CN117782553A - Rotary buckle life testing device, life testing method and electronic equipment - Google Patents

Abstract

The application relates to a rotary buckle life testing device, a life testing method and electronic equipment, and belongs to the technical field of instrument life testing. This rotatory life-span testing arrangement that detains includes the workstation, the cylinder, coupling mechanism, drive mechanism, detection mechanism and control mechanism, be equipped with the mount on the workstation, the mount is used for fixed lens that awaits measuring, rotatory knot is installed in the lens that awaits measuring, the cylinder, detection mechanism all with control mechanism signal connection, the cylinder includes first cylinder and second cylinder, detection mechanism includes pressure sensor and travel sensor, can detect drive mechanism's motion parameter respectively, control the cylinder operation through control mechanism, the cylinder drives the drive mechanism operation, and judge the life-span of rotatory knot according to the motion parameter of detection mechanism feedback. The rotary buckle life testing device can replace manual rotary buckle life testing, automatic testing is achieved, testing labor cost and testing errors are reduced, and testing efficiency and accuracy are improved.

Description

Rotary buckle life testing device, life testing method and electronic equipment

Technical Field

The application relates to the technical field of instrument life test, in particular to a life test device and a life test method for a rotary buckle and electronic equipment.

Background

With the development of technology, medical endoscopes are increasingly applied to diagnosis and treatment of diseases. The medical endoscope is provided with an endoscope head which extends into the human body and plays roles of guiding surgical instruments, shooting and the like.

The endoscope head comprises an endoscope eye and an endoscope eye mounting seat, the disassembly and assembly operations of the endoscope eye and the endoscope eye mounting seat are frequent in the actual operation process, and the general connection of the endoscope eye and the endoscope eye mounting seat is fixed into a quick-disassembly structure. The endoscope mesh installation seat comprises an installation seat body, a rotary buckle and an endoscope mesh claw, the installation seat body seat is driven to rotate by pressing the rotary buckle, the inner diameter of the endoscope mesh claw is controlled to be increased, and the endoscope mesh of the endoscope is loosened. When the force applied to the rotary buckle is withdrawn, the rotary buckle can be automatically reset under the action of the spring force, so that the inner diameter of the lens claw is reduced, and the endoscope lens can be pressed and fixed. Because the rotary buckle moves frequently, the phenomena of damping increase, activity blocking and the like are easy to occur due to abrasion.

In order to test the life of rotatory knot among the prior art, adopt the mode of manual rotation test more, the drawback of manual rotation test has: 1. a great deal of manpower is consumed; 2. the angular range of each rotation cannot be guaranteed to be consistent; 3. the number of manual calculations is prone to error.

Therefore, the rotary buckle life testing device and the life testing method can replace manual rotary buckle life testing, realize automatic testing and improve testing efficiency and accuracy.

Disclosure of Invention

In order to overcome the problems in the related art, one of the purposes of the present application is to provide a rotary buckle life testing device, which comprises a workbench, a cylinder, a connecting mechanism, a transmission mechanism, a detection mechanism and a control mechanism, wherein the cylinder is controlled to operate by the control mechanism, the cylinder drives the transmission mechanism to operate, and the life of the rotary buckle is judged according to the motion parameters fed back by the detection mechanism.

A rotary buckle life testing device comprises a workbench, an air cylinder, a connecting mechanism, a transmission mechanism, a detection mechanism and a control mechanism,

the workbench is provided with a fixing frame which is used for fixing the lens to be tested;

the cylinder comprises a first cylinder and a second cylinder, the first cylinder and the second cylinder comprise a cylinder body and a sliding block, the two cylinder bodies are respectively arranged horizontally and vertically, and the sliding block can reciprocate along the cylinder body;

the transmission mechanism is mechanically connected with the sliding block through the connecting mechanism and drives the rotary buckle to rotate;

the detection mechanism comprises a pressure sensor and a travel sensor, and the motion parameters of the transmission mechanism and the sliding block are respectively detected;

the control mechanism is used for controlling the operation of the air cylinder and judging the service life of the tested rotary buckle according to the motion parameters fed back by the detection mechanism.

In a preferred technical solution of the present application, the transmission mechanism includes a roller or a manipulator.

In the preferred technical scheme of the application, the pressure sensor is arranged on the transmission mechanism and used for detecting the pressure value in the extrusion and rotation process of the transmission mechanism and the rotary buckle.

In the preferred technical scheme of this application, the stroke sensor sets up on vertical back and forth motion's slider for detect the stroke value of rotatory knot.

In the preferred technical solution of the present application, the transmission mechanism is mechanically connected with the slider that moves vertically back and forth through the connection mechanism.

In the preferred technical scheme of the application, the control mechanism comprises a counting module for counting the rotation times of the measured rotary buckle.

It is an object of the present application to provide a life testing method, using the rotary buckle life testing device described in any one of the above, the life testing method comprising:

the control mechanism controls the air cylinder to drive the tested rotary buckle to rotate;

respectively acquiring a pressure value f of the pressure sensor and a stroke value l of the stroke sensor;

and respectively comparing the pressure value F with the pressure preset value F, and judging whether the service life of the tested rotary buckle is full or not according to the comparison result by the stroke L and the stroke preset value L.

In the preferred technical scheme of the application, judging whether the service life of the measured rotary buckle is full according to the comparison result comprises the following steps:

if F is more than or equal to F and L is more than or equal to L, judging that the service life of the measured rotary buckle is not full, retracting the second cylinder, returning the transmission mechanism to the initial position, and entering the next rotation;

if F is more than or equal to F and L is less than L, judging that the service life of the tested rotary buckle is full, and stopping testing.

In a preferred technical scheme of the application, the control mechanism comprises a counting module for calculating the number X of times the measured rotary buckle rotates;

if F is more than or equal to F and L is more than or equal to L, judging that the service life of the detected rotary buckle is not full, retracting the air cylinder, returning the transmission mechanism to the initial position, and entering the next rotation, wherein the service life of the detected rotary buckle is X+1;

and judging that the service life of the tested rotary buckle is full until F is more than or equal to F and L is less than L.

In the preferred technical scheme of the application, if F is smaller than F, the control mechanism controls the air cylinder to continuously drive the tested rotary buckle to rotate.

The beneficial effect of the technical scheme that this application provided is: the rotary buckle life testing device comprises a workbench, an air cylinder, a connecting mechanism, a transmission mechanism, a detection mechanism and a control mechanism,

the workbench is provided with a fixing frame for fixing the rotary buckle to be detected, the air cylinder and the detection mechanism are connected with the control mechanism through signals, the air cylinder comprises a first air cylinder and a second air cylinder, the first air cylinder and the second air cylinder comprise a cylinder body and a sliding block, the two cylinder bodies are respectively horizontally and vertically arranged, the sliding block can reciprocate along the cylinder body, and the transmission mechanism is mechanically connected with the sliding block through a connecting mechanism.

The setting of first cylinder and second cylinder has guaranteed that drive mechanism can reach the assigned position, with the rotatory knot contact that awaits measuring, and the motion of cylinder drives drive mechanism motion, and drive mechanism drives rotatory knot and rotates to replace the manual operation of rotatory knot of manual rotation, reduce the human cost.

Meanwhile, the rotary buckle life testing device further comprises a detection mechanism, the detection mechanism comprises a pressure sensor and a travel sensor, different motion parameters of the transmission mechanism can be detected respectively, and the control mechanism can judge the life of the detected rotary buckle according to the motion parameters fed back by the detection mechanism, so that the phenomenon that subjective judgment errors exist in manually judging the life of the rotary buckle is avoided.

To sum up, this rotatory life test device that detains can replace the manual work to carry out rotatory life test that detains, realizes automated test, has reduced test cost of labor and test error, improves efficiency and the degree of accuracy of test.

Drawings

Fig. 1 is a schematic structural view 1 of a rotary buckle life testing device according to an embodiment of the present application;

FIG. 2 is a schematic structural view of a device for testing the life of a spin button according to an embodiment of the present disclosure;

fig. 3 is a schematic structural view of a lens shown in an embodiment of the present application;

FIG. 4 is a schematic structural view of a control mechanism shown in an embodiment of the present application;

fig. 5 is a schematic structural diagram of an electronic device according to an embodiment of the present application;

fig. 6 is a flow chart of a lifetime test method according to an embodiment of the present application.

Reference numerals:

1. a work table; 2. a cylinder; 21. a cylinder; 22. a slide block; 23. a first cylinder; 24. a second cylinder; 3. a connecting mechanism; 4. a transmission mechanism; 5. a detection mechanism; 6. a control mechanism; 7. a fixing frame; 8. a rotary buckle; 9. a mounting seat body; 10. a lens claw; 11. a rotation stopping structure; 12. a bracket; 51. a pressure sensor; 52. a stroke sensor; 61. a counting module; 62. a judging module; 63. a storage module; 1000. an electronic device; 1010. a memory; 1020. a processor.

Detailed Description

Preferred embodiments of the present application will be described in more detail below with reference to the accompanying drawings. While the preferred embodiments of the present application are shown in the drawings, it should be understood that the present application may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

Example 1

In the prior art, in order to test the service life of the rotary buckle, a manual rotary test is adopted, and the defects of the manual rotary test are as follows: 1. a great deal of manpower is consumed; 2. the angular range of each rotation cannot be guaranteed to be consistent; 3. the number of manual calculations is prone to error.

Therefore, the rotary buckle life testing device and the life testing method can replace manual rotary buckle life testing, realize automatic testing and improve testing efficiency and accuracy.

The following describes the technical scheme of the embodiments of the present application in detail with reference to the accompanying drawings.

See fig. 1 to 4.

The rotary buckle life testing device comprises a workbench 1, a cylinder 2, a connecting mechanism 3, a transmission mechanism 4, a detection mechanism 5 and a control mechanism 6.

The workbench 1 is provided with a fixing frame 7, and the fixing frame 7 is used for fixing a lens to be tested; namely, when the life test operation is performed, the lens to be tested is fixed on the fixing frame 7, the lens to be tested comprises a lens mount, and the lens mount comprises a mount body 9, a rotary buckle 8 and a lens claw 10.

Further, the detection mechanism 5 and the cylinder 2 in the embodiment of the present application are in signal connection with the control mechanism 6, that is, the control mechanism 6 can control the cylinder 2, and the detection mechanism 5 can feed back the detected data to the control mechanism 6.

Further, the control mechanism 6 may be embedded in the workbench 1 or disposed on the surface of the workbench 1, which is not limited in this embodiment, and may be set according to practical applications.

Further, the cylinder 2 may be disposed above the table 1. The cylinder 2 includes a first cylinder 23 and a first cylinder 24, and the first cylinder 23 and the first cylinder 24 each include a cylinder body 21 and a slider 22, and the two cylinder bodies 21 are respectively disposed horizontally and vertically, and the slider 22 is reciprocable along the cylinder bodies 21.

Further, the cylinder 2 horizontally arranged on the cylinder 21 is a first cylinder 23, the cylinder 21 is vertically arranged on the cylinder 24, and the sliding block 22 of the first cylinder 23 can slide reciprocally along the horizontal direction, and the sliding block 22 of the first cylinder 24 can slide along the vertical direction.

The first cylinder 23 and the first cylinder 24 are mechanically connected, i.e. the cylinder body 21 of the first cylinder 24 is connected to the slide 22 of the first cylinder 24. The transmission mechanism 4 is mechanically connected with the sliding block 22 through the connecting mechanism 3, and the transmission mechanism 4 drives the rotary buckle 8 to rotate.

Further, the rotary buckle life testing device can be further provided with a support 12, the support 12 is used for supporting the first air cylinder 23, the first air cylinder 23 is ensured to run stably and not to shake, the support 12 can be arranged as a portal frame, and the sliding block 22 of the first air cylinder 23 can be hung on a transverse frame of the portal frame. The fixing frame 7 on the workbench 1 is positioned below the portal frame.

That is, when the first cylinder 23 operates, the slide block 22 of the first cylinder 23 can be pushed or contracted in the horizontal direction, at this time, since the first cylinder 24 is mechanically connected with the first cylinder 23, the first cylinder 24 slides along with the slide block 22 of the first cylinder 23, when the first cylinder 24 slides to the designated position in the horizontal direction, the first cylinder 24 also reaches the designated position in the horizontal direction, at this time, the first cylinder 24 is started, the cylinder 21 of the first cylinder 24 is vertically arranged, so that the slide block 22 of the first cylinder 24 can slide vertically, the slide block 22 of the first cylinder 24 slides, the transmission mechanism 4 is connected with the slide block 22 through the connection mechanism 3, and therefore, by adjusting the position of the slide block 22, the transmission mechanism 4 can be in contact with the turnbuckle 8.

The connection of the lens of the general lens and the lens mounting seat is fixed into a quick-dismantling structure. The mirror mesh installation seat comprises an installation seat body 9, a rotary buckle 8, a mirror mesh claw 10 and a rotation stopping structure 11.

The rotary buckle life testing device further comprises a detection mechanism 5, the detection mechanism 5 of the embodiment of the application comprises a pressure sensor 51 and a stroke sensor 52, the pressure sensor 51 can be used for detecting the pressure value of the extrusion and rotation process of the transmission mechanism 4 and the rotary buckle 8, and the stroke sensor 52 can be used for detecting the stroke value of the extrusion and rotation process of the transmission mechanism 4 and the rotary buckle 8.

The data collected by the pressure sensor 51 and the travel sensor 52 are fed back to the control mechanism 6, the control mechanism 6 can control the movement of the first cylinder 23 and the first cylinder 24 according to the data, and in addition, the service life of the rotary buckle 8 can be judged according to the data, namely, whether the rotary buckle 8 can normally rotate or not is judged, if the rotary buckle 8 cannot continue to normally rotate, the service life is judged to be full, the service life of the rotary buckle 8 is recorded and saved, and the test is stopped.

The beneficial effects of the embodiment of the application are that: the rotary buckle life testing device comprises a workbench, an air cylinder, a connecting mechanism, a transmission mechanism, a detection mechanism and a control mechanism,

the workbench is provided with a fixing frame for fixing the rotary buckle to be detected, the air cylinder and the detection mechanism are connected with the control mechanism through signals, the air cylinder comprises a first air cylinder and a second air cylinder, the first air cylinder and the second air cylinder comprise a cylinder body and a sliding block, the two cylinder bodies are respectively horizontally and vertically arranged, the sliding block can reciprocate along the cylinder body, and the transmission mechanism is mechanically connected with the sliding block through a connecting mechanism.

The setting of first cylinder and second cylinder has guaranteed that drive mechanism can reach the assigned position, with the rotatory knot contact that awaits measuring, and the motion of cylinder drives drive mechanism motion, and drive mechanism drives rotatory knot and rotates to replace the manual operation of rotatory knot of manual rotation, reduce the human cost.

Meanwhile, the rotary buckle life testing device further comprises a detection mechanism, the detection mechanism comprises a pressure sensor and a travel sensor, different motion parameters of the transmission mechanism can be detected respectively, and the control mechanism can judge the life of the detected rotary buckle according to the motion parameters fed back by the detection mechanism, so that the phenomenon that subjective judgment errors exist in manually judging the life of the rotary buckle is avoided.

To sum up, this rotatory life test device that detains can replace the manual work to carry out rotatory life test that detains, realizes automated test, has reduced test cost of labor and test error, improves efficiency and the accuracy of test.

Example two

The rotary buckle life testing device of the embodiment of the application comprises the structural characteristics of the first embodiment, namely a workbench, a cylinder, a connecting mechanism, a transmission mechanism, a detection mechanism and a control mechanism.

See fig. 1 to 4.

The workbench 1 is provided with a fixing frame 7, and the fixing frame 7 is used for fixing a lens to be tested.

The cylinder 2 comprises a first cylinder 23 and a first cylinder 24, the first cylinder 23 and the first cylinder 24 comprise a cylinder body 21 and a sliding block 22, the two cylinder bodies 21 are respectively arranged horizontally and vertically, the sliding block 22 can reciprocate along the cylinder body 21, and the first cylinder 23 and the first cylinder 24 are mechanically connected.

The transmission mechanism 4 is mechanically connected with the sliding block 22 through the connecting mechanism 3, and the transmission mechanism 4 drives the rotary buckle 8 to rotate. The detection mechanism 5 includes a pressure sensor 51 and a stroke sensor 52, and detects a motion parameter of the transmission mechanism 4.

Further, the transmission mechanism 4 of the rotary buckle life testing device in the embodiment of the present application includes a roller or a manipulator, and the specific structure type of the transmission mechanism 4 is not limited in the above embodiment, and the embodiment of the present application adopts the roller or the manipulator as an example.

Further, the pressure sensor 51 is disposed on the transmission mechanism 4 and is used for detecting a pressure value during the extrusion and rotation process of the transmission mechanism 4 and the rotary buckle 8, the pressure value detected and collected by the pressure sensor 51 is transmitted to the control mechanism 6, and the control mechanism 6 determines the service life of the rotary buckle 8 according to the pressure value and other parameter data.

Further, a stroke sensor 52 is disposed on the slider 22 that moves vertically back and forth, that is, on the slider 22 of the first cylinder 24, for detecting a stroke value of the rotation of the rotary buckle 8 during the extrusion transmission process with the transmission mechanism 4. The stroke sensor 52 detects the acquired stroke value and transmits the acquired stroke value to the control mechanism 6, and the control mechanism 6 judges the service life of the rotary buckle 8 according to the magnitude of the stroke value and other data.

The transmission mechanism 4 is mechanically connected with a sliding block 22 which moves vertically and reciprocally through a connecting mechanism 3. I.e. the transmission 4 is mechanically connected to the slide 22 of the first cylinder 24 via the connection 3. Further, when the transmission mechanism 4 is a roller, the connection mechanism 3 may be a connection rod, and the material and the size of the connection rod are not limited in the present application, and the inventive design of the material and the size of the connection rod is within the scope of the present application. When the transmission mechanism 4 is a robot arm, the connection mechanism 3 may be a robot arm.

Further, the control mechanism 6 of the embodiment of the present application further includes a counting module 61 for counting the number of rotations of the detected rotary hook 8. The control mechanism 6 includes, but is not limited to, a judging module 62 and a storing module 63, wherein the judging module 62 is used for analyzing and judging whether the life of the tested rotary button 8 is full, and the storing module 63 is used for storing and recording the related data of the tested rotary button 8.

The beneficial effects of the embodiment of the application are that: the rotary buckle life testing device tests the life of the rotary buckle through the automatic mechanism, improves the detection automation level and the detection efficiency and precision, and can be popularized and applied to actual production testing.

Example III

The first embodiment and the second embodiment describe the rotary buckle life testing device, and the embodiments of the present application correspondingly describe the life testing method of the rotary buckle life testing device of the foregoing embodiments.

The following describes the technical scheme of the embodiments of the present application in detail with reference to the accompanying drawings.

See fig. 6.

The service life testing method of the embodiment of the application comprises the following steps:

s01, controlling a cylinder by a control mechanism to drive the tested rotary buckle to rotate;

that is, the control mechanism controls the air cylinder to start, specifically includes that the first air cylinder starts, and the slider of the first air cylinder slides to the appointed position along the horizontal direction, including sliding to the appointed horizontal position, and the appointed horizontal position of this application embodiment is not limited, in actual operation, should be above the rotatory knot. At this time, the second cylinder starts, and the slider of second cylinder slides in vertical direction, specifically slides downwards to appointed vertical position, and the appointed vertical position of this application is the position that the slider of second cylinder was located when can touching with rotatory knot with drive mechanism, and the position that drive mechanism was located at this moment is initial position.

At the moment, the control mechanism is used for continuously controlling the second air cylinder to continuously run, the sliding block of the second air cylinder continuously slides downwards from the appointed vertical position, and the transmission mechanism can drive the tested rotary buckle to rotate.

S02, respectively acquiring a pressure value f of the pressure sensor and a stroke value l of the stroke sensor;

the rotary buckle life testing device is provided with a pressure sensor and a travel sensor, the pressure sensor and the travel sensor can acquire a pressure value f in the extrusion and rotation process of the transmission mechanism and the rotary buckle, the pressure value f acquired by the pressure sensor is transmitted to the control mechanism, and the control mechanism judges the life condition of the rotary buckle according to the pressure value f and other data.

The stroke sensor detects a stroke value l of the rotary buckle rotating in the extrusion transmission process of the transmission mechanism. The stroke sensor detects the acquired stroke value l and transmits the acquired stroke value l to the control mechanism, and the control mechanism judges the service life condition of the rotary buckle according to the magnitude of the stroke value l and other data.

S03, comparing the pressure value F with a pressure preset value F, and comparing the stroke L with a stroke preset value L.

After the pressure value F and the stroke L are obtained, the pressure value F and the preset pressure value F are respectively analyzed and judged, the stroke L and the preset stroke value L are respectively analyzed and judged, the preset pressure value F and the preset stroke value L are preset in the control mechanism, the magnitudes of the preset pressure value F and the preset stroke value L are not particularly limited, and the preset pressure value F and the preset stroke value L are set according to actual test requirements.

S04, judging whether the service life of the tested rotary buckle is full or not according to the comparison result.

The method for testing the service life comprises the following steps of analyzing and judging the magnitude of a pressure value F and a pressure preset value F, and analyzing and judging the magnitude of a stroke L and a stroke preset value L:

if F is more than or equal to F and L is more than or equal to L, judging that the service life of the tested rotary buckle is not full, retracting the cylinder, returning the transmission mechanism to the initial position, and entering the next rotation.

In the extrusion transmission process of the rotary buckle and the transmission mechanism, the pressure sensor detects the pressure value change in the extrusion rotation process in real time, the actual pressure value F is increased along with the increase of the downward pressing distance of the rotary buckle driven by the second cylinder, the actual pressure value F can be contacted with the rotation stopping structure of the lens until the rotary buckle reaches the movement limit position, and in general, in order to prevent the rotary buckle from excessively rotating, the rotation stopping structure is arranged, at the moment, the second cylinder continuously moves downwards, and the actual pressure value F continuously rises and is larger than the pressure set value F.

At the moment, the stroke sensor detects a rotating stroke value L of the rotating buckle in real time in the extrusion transmission process of the rotating buckle and the transmission mechanism, and feeds the stroke value L back to the control mechanism, and when F is more than or equal to F, the stroke value L and a stroke preset value L are judged; if L is greater than or equal to L, the first cylinder and the second cylinder retract to prepare for the next cycle. At this time, it can be determined that the life of the spin button is not full, and the spin button is quickly reset to the initial position under the action of force after the pressure of the spin button is lost. Meanwhile, the test times recorded by the control mechanism are X, and the service life times of the rotary buckle are X+1.

When F is greater than or equal to F, if L is less than L, judging that the rotary buckle is abnormal, and failing to complete one complete pressing movement, namely judging that the service life of the tested rotary buckle is full, stopping testing, and sending out a buzzing prompt by the control mechanism.

Further, if F is smaller than F, the control mechanism controls the air cylinder to continuously drive the tested rotary buckle to rotate. Until the lens base is rotated, F is still smaller than F, and the rotating buckle life testing device is abnormal, and the rotating buckle life testing device is subjected to quality inspection.

Further, the control mechanism comprises a counting module for calculating the number X of times the measured rotary buckle rotates; the control mechanism comprises, but is not limited to, a judging module for analyzing and judging whether the life of the tested rotary buckle is full or not, and a storage module for storing and recording the related data of the tested rotary buckle.

The beneficial effects of the embodiment of the application are that: the life test method is to compare the pressure value F with the pressure preset value F, and the stroke L with the stroke preset value L, and judge whether the life of the rotary buckle is full according to the comparison result. The rotary buckle life test device can replace manual operation to perform rotary buckle life test, realize automatic test, reduce test labor cost and test errors, improve test efficiency and accuracy, meet actual application requirements, have practical value, and can be popularized and applied.

Example IV

An embodiment of the application provides an electronic device including one or more processors and corresponding memories.

See fig. 5.

The processor 1020 may be a central processing unit or other form of processing unit having data processing capabilities and/or instruction execution capabilities and may control other components in the electronic device 1000 to perform the desired functions.

The memory 1010 may include one or more computer program products that may include various forms of computer storage media, such as volatile memory 1010 and/or non-volatile memory 1010. The volatile memory 1010 may include, for example, random access memory 1010 (RAM) and/or cache memory 1010 (cache), among others. The non-volatile memory 1010 may include, for example, read only memory 1010 (ROM), hard disk, flash memory, and the like. One or more computer program instructions may be stored on the computer storage medium,

the processor 1020 may execute the program instructions to implement the decision-making methods of decision-making behavior of the various embodiments of the present application described above and/or other desired functions.

In an example, the electronic device 1000 may further include: input devices and output devices, which are interconnected by a bus system and/or other forms of connection 3 (not shown). The input device may also include, for example, a keyboard, mouse, etc. The output means may include, for example, a display, speakers, a printer, and a communication network and remote output devices connected thereto, etc. Of course, only some of the components of the electronic device 1000 that are relevant to the present application are shown in fig. 5 for simplicity, components such as buses, input/output interfaces, etc. are omitted. In addition, the electronic device 1000 may include any other suitable components depending on the particular application.

In addition to the methods and apparatus described above, embodiments of the present application may also extend to computer program products comprising computer program instructions that, when executed by the processor 1020, cause the processor 1020 to perform steps in a decision making method according to various embodiments of the present application described in the "exemplary methods" section of this specification. The computer program product may write program code for performing the operations of embodiments of the present application in any combination of one or more programming languages, including an object oriented programming language such as Java, C++ or the like and conventional procedural programming languages, such as the "C" programming language or similar programming languages. The program code may execute entirely on the user's computing device, partly on the user's device, as a stand-alone software package, partly on the user's computing device, partly on a remote computing device, or entirely on the remote computing device or server.

Furthermore, embodiments of the present application may also be a readable computer storage medium, having stored thereon computer program instructions, which when executed by the processor 1020, cause the processor 1020 to perform the steps in the decision making method according to various embodiments of the present application described in the above detailed flow section of the present specification.

Computer storage media may take the form of any combination of one or more readable media. The readable medium may be a readable signal medium or a storage medium. The storage medium may include, for example, but is not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or a combination of any of the foregoing. More specific examples (a non-exhaustive list) of the storage medium include: an electrical connection having one or more wires, a portable disk, a hard disk, a random access memory 1010 (RAM), a read-only memory 1010 (ROM), an erasable programmable read-only memory 1010 (EPROM or flash memory), an optical fiber, a portable compact disk read-only memory 1010 (CD-ROM), an optical memory 1010 piece, a magnetic memory 1010 piece, or any suitable combination of the preceding.

The relative arrangement of the components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present application unless it is specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective parts shown in the drawings are not drawn in actual scale for convenience of description. Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail, but should be considered part of the specification where appropriate. In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures. In the description of the present application, it should be understood that, where azimuth terms such as "front, rear, upper, lower, left, right", "transverse, vertical, horizontal", and "top, bottom", etc., indicate azimuth or positional relationships generally based on those shown in the drawings, only for convenience of description and simplification of the description, these azimuth terms do not indicate and imply that the apparatus or elements referred to must have a specific azimuth or be constructed and operated in a specific azimuth, and thus should not be construed as limiting the scope of protection of the present application; the orientation word "inner and outer" refers to inner and outer relative to the contour of the respective component itself.

In addition, the terms "first", "second", etc. are used to define the components, and are merely for convenience of distinguishing the corresponding components, and unless otherwise stated, the terms have no special meaning, and thus should not be construed as limiting the scope of the present application.

The foregoing description is only of the preferred embodiments of the present application and is not intended to limit the same, but rather, various modifications and variations may be made by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (10)

1. The utility model provides a rotatory life-span testing arrangement that detains which characterized in that: comprises a workbench (1), an air cylinder (2), a connecting mechanism (3), a transmission mechanism (4), a detection mechanism (5) and a control mechanism (6),

a fixing frame (7) is arranged on the workbench (1), and the fixing frame (7) is used for fixing a lens to be tested;

the air cylinder (2) comprises a first air cylinder (23) and a second air cylinder (24), the first air cylinder (23) and the second air cylinder (24) comprise a cylinder body (21) and a sliding block (22), the two cylinder bodies (21) are respectively arranged horizontally and vertically, the sliding block (22) can reciprocate along the cylinder bodies (21), and the first air cylinder (23) and the second air cylinder (24) are mechanically connected;

the transmission mechanism (4) is mechanically connected with the sliding block (22) through the connecting mechanism (3), and the transmission mechanism (4) drives the rotary buckle (8) of the lens to be tested to rotate;

the detection mechanism (5) comprises a pressure sensor (51) and a stroke sensor (52) and is used for detecting the motion parameters of the transmission mechanism (4);

the control mechanism (6) is used for controlling the operation of the air cylinder (2) and judging the service life of the rotary buckle (8) to be measured according to the motion parameters fed back by the detection mechanism (5).

2. The spin button life test device of claim 1, wherein:

the transmission mechanism (4) comprises a roller or a manipulator.

3. The spin button life test device of claim 1, wherein:

the pressure sensor (51) is arranged on the transmission mechanism (4) and is used for detecting the pressure value in the extrusion and rotation process of the transmission mechanism (4) and the rotary buckle (8).

4. The spin button life test device of claim 3, wherein:

the stroke sensor (52) is arranged on the sliding block (22) which moves vertically back and forth and is used for detecting the stroke value of the rotary buckle (8).

5. The spin button life test device of claim 3, wherein:

the transmission mechanism (4) is mechanically connected with the sliding block (22) which moves vertically back and forth through the connecting mechanism (3).

6. The spin button life test device of claim 1, wherein:

the control mechanism (6) comprises a counting module (61) for counting the number of rotations of the detected rotary buckle (8).

7. A life test method is characterized in that: use of the rotary hook life test device of any one of claims 1 to 6;

the life test method comprises the following steps:

the control mechanism (6) controls the air cylinder (2) to drive the tested rotary buckle (8) to rotate;

respectively acquiring a pressure value f of the pressure sensor (51) and a stroke value l of the stroke sensor (52);

comparing the pressure value F with the pressure preset value F, and comparing the stroke value L with the stroke preset value L;

judging whether the life of the detected rotary buckle (8) is full or not according to the comparison result.

8. The life testing method according to claim 7, wherein:

judging whether the life of the detected rotary buckle (8) is full according to the comparison result comprises the following steps:

if F is more than or equal to F and L is more than or equal to L, judging that the service life of the detected rotary buckle (8) is not full, retracting the cylinder (2), returning the transmission mechanism (4) to an initial position, and entering the next rotation;

if F is more than or equal to F and L is less than L, judging that the service life of the tested rotary buckle (8) is full, and stopping testing.

9. The life testing method according to claim 8, wherein:

the control mechanism (6) comprises a counting module (61) for calculating the number X of times the detected rotary buckle (8) rotates;

if F is more than or equal to F and L is more than or equal to L, judging that the service life of the measured rotary buckle (8) is not full, retracting the air cylinder (2), returning the transmission mechanism (4) to the initial position, and entering the next rotation, wherein the service life of the measured rotary buckle (8) is X+1;

and judging that the service life of the tested rotary buckle (8) is full until F is more than or equal to F and L is less than L.

10. An electronic device, comprising:

the electronic device includes one or more processors and corresponding memory;

a memory having executable code stored thereon, which when executed by the processor, causes the processor to perform the method of any of claims 7-9.