CN213072805U - Test platform - Google Patents

Test platform Download PDF

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Publication number
CN213072805U
CN213072805U CN202022457755.8U CN202022457755U CN213072805U CN 213072805 U CN213072805 U CN 213072805U CN 202022457755 U CN202022457755 U CN 202022457755U CN 213072805 U CN213072805 U CN 213072805U
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test
telephone
test platform
platform
telescopic
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CN202022457755.8U
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Chinese (zh)
Inventor
李威
张兆鹏
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Beijing Fanhua Hengxing Technology Co ltd
Beijing Zhongke Pansino Measurement & Control Co ltd
Original Assignee
Beijing Fanhua Hengxing Technology Co ltd
Beijing Zhongke Pansino Measurement & Control Co ltd
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Application filed by Beijing Fanhua Hengxing Technology Co ltd, Beijing Zhongke Pansino Measurement & Control Co ltd filed Critical Beijing Fanhua Hengxing Technology Co ltd
Priority to CN202022457755.8U priority Critical patent/CN213072805U/en
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Abstract

The utility model relates to a this application provides a test platform, test platform is used for detecting the telephone, including detecting the platform, establish the first testboard on detecting the platform, establish the fixing base that is used for fixed telephone on the first testboard, establish the second testboard on detecting the platform, establish the first test jig on the second testboard, establish the first telescopic link that is used for pressing the control area on the telephone on the first test jig, establish the second test jig on detecting platform or second testboard, establish the optic fibre on the second test jig and be used for controlling first telescopic link and receive the feedback of optic fibre, analysis telephone is last control area and is instructed the lamp and can normally work analytic system. The telephone is tested in an automatic detection mode, and the telephone is tested more comprehensively.

Description

Test platform
Technical Field
The application relates to the technical field of detection, in particular to a test platform.
Background
The telephone is a telephone capable of providing microphone signal input and sound box signal output, and can provide a solution for two-way call, and because the telephone is often used in a conference scene, higher requirements are also made in terms of reliability and the like.
Disclosure of Invention
The application provides a test platform, through automatic detection mode, help carrying out more comprehensive test to the telephone.
The above object of the present application is achieved by the following technical solutions:
in a first aspect, the present application provides a test platform for testing a telephone, comprising:
a detection table;
the first test bench is arranged on the test bench;
the fixed seat is arranged on the first test board and used for fixing the telephone;
the second test bench is arranged on the test bench;
the first test frame is arranged on the second test board;
one or more first telescopic rods arranged on the first test rack and used for pressing a control area on the telephone;
the second test frame is arranged on the test bench or the second test bench;
the optical fiber is arranged on the second test rack and used for collecting the working state information of the indicator lamp on the telephone; and
and the analysis system is used for controlling the first telescopic rod, receiving feedback of the optical fiber and analyzing whether a control area and an indicator lamp on the telephone can work normally or not.
Through adopting above-mentioned technical scheme, place the telephone back on the fixing base, press the control area on the telephone through first telescopic link, then gather the operating condition of pilot lamp through optic fibre, this kind of test mode is automatic going on, can simulate various use scenes, and is more comprehensive to the test of telephone.
In a possible implementation manner of the first aspect, a positioning block for assisting a fixed telephone set is arranged on the fixed base.
By adopting the technical scheme, the telephone can be quickly positioned, and the telephone is favorable for avoiding the deviation of the test result caused by the displacement of the telephone in the test process.
In a possible implementation manner of the first aspect, a sensor is provided on the holder, and the sensor is configured to detect whether the telephone is in contact with the holder.
By adopting the technical scheme, whether the telephone is laid flat or not can be detected in an active detection mode, and the accuracy of a test result is improved.
In a possible implementation manner of the first aspect, the second testing jig includes a support provided on the testing table or the second testing table, a telescopic device provided on the support, and a fixing block provided on the telescopic device;
the optical fiber is arranged on the fixed block;
the telescopic device can push the fixed block to move towards the direction close to or away from the fixed seat corresponding to the fixed block.
By adopting the technical scheme, the position of the optical fiber can be adjusted according to the telephone, and the use scene is richer.
In a possible implementation manner of the first aspect, the method further includes: the telescopic device is connected with the analysis system and can perform corresponding actions according to instructions issued by the analysis system.
By adopting the technical scheme, the telescopic device can be telescopic under the control of the analysis system, and the automation degree is higher.
In a possible implementation manner of the first aspect, the method further includes:
the first mobile module is arranged on the second test board;
the cantilever is arranged on the first moving module and can move under the driving of the first moving module;
the second moving module is arranged on the cantilever;
the first connecting frame is arranged on the second moving module; and
the second telescopic rod is arranged on the first connecting frame;
the first mobile module and the second mobile module are configured to perform data interaction with the analysis system, so that the second telescopic rod can cover a detection area on the telephone.
By adopting the technical scheme, the detection area on the telephone can be tested, and the comprehensiveness of the test can be further improved.
In a possible implementation manner of the first aspect, the test device further includes an image acquisition device disposed on the second test board; the image acquisition device is configured to acquire display content on the detection area covered by the second telescopic rod.
By adopting the technical scheme, the display content on the detection area is acquired by the image acquisition device, the acquired display content can be used for subsequent analysis, and the automation degree is higher.
In a possible implementation manner of the first aspect, the image acquisition device includes a second connection frame disposed on the second test board, an adjustment frame disposed on the second connection frame, and a camera disposed on the adjustment frame;
the adjusting frame is configured to adjust the angle between the camera and a detection area which can be covered by the second telescopic rod on the telephone.
By adopting the technical scheme, the posture of the camera can be adjusted by the adjusting frame so as to meet the use requirements under different scenes.
In a possible implementation manner of the first aspect, the first test platform is rotatably connected to the test platform;
two sides of the rotary connection part of the first test platform and the detection platform are respectively provided with a sliding rail, and the sliding rails are fixed on the first test platform or the detection platform;
the slide rail is provided with the slider, and the slider can slide to first testboard and examine between the test table, adjusts the levelness of first testboard.
By adopting the technical scheme, the levelness of the first test board can be adjusted through the sliding block, so that the telephone placed on the fixed seat can complete the test under the environment meeting the levelness requirement.
Drawings
Fig. 1 is a schematic perspective view of a test platform according to an embodiment of the present application.
Fig. 2 is a schematic perspective view of a testing platform added with a telephone set on the basis of fig. 1.
Fig. 3 is an enlarged schematic view of a portion a in fig. 1.
Fig. 4 is an enlarged schematic view of a portion a in fig. 2.
Fig. 5 is a schematic perspective view showing a first moving module, a second moving module, and the like based on fig. 1.
Fig. 6 is a schematic perspective view showing the sliding module according to fig. 1.
Fig. 7 is a block diagram schematically illustrating a structure of an analysis system according to an embodiment of the present application.
Fig. 8 is a block diagram schematically illustrating a structure of another analysis system provided in an embodiment of the present application.
In the figure, 11, a detection table, 12, a first test table, 13, a fixed base, 14, a second test table, 15, a first test rack, 16, a first telescopic rod, 17, a second test rack, 18, an optical fiber, 19, an analysis system, 131, a positioning block, 132, a sensor, 171, a bracket, 172, a telescopic device, 173, a fixed block, 21, a first moving module, 22, a cantilever, 23, a second moving module, 24, a first connecting rack, 25, a second telescopic rod, 26, an image acquisition device, 27, a sliding module, 261, a second connecting rack, 262, an adjusting rack, 263, a camera, 31, a sliding rail, 32, a sliding block, 191, a CPU, 192, a RAM, 193, a ROM, 194, a system bus, 195, a first external connection circuit, 196, a second external connection circuit, 197, a sensing starter, 198, a module driver, 199, and an image driver.
Detailed Description
The technical solution of the present application will be described in further detail below with reference to the accompanying drawings.
Firstly, simply introducing a test of a telephone, wherein the test of the telephone is mainly divided into an audio test and a control test, the audio test mainly comprises an input/output test, a noise test, a load test and the like, and the purpose is to detect the sound collection and play function of the telephone and to determine whether the use requirement of a teleconference can be met; the control test mainly tests various control keys (physical keys or touch keys) and indicator lights and the like on the telephone, and is used for detecting whether the control keys can work normally or not and whether the control keys can work normally under different use environments or not.
It should be understood that the teleconference is a highly demanding usage scenario, which requires the telephone to work normally in different usage scenarios, and therefore, for the test, a plurality of usage scenarios are simulated or repeated for many times, so that a potential problem can be found.
If manual testing is used, the stability and consistency of the testing result are difficult to guarantee, on one hand, manual operation has great subjectivity, whether all testing contents can be completed cannot be guaranteed, on the other hand, different people can have different judgment standards for judging the testing result, and the consistency of the result cannot be guaranteed.
The embodiment of the application discloses a test platform, which can test the performance of a telephone through an automatic test mode, can ensure the consistency of a test process and the consistency of a test result.
Referring to fig. 1 and 2, a telephone is added in fig. 2, and the test platform disclosed in the embodiment of the present application is mainly composed of a main body part, a touch part, a signal feedback part, and an analysis part, wherein the main body part includes a test platform 11, a first test platform 12, and a second test platform 14, the first test platform 12 and the second test platform 14 are both installed on the test platform 11, the first test platform 12 is used for placing a telephone to be tested, and the second test platform 14 is used for installing a first test rack 15.
The touch part mainly comprises a first test frame 15 and a first telescopic rod 16 arranged on the first test frame 15, wherein the number of the first test frames 15 and the number of the first telescopic rods 16 are determined according to the telephone to be tested. Taking a triangle telephone as an example, the number of the first testing jig 15 is three, and each first testing jig 15 is responsible for testing one corner of the triangle telephone.
The number of the first telescopic rods 16 on the first test frame 15 is at least the same as that of the control areas on one corner of the triangular telephone, and for the control areas, it can be understood that during the use process of the telephone, various physical keys or virtual keys are needed to be used for controlling so as to call functions needed to be used, and the physical keys or the virtual keys are the control areas of the telephone.
Therefore, if the number of the control areas on one corner of the triangular telephone is three, the number of the first telescopic rods 16 on one first test frame 15 is at least three, and the first telescopic rods 16 can simulate human operation in the process of extension and retraction, the operation is performed according to instructions, all actions can be executed according to a set sequence, the pressing consistency can be ensured, and the problems that the triggering cannot be caused due to insufficient pressing force or the triggering can be successfully carried out due to slightly larger pressing force but the defects exist substantially and the like can be avoided to a certain extent.
The first testing platform 12 is provided with a fixing seat 13, and the fixing seat 13 is used for fixing the telephone to prevent the telephone from moving in the testing process.
It should be understood that, during the test process, the first telescopic rod 16 presses the control area on the telephone, which may cause the telephone to shift, cause the test result to be inaccurate, and even cause an interruption, the fixing seat 13 is used to fix the telephone at a position during the test process, so that the test process can be performed smoothly.
The number of the fixing seats 13 also needs to be determined according to the telephone, for example, for a triangle telephone, three fixing seats 13 may be used to fix three corners of the triangle telephone, and of course, other numbers of fixing seats 13 may be used to fix the triangle telephone.
The second testing jig 17 is disposed on the testing station 11 or the second testing station 14, and is used for providing a working environment for the optical fiber 18, and similarly, the number of the second testing jigs 17 is determined according to the telephone, which has already been stated above, and is not described herein again.
The core of the signal feedback part is an optical fiber 18, and referring to fig. 1 and 4, the optical fiber 18 is mounted on a second test rack 17 and is used for collecting the working state information of the indicator light on the telephone, such as whether the indicator light can be turned on, brightness, color, saturation, and the like.
It should be understood that when the corresponding control area on the telephone is pressed, the corresponding indicator light is also turned on, and the indicator light cannot be turned on to indicate that the indicator light cannot work normally.
When the indicator lamp on the telephone is lighted, the light emitted by the indicator lamp can be collected by the optical fiber 18, the actual condition of the corresponding indicator lamp can be obtained by analyzing the collected light, and the analysis is performed based on the same standard and has consistency.
The core of the analysis part is an analysis system 19, the analysis system 19 is used for controlling the first telescopic rod 16 to act according to instructions stored in the analysis system 19, a control area on the telephone is pressed, an indicator light corresponding to the control area works when the control area is pressed, and the optical fiber 18 collects light emitted by the indicator light when the indicator light works and then transmits the light to the analysis system 19 for testing the performance of the telephone.
In the testing process, all the first telescopic rods 16 can work according to the set rules, various operations under different application scenes and different use environments are simulated, the testing process is automatically carried out, the automation degree is high, and the testing result is more accurate.
On the whole, the test platform disclosed in the embodiment of the application can automatically test the telephone, can be completely carried out according to test contents in the test process, and can more accurately feed back the performance of the telephone because the pressing of the control area and the detection of the indicator light are carried out based on the same standard.
As a specific embodiment of the testing platform provided by the application, please refer to fig. 1 and fig. 2, a positioning block 131 is added on the fixing base 13, and the positioning block 131 is used to assist in fixing the telephone, so as to further reduce the displacement of the telephone during the detection process.
It should be understood that, in the detection process, the first telescopic rod 16 can simulate various working conditions, which aggravates the tendency of movement of the telephone, and leads to the occurrence of potential uncontrollable factors, and after the positioning block 131 is added, the displacement of the telephone can be further reduced, so that the detection result is more accurate.
Taking a triangular telephone as an example, the number of the fixing seats 13 may be three, so as to fix three corners of the triangular telephone respectively, and two positioning blocks 131 may be added to each fixing seat 13, where the two positioning blocks 131 are respectively located at two sides of one corner of the triangular telephone, so as to limit the triangular telephone from two sides, thereby preventing the triangular telephone from being displaced in the testing process.
Further, referring to fig. 3, a sensor 132 is added to the fixing base 13, the sensor 132 is used for detecting whether the telephone is in contact with the fixing base 13, and in some possible implementations, one sensor 132 is installed on each fixing base 13.
It will be appreciated that the telephone may be flat if viewed purely visually when placed on the mounting base 13, but in practice the telephone is in a tilted position which may lead to deviations in the final test results, for example the first telescopic rod 16, although in contact with the control area, cannot be actually pressed or the pressing deviates so far that the control area cannot be triggered.
Therefore, it is necessary to detect whether the phone is in contact with the holder 13 by the sensor 132, and after the phone is in contact with the holder 13, the sensor 132 on the holder 13 is triggered, for example, the number of the holders 13 is three, so that when all three sensors 132 are triggered, it can be said that the phone is in contact with the holder 13.
For the feedback form of the sensor 132, there may be several:
first, each sensor 132 is provided with an indicator light, and the indicator light is turned on after the sensor 132 is triggered, so that whether the telephone is in contact with all the holders 13 can be known by observing the number of turned-on indicator lights during the placement of the telephone.
Secondly, the sensor 132 is connected to the analysis system 19, and when the sensor 132 is triggered, a signal is fed back to the analysis system 19, and the analysis system 19 can determine whether the telephone is in contact with all the fixed seats 13 by calculating the number of the fed-back signals.
Referring to fig. 1 and 2, the second testing jig 17 is composed of a bracket 171, a telescopic device 172 and a fixing block 173, wherein the bracket 171 is fixedly installed on the testing platform 11 or the second testing platform 14, the telescopic device 172 is installed on the bracket 171, and the fixing block 173 is installed on the telescopic device 172
The second testing jig 17 is adjustable, and the extension device 172 can push the fixing block 173 to move toward or away from the corresponding fixing base 13. Referring to fig. 3, the optical fiber 18 is fixed on the fixing block 173 and can move along with the movement of the fixing block 173, so that when the specification or model of the telephone is changed, the position of the optical fiber 18 can be adjusted by the telescopic device 172, or after the telephone is used for a period of time, the position of the optical fiber 18 can be adjusted by the telescopic device 172, so that the optical fiber can always accurately feed back a signal to the analysis system 19.
It should be understood that there are differences between phones of the same model, which may affect the accuracy of the test results, and therefore, it is also meaningful to perform fine tuning for different phones.
Further, the telescopic device 172 is connected to the analysis system 19, and can perform corresponding actions according to instructions issued by the analysis system 19, so that for different telephones, after the corresponding side test content is selected in the analysis system 19, the telescopic device 172 can move the optical fiber 18 to a proper position according to the test content.
Of course, the extension device 172 may be manually adjusted, for example, using an adjustment button, and the adjustment button controls the movement of the extension device 172 to move the optical fiber 18 to a desired position during the test.
It should be understood that some existing telephone sets are additionally provided with a touch screen besides physical keys for performing human-computer interaction, corresponding tests are also required to be performed on the touch screen, and for convenience of description, an area on the touch screen which can be used for human-computer interaction is referred to as a detection area.
As a specific embodiment of the test platform provided by the application, please refer to fig. 1 and 5, a part for detecting the detection area on the telephone is added, the part mainly comprises a first moving module 21, a cantilever 22, a second moving module 23, a first connecting frame 24, a second telescopic rod 25, and the like, and the working directions of the first moving module 21 and the second moving module 23 are not the same, so that one area can be covered, and the above mentioned detection area is also included.
The first moving module 21 is installed on the second test station 14, on which a cantilever 22 is installed, and the second moving module 23 is installed on the cantilever 22 to be capable of moving along with the movement of the cantilever 22. The first link 24 is mounted on the arm 22 and is movable with the movement of the first moving module 21 and the movement of the second moving module 23. The second telescopic rod 25 is attached to the first link frame 24 and can move in accordance with the movement of the first link frame 24.
The moving direction of the first moving module 21 and the moving direction of the second moving module 23 are different, and if the moving area of the second telescopic rod 25 is taken as a reference, the moving area is a parallelogram, and when the moving direction of the first moving module 21 is perpendicular to the moving direction of the second moving module 23, the moving area is a rectangle.
The second telescopic rod 25 is movable along with the first link 24 and is also extendable and retractable, that is, the second telescopic rod 25 is movable along a specific trajectory in addition to being able to click in the detection area.
It should be understood that, in an actual use process, besides the click operation, a sliding operation may be performed on the touch screen, and if a track of the click operation is regarded as a point, a track of the sliding operation is a line.
The second telescopic link 25 can carry out the click operation, can also slide under the drive of first removal module 21 and second removal module 23, can carry out comprehensive test to the touch-control screen.
In some possible implementations, the first movement module 21 uses a ball screw linear module.
In some possible implementations, the second movement module 23 uses a ball screw linear module.
It should be understood that, referring to fig. 6, a sliding module 27 may be added to the other end of the cantilever 22, and the sliding module 27 also serves to support the cantilever 22.
As a specific embodiment of the test platform provided by the application, please refer to fig. 1 and fig. 2, an image acquisition device 26 is added on the second test platform 14, the image acquisition device 26 is used for acquiring display contents on the detection area, specifically, the display contents on the detection area are feedback to the action of the second telescopic rod 25, if the detection area can work normally, the display contents on the detection area should be consistent with the stored contents, the two contents are compared, whether the detection area can work normally can be analyzed, if the feedback is consistent with the setting, it is indicated that the detection area can work normally, and otherwise, the detection area cannot work normally.
In some possible implementations, the image capturing device 26 is composed of a camera 263, and the camera 263 may be fixedly installed on the second testing platform 14, or may be installed at other positions as long as the display content of the testing area can be obtained.
The camera 263 faces the detection area, collects the content displayed thereon, and then performs feedback, where the feedback object may be an upper computer, and of course, may be the analysis system 19.
In other possible implementations, the image capturing device 26 is composed of a second connecting frame 261, an adjusting frame 262 and a camera 263, the second connecting frame 261 is fixedly installed on the second testing platform 14, the adjusting frame 262 is fixedly installed on the second connecting frame 261, and the camera 263 is installed on the adjusting frame 262.
The adjusting frame 262 is composed of a fixed part and a movable part, the fixed part is connected with the second connecting frame 261, the movable part is connected with the camera 263, the camera 263 can rotate, and for telephones of different models or specifications, the required content can be acquired by adjusting the posture of the camera 263.
From another perspective, the angle between the camera 263 and a detection area of the telephone that can be covered by the second telescopic rod 25 can be adjusted, and the camera 263 and the detection area can be made to be as perpendicular as possible by means of adjustment.
As a specific embodiment of the testing platform provided by the application, the first testing platform 12 is rotatably connected to the testing platform 11, that is, the first testing platform 12 is rotatable and can be adjusted as required.
What provides the support for first testboard 12 is slide rail 31 and slider 32, and slide rail 31 is located and examines between testboard 11 and the first testboard 12, and the quantity is two, is located the both sides of examining the junction of testboard 11 and first testboard 12 respectively.
All be provided with slider 32 on every slide rail 31, slider 32 can slide on slide rail 31, and can slide to first testboard 12 and examine between the test bench 11, adjusts the levelness of first testboard 12.
It should be understood that the relative position between the testing table 11 and the first testing table 12 may vary during a long period of use, and when the variation is large enough, the accuracy of the testing result may be affected, so that the relative position between the testing table 11 and the first testing table 12 needs to be adjusted to be within the allowable range.
It should be understood that the first and second telescoping rods 16 and 25 described above can be used with either a start telescoping rod or an electric telescoping rod.
It should be understood that the sensor 132 may be a push type sensor, and that the trigger action is achieved by moving a push button after the telephone contacts the push button on the depressor.
It should be understood that referring to fig. 7 and 8, the analysis system 19 referred to above may be a CPU, microprocessor, ASIC, or one or more integrated circuits for controlling the execution of the programs described above. The analysis system 19 mainly includes a CPU191, a RAM192, a ROM193, and a system bus 194, wherein the CPU191, the RAM192, and the ROM193 are connected to the system bus 194.
When the first telescopic rod 16 and the second telescopic rod 25 are electric rods, the control circuits of the first telescopic rod 16 and the second telescopic rod 25 are connected to the system bus 194 through the first peripheral connecting circuit 195, and when the first telescopic rod 16 and the second telescopic rod 25 are pneumatic rods, the control gas circuits of the first telescopic rod 16 and the second telescopic rod 25 are connected to the system bus 194 through the second peripheral connecting circuit 196.
The sensors 132 may be coupled to the system bus 194 via sensor actuators 197.
The first moving module 21 and the second moving module 23 may be connected to the system bus 194 through a module driver 198.
Image capture device 26 may be coupled to system bus 194 via an image driver 199.
The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. A test platform for testing a telephone, comprising:
a detection table (11);
the first test bench (12) is arranged on the test bench (11);
the fixed seat (13) is arranged on the first test bench (12) and used for fixing the telephone;
the second test bench (14) is arranged on the test bench (11);
the first test frame (15) is arranged on the second test bench (14);
one or more first telescopic rods (16) arranged on the first test rack (15) and used for pressing a control area on the telephone;
the second test frame (17) is arranged on the test platform (11) or the second test platform (14);
the optical fiber (18) is arranged on the second test rack (17) and is used for collecting the working state information of the indicator lamp on the telephone; and
and the analysis system (19) is used for controlling the first telescopic rod (16) and receiving feedback of the optical fiber (18) to analyze whether a control area and an indicator lamp on the telephone can work normally or not.
2. A test platform according to claim 1, wherein the mounting base (13) is provided with a positioning block (131) for assisting in mounting the telephone.
3. A test platform according to claim 1 or 2, characterised in that the holder (13) is provided with a sensor (132), the sensor (132) being arranged to detect whether the telephone is in contact with the holder (13).
4. A test platform according to claim 1, characterized in that the second test rack (17) comprises a support (171) arranged on the test table (11) or the second test table (14), a telescopic device (172) arranged on the support (171), and a fixed block (173) arranged on the telescopic device (172);
the optical fiber (18) is arranged on the fixed block (173);
the telescopic device (172) can push the fixed block (173) to move towards or away from the corresponding fixed seat (13).
5. A test platform according to claim 4, further comprising: the telescopic device (172) is connected with the analysis system (19) and can perform corresponding actions according to instructions issued by the analysis system (19).
6. A test platform according to claim 4, further comprising:
a first moving module (21) arranged on the second test bench (14);
the cantilever (22) is arranged on the first moving module (21) and can move under the driving of the first moving module (21);
a second moving module (23) arranged on the cantilever (22);
a first connecting frame (24) arranged on the second moving module (23); and
a second telescopic rod (25) arranged on the first connecting frame (24);
the first mobile module (21) and the second mobile module (23) are configured to interact with the analysis system (19) in such a way that the second telescopic bar (25) is able to cover a detection area on the telephone.
7. A test platform according to claim 6, further comprising image capturing means (26) provided on the second test station (14); the image acquisition device (26) is configured to acquire display content on a detection area covered by the second telescopic rod (25).
8. A test platform according to claim 7, wherein the image capturing device (26) comprises a second connecting frame (261) arranged on the second test platform (14), an adjusting frame (262) arranged on the second connecting frame (261), and a camera (263) arranged on the adjusting frame (262);
the adjusting frame (262) is configured to adjust the angle between the camera (263) and a detection area which can be covered by the second telescopic rod (25) on the telephone.
9. A test platform according to claim 1, characterized in that said first test station (12) is rotatably connected to said test station (11);
two sides of the rotary connection part of the first test platform (12) and the detection platform (11) are respectively provided with a sliding rail (31), and the sliding rails (31) are fixed on the first test platform (12) or the detection platform (11);
the sliding rail (31) is provided with a sliding block (32), and the sliding block (32) can slide between the first test platform (12) and the test platform (11) to adjust the levelness of the first test platform (12).
CN202022457755.8U 2020-10-29 2020-10-29 Test platform Active CN213072805U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202022457755.8U CN213072805U (en) 2020-10-29 2020-10-29 Test platform

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202022457755.8U CN213072805U (en) 2020-10-29 2020-10-29 Test platform

Publications (1)

Publication Number Publication Date
CN213072805U true CN213072805U (en) 2021-04-27

Family

ID=75563382

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202022457755.8U Active CN213072805U (en) 2020-10-29 2020-10-29 Test platform

Country Status (1)

Country Link
CN (1) CN213072805U (en)

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