, pressing stroke and pressing force) set by a program, and in the test process, the probe pressing plate can integrally and repeatedly press the needle heads of the probes according to the set displacement until the set test times are completed.
2. The probe jig after the pre-pressing test is driven by the X-axis screw to move to the position below an impedance test station of right-side elasticity (namely under the load sensor and at the position on the right side), and the impedance test of the elasticity of each probe can be translated to the position below the test head one by one through a moving platform consisting of the X-axis screw, the guide machine and the motor according to the test requirement to acquire the elasticity and the impedance data, and the probe jig and the test head are respectively connected to an impedance acquisition port through 2 leads;
3. after data acquisition is finished at the elastic impedance testing station, each probe moves leftwards to the position right below the pre-pressing testing station under the control of a program, so that a testing cycle is finished, and replacement work of different data tests is carried out.
Drawings
FIG. 1 is a front external view of the present invention;
FIG. 2 is a schematic view of the left side of the internal structure of the present invention;
FIG. 3 is a schematic view of the right side of the inner side of the present invention;
FIG. 4 is a schematic view of the internal top view structure of the present invention;
fig. 5 is an enlarged schematic view of a portion a in fig. 3 according to the present invention.
In the figure: 1. a machine housing; 2. a Z-axis guide rod; 3. a Z-axis guide block; 4. a Z-axis motor; 5. a first cantilever beam; 6. a second cantilever beam; 7. a first load sensor; 8. a second load sensor; 9. a probe pressing plate; 10. an insulating column; 11. a test head; 12. an X-axis motor; 13. a coupling; 14. an X-axis screw; 15. an X-axis guide rail; 16. an X-axis guide block; 17. a Y-axis screw; 18. a Y-axis guide rail; 19. a Y-axis motor; 20. a synchronizing wheel; 21. a synchronous belt; 22. a limit position switch; 23. a Y-axis guide block; 24. an insulating plate; 25. a probe jig; 26. an impedance acquisition lead interface; 27. a probe body; 28. a base floor.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1-5, the present invention provides a technical solution: a multifunctional probe comprehensive testing machine convenient for probe multi-attribute testing comprises a machine shell 1, a Z-axis guide rod 2, a Z-axis guide block 3, a Z-axis motor 4, a first cantilever beam 5, a second cantilever beam 6, a first load sensor 7, a second load sensor 8, a probe pressing plate 9, an insulating column 10, a testing head 11, an X-axis motor 12, a coupler 13, an X-axis screw 14, an X-axis guide rail 15, an X-axis guide block 16, a Y-axis screw 17, a Y-axis guide rail 18, a Y-axis motor 19, a synchronizing wheel 20, a synchronizing belt 21, a limit position switch 22, a Y-axis guide block 23, an insulating plate 24, a probe jig 25, an impedance acquisition lead interface 26, a probe body 27 and a base bottom plate 28, wherein the Z-axis guide rod 2 is fixedly installed inside the machine shell 1, the Z-axis guide block 3 is sleeved on the outer side of the Z-axis guide rod 2, the Z-axis motor 4 is fixedly installed at the lower end of the Z-axis guide rod 2, a first cantilever beam 5 and a second cantilever beam 6 are fixed on a Z-axis guide rod 2, a first load sensor 7 and a second load sensor 8 are respectively and fixedly connected on the outer walls of the first cantilever beam 5 and the second cantilever beam 6, a probe pressing plate 9 is vertically arranged at the bottom of the first load sensor 7, an insulating column 10 is fixedly connected at the bottom of the second load sensor 8, a test head 11 is fixedly arranged at the lower end of the insulating column 10, an X-axis motor 12 is fixed on a base bottom plate 28, the base bottom plate 28 is arranged at the bottom of a machine shell 1, the end part of the X-axis motor 12 is connected with an X-axis screw 14 through a coupling 13, an X-axis guide rail 15 is arranged at the side of the X-axis screw 14, an X-axis guide block 16 is slidably arranged on the X-axis screw 14 and the X-axis guide rail 15, and a Y-axis screw 17, a Y-axis guide rail 18 and a Y-axis motor 19 are fixed, through synchronizing wheel 20 and hold-in range 21 interconnect between Y axle guide rail 18 and the Y axle motor 19, and the avris of Y axle guide rail 18 is fixed with limit switch 22, movable mounting has Y axle guide block 23 on Y axle screw 17 and the Y axle guide rail 18, and the top of Y axle guide block 23 is fixed with insulation board 24, and insulation board 24's top fixed mounting has probe tool 25, and all be provided with impedance collection wire interface 26 on probe tool 25 and the test head 11, probe tool 25's top fixedly connected with probe body 27 simultaneously.
The X-axis screw 14 and the Y-axis screw 17 are vertically distributed, the surfaces of the X-axis screw 14 and the Y-axis screw 17 are staggered, the X-axis guide block 16 and the Y-axis guide block 23 are in threaded connection with the X-axis screw 14 and the Y-axis screw 17 respectively, the bottom edges of the X-axis guide block 16 and the Y-axis guide block 23 are in penetrating sliding connection with the X-axis guide rail 15 and the Y-axis screw 17 respectively, the top of the Y-axis guide block 23 and the machine shell 1 are arranged in a penetrating mode, the sides of penetrating connection positions of the machine shell 1 and the Y-axis guide block 23 are arranged in a corrugated net shape, and the position of the probe is convenient to move, change and change, so that the probe is subjected to service life prepressing, quick conversion between elasticity and impedance is performed, conversion efficiency is improved, and detection and testing of different attribute works is facilitated.
The probe bodies 27 are uniformly distributed on the probe jig 25 at equal intervals, and the probe bodies 27 are arranged on the probe jig 25 in an 8 × 10 specification, so that service life prepressing, elastic force and impedance work of a large number of probes is performed, and the number and efficiency of tests are improved.
The working principle is as follows: when the multifunctional probe comprehensive test machine convenient for multi-attribute test of the probe is used, firstly, as shown in fig. 1, a 7-inch touch screen, an emergency stop button, a 17-inch liquid crystal display, an operation indicator lamp, a start button, a rocker controller, a shock absorption foot cup, a control panel, a keyboard and the like are fixedly installed on a machine shell 1, a storage drawer and a terminal panel are arranged on the side of the machine shell, all actions during the test can be executed according to the action preset by a program, a table is automatically generated, manual intervention is not needed, and the test efficiency of the probe and the accuracy of data are greatly improved;
according to the fig. 1-5, under the action of the operation start of the X-axis motor 12 and the Y-axis motor 19, the X-axis guide block 16 and the Y-axis guide block 23 can be moved and changed, the insulating plate 24 and the probe jig 25 on the Y-axis guide block 23 can be adjusted to be moved and changed, under the action of the probe body 27 on the probe jig 25, the probe performs different data tests on the probe pressing plate 9 and the test head 11 below different first load sensors 7 and second load sensors 8, performs large-batch rapid tests of service life, elasticity and impedance work, improves the test efficiency, and the work starting of the Z-axis motor 4 can drive the Z-axis guide rod 2 to rotate, so that the heights of the positions of the first cantilever beam 5 and the second cantilever beam 6 on the Z-axis guide rod 2 are changed, and different data tests of the probe are completed.
Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.
Claims (6)
1. The utility model provides a multi-functional probe comprehensive test machine convenient to test of probe multiattribute, includes machine housing (1), Z axle motor (4), X axle motor (12) and Y axle motor (19), its characterized in that: the machine is characterized in that a Z-axis guide rod (2) is fixedly installed inside the machine shell (1), a Z-axis guide block (3) is sleeved outside the Z-axis guide rod (2), a Z-axis motor (4) is fixedly installed at the lower end of the Z-axis guide rod (2), a first cantilever beam (5) and a second cantilever beam (6) are fixed on the Z-axis guide rod (2), a first load sensor (7) and a second load sensor (8) are fixedly connected to the outer walls of the first cantilever beam (5) and the second cantilever beam (6) respectively, a probe pressing plate (9) is vertically installed at the bottom of the first load sensor (7), an insulating column (10) is fixedly connected to the bottom of the second load sensor (8), a testing head (11) is fixedly installed at the lower end of the insulating column (10), and the X-axis motor (12) is fixed on a base bottom plate (28), and the base bottom plate (28) is installed at the bottom of the machine shell (1), and the end part of the X-axis motor (12) is connected with an X-axis screw (14) through a coupler (13), and an X-axis guide rail (15) is installed at the side of the X-axis screw (14), an X-axis guide block (16) is installed on the X-axis screw (14) and the X-axis guide rail (15) in a sliding manner, a Y-axis screw (17), a Y-axis guide rail (18) and a Y-axis motor (19) are fixed at the top of the X-axis guide block (16), the Y-axis guide rail (18) and the Y-axis motor (19) are connected with each other through a synchronizing wheel (20) and a synchronizing belt (21), a limit position switch (22) is fixed at the side of the Y-axis guide rail (18), a Y-axis guide block (23) is movably installed on the Y-axis screw (17) and the Y-axis guide rail (18), and an insulating plate (24) is, and the top fixed mounting of insulation board (24) has probe tool (25), all is provided with impedance collection wire interface (26) moreover on probe tool (25) and test head (11), and the top fixedly connected with probe body (27) of probe tool (25) simultaneously.
2. The multifunctional probe comprehensive testing machine facilitating multi-attribute testing of probes as claimed in claim 1, wherein: the first cantilever beam (5) and the second cantilever beam (6) are arranged in parallel, and the first cantilever beam (5) and the second cantilever beam (6) and the machine shell (1) are of a penetrating sliding installation structure.
3. The multifunctional probe comprehensive testing machine facilitating multi-attribute testing of probes as claimed in claim 1, wherein: the X-axis screw (14) and the Y-axis screw (17) are vertically distributed, and the surfaces of the X-axis screw (14) and the Y-axis screw (17) are staggered.
4. The multifunctional probe comprehensive testing machine facilitating multi-attribute testing of probes as claimed in claim 1, wherein: the X-axis guide block (16) and the Y-axis guide block (23) are respectively in threaded connection with the X-axis screw (14) and the Y-axis screw (17) in a penetrating mode, and the bottom edges of the X-axis guide block (16) and the Y-axis guide block (23) are respectively in sliding connection with the X-axis guide rail (15) and the Y-axis screw (17) in a penetrating mode.
5. The multifunctional probe comprehensive testing machine facilitating multi-attribute testing of probes as claimed in claim 1, wherein: the top of the Y-axis guide block (23) and the machine shell (1) are arranged in a penetrating mode, and the edge side of the penetrating connection position of the machine shell (1) and the Y-axis guide block (23) is arranged to be corrugated net-shaped.
6. The multifunctional probe comprehensive testing machine facilitating multi-attribute testing of probes as claimed in claim 1, wherein: the probe bodies (27) are uniformly distributed on the probe jig (25) at equal intervals, and the probe bodies (27) are arranged on the probe jig (25) in an 8 x 10 specification.
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CN202020567176.6U CN211926936U (en) | 2020-04-16 | 2020-04-16 | Multifunctional probe comprehensive test machine convenient for probe multi-attribute test |
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CN202020567176.6U CN211926936U (en) | 2020-04-16 | 2020-04-16 | Multifunctional probe comprehensive test machine convenient for probe multi-attribute test |
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CN202020567176.6U Expired - Fee Related CN211926936U (en) | 2020-04-16 | 2020-04-16 | Multifunctional probe comprehensive test machine convenient for probe multi-attribute test |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112903022A (en) * | 2021-02-04 | 2021-06-04 | 上海泽丰半导体科技有限公司 | Probe test system, operation method and detection method thereof |
CN114608653A (en) * | 2022-03-09 | 2022-06-10 | 丹东富田精工机械有限公司 | Automatic performance detection device for spring probe |
CN115219750A (en) * | 2022-07-07 | 2022-10-21 | 深圳市斯纳达科技有限公司 | Three-dimensional electric probe base with force feedback |
-
2020
- 2020-04-16 CN CN202020567176.6U patent/CN211926936U/en not_active Expired - Fee Related
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112903022A (en) * | 2021-02-04 | 2021-06-04 | 上海泽丰半导体科技有限公司 | Probe test system, operation method and detection method thereof |
CN114608653A (en) * | 2022-03-09 | 2022-06-10 | 丹东富田精工机械有限公司 | Automatic performance detection device for spring probe |
CN114608653B (en) * | 2022-03-09 | 2022-09-20 | 丹东富田精工机械有限公司 | Automatic performance detection device for spring probe |
CN115219750A (en) * | 2022-07-07 | 2022-10-21 | 深圳市斯纳达科技有限公司 | Three-dimensional electric probe base with force feedback |
CN115219750B (en) * | 2022-07-07 | 2024-06-07 | 深圳市斯纳达科技有限公司 | Three-dimensional electric probe seat with force feedback |
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Granted publication date: 20201113 |