CN216700187U - Camera detection device - Google Patents

Abstract

The embodiment of the application discloses camera detection device. The camera detection device comprises a base, a rotary platform and a compression joint jig, wherein the rotary platform is installed on the base and is rotatably connected with the base; the compression joint jig is arranged on the installation area of the rotary platform and used for installing the camera; the rotary platform is used for driving the crimping jig to rotate between a plurality of preset positions around the rotation axis so as to carry out a plurality of detections on the camera. This application installs the crimping tool on rotary platform, drives the crimping tool through rotary platform and rotates around the rotation axis between a plurality of preset positions, and different preset positions correspond different detections to the realization carries out multinomial detection in succession to the camera of installing on the crimping tool, with improvement camera detection device's detection efficiency.

Description

Camera detection device

Technical Field

The application relates to the technical field of detection, in particular to a camera detection device.

Background

With the gradual development of screen-shooting integrated products, a large application market exists in the future. For the result of use of guaranteeing the screen integration product of making a video recording, need detect and rectify camera under the screen in the production process, because the camera data volume is big, the bandwidth requirement is high, and traditional camera detection device can't do many technologies to the camera and detect to lead to detection efficiency low.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a camera detection device, which can solve the problem of low detection efficiency of the existing camera detection device.

The embodiment of the application provides a camera detection device, includes:

a base;

the rotating platform is arranged on the base and is rotationally connected with the base, and the extending direction of the rotating axis of the rotating platform and the plane where the rotating platform is located form an included angle; the rotating platform is provided with an installation area;

the compression joint jig is arranged on the installation area of the rotary platform and is used for installing a camera; the rotary platform is used for driving the crimping jig to rotate around the rotation axis between a plurality of preset positions so as to carry out a plurality of detections on the camera.

Optionally, in some embodiments of the present application, a plurality of the mounting regions are disposed on the rotating platform, and the plurality of the mounting regions are distributed along a circumferential direction of the rotating platform; and each mounting area is provided with the crimping jig.

Optionally, in some embodiments of the present application, a plurality of the crimping jigs are arranged in parallel on each of the mounting regions.

Optionally, in some embodiments of the present application, the camera detection device includes an optical fiber conductive slip ring, the optical fiber conductive slip ring is mounted on the rotating platform, and the optical fiber conductive slip ring and the rotating platform rotate around the rotation axis.

Optionally, in some embodiments of the present application, the optical fiber conductive slip ring is electrically connected to the crimping jig, and the optical fiber conductive slip ring is configured to receive and transmit detection data of a camera on the crimping jig.

Optionally, in some embodiments of the present application, a mounting opening is formed in the rotating platform, the mounting opening penetrates through the rotating platform in a thickness direction of the rotating platform, and the optical fiber slip ring passes through the mounting opening and is rotatably connected to the base; the rotation axis passes through the mounting opening.

Optionally, in some embodiments of the present application, the camera detection device further includes a driving mechanism, the driving mechanism is connected to the rotating platform, and the driving mechanism is configured to drive the crimping jig on the rotating platform to rotate around the rotation axis;

when the crimping jig rotates to a first position, the camera detection device is used for feeding the camera; when the crimping jig rotates to a second position, the camera detection device is used for testing and correcting the camera; when the crimping jig rotates to a third position, the camera detection device is used for retesting the camera; when the crimping jig rotates to the fourth position, the camera detection device is used for discharging the camera.

Optionally, in some embodiments of the present application, the driving mechanism is configured to drive the crimping jig to rotate around the rotation axis in sequence along the first position, the second position, the third position, and the fourth position.

Optionally, in some embodiments of the present application, the first position, the second position, the third position, and the fourth position are sequentially distributed along a rotation direction of the crimping jig.

Optionally, in some embodiments of the present application, the first position, the second position, the third position, and the fourth position are uniformly distributed along a circumferential direction of the rotating platform.

The camera detection device comprises a base, a rotary platform and a compression joint jig, wherein the rotary platform is mounted on the base and is rotatably connected with the base; the compression joint jig is arranged on the installation area of the rotary platform and used for installing the camera; the rotary platform is used for driving the crimping jig to rotate between a plurality of preset positions around the rotation axis so as to carry out a plurality of detections on the camera. This application installs the crimping tool on rotary platform, drives the crimping tool through rotary platform and rotates around the rotation axis between a plurality of preset positions, and different preset positions correspond different detections to the realization carries out multinomial detection in succession to the camera of installing on the crimping tool, with improvement camera detection device's detection efficiency.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a camera detection device provided in an embodiment of the present application.

Description of reference numerals:

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application. Furthermore, it should be understood that the detailed description and specific examples, while indicating exemplary embodiments of the invention, are given by way of illustration and explanation only, and are not intended to limit the scope of the invention. In this application, where the context requires otherwise, the words "upper" and "lower" used in relation to the device in use or operation will generally refer to the upper and lower extremities of the device, particularly as oriented in the drawing figures; while "inner" and "outer" are with respect to the outline of the device.

The embodiment of the application provides a camera detection device. The following are detailed below. It should be noted that the following description of the embodiments is not intended to limit the preferred order of the embodiments.

First, as shown in fig. 1, the camera detection device 100 includes a base 110, where the base 110 serves as a main support structure of the camera detection device 100 and is used to support other structures in the camera detection device 100, so as to ensure overall stability of the structure of the camera detection device 100.

Camera detection device 100 includes rotary platform 120, and rotary platform 120 installs on base 110, and rotary platform 120 rotates with base 110 to be connected, and rotary platform 120 can rotate relative base 110 promptly to rotate to different positions, realize the different detection demands of camera detection device 100.

The extending direction of the rotation axis of the rotating platform 120 is disposed at an angle with respect to the plane of the rotating platform 120, that is, the rotation axis of the rotating platform 120 penetrates through the thickness direction of the rotating platform 120, for example, the rotation axis is perpendicular to the surface of the rotating platform 120, so that the rotating platform 120 rotates on the horizontal plane, which helps to keep the object placed on the rotating platform 120 relatively stable.

The rotary platform 120 is further provided with an installation area 121 for locating the installation structure in a partitioned manner, and the structure installed on the installation area 121 can be designed in a distributed manner by designing the position of the installation area 121 on the rotary platform 120, so as to meet different structural design requirements of the camera detection device 100.

The camera detection device 100 comprises a crimping jig 130, the crimping jig 130 is installed on an installation area 121 of the rotary platform 120, the crimping jig 130 is used for installing a camera, and the installation mode of the camera can be adjusted through the setting position of the installation area 121 and the adjustment of the installation mode of the crimping jig 130 in the installation area 121 so as to meet the detection requirements of different detection modes of the camera detection device 100.

It should be noted that the camera in the embodiment of the present application can be a screen-shooting integrated camera, that is, a screen-down camera, and can also be a common single camera, where no special limitation is made here, and the camera detection device 100 in the present application can be used for performing corresponding detection.

Wherein, rotary platform 120 is used for driving crimping tool 130 to rotate between a plurality of preset positions around the rotation axis to carry out a plurality of detections to the camera. Different detection technology that predetermines the position correspondence promptly, when crimping tool 130 rotated to corresponding position, can carry out corresponding detection to the camera on crimping tool 130. The adjustment and control of the detection mode of the camera between a plurality of preset positions can be realized by adjusting and controlling the rotation mode of the rotation platform 120.

The camera detection device 100 in the embodiment of the present application includes a base 110, a rotating platform 120 and a crimping jig 130, wherein the rotating platform 120 is installed on the base 110, the rotating platform 120 is rotatably connected to the base 110, an extending direction of a rotation axis of the rotating platform 120 forms an included angle with a plane where the rotating platform 120 is located, and an installation area 121 is arranged on the rotating platform 120; the crimping jig 130 is installed on the installation area 121 of the rotary platform 120, and the crimping jig 130 is used for installing a camera; the rotary platform 120 is used for driving the crimping jig 130 to rotate around the rotation axis between a plurality of preset positions so as to perform a plurality of detections on the camera. This application installs crimping tool 130 on rotary platform 120, drives crimping tool 130 through rotary platform 120 and rotates around the rotation axis between a plurality of preset positions, and different preset positions correspond different detections to the realization carries out multinomial detection in succession to the camera of installing on crimping tool 130, with improvement camera detection device's detection efficiency.

Optionally, a plurality of mounting regions 121 are disposed on the rotating platform 120, the plurality of mounting regions 121 are distributed along the circumferential direction of the rotating platform 120, and the mounting position of the crimping jig 130 is conveniently adjusted according to actual conditions by disposing the plurality of mounting regions 121 on the rotating platform 120, so that a camera mounted on the crimping jig 130 is quickly detected.

Wherein, install crimping tool 130 on every installation area 121, then correspond on every crimping tool 130 and install the camera, a plurality of cameras distribute along rotary platform 120's circumference promptly for when crimping tool 130 rotates around the rotation axis along with rotary platform 120, a plurality of cameras can detect in proper order, thereby improve camera detection device 100's detection efficiency.

It should be noted that the plurality of mounting areas 121 are uniformly distributed along the circumferential direction of the rotating platform 120, that is, the cameras on the plurality of crimping jigs 130 are uniformly distributed along the circumferential direction of the rotating platform 120, so that when the plurality of cameras are sequentially rotated to a certain preset position, the angle of rotation of the rotating platform 120 is the same each time, so as to facilitate the regulation and control of the rotation mode of the rotating platform 120.

Optionally, a plurality of crimping jigs 130 are arranged on each mounting area 121 in parallel, that is, when the same mounting area 121 rotates to a certain preset position, the camera detection device 100 can simultaneously perform the same detection on a plurality of cameras of the mounting area 121, so as to further improve the detection efficiency of the camera detection device 100.

Optionally, the camera detection device 100 includes an optical fiber conductive slip ring 140, the optical fiber conductive slip ring 140 is installed on the rotary platform 120, and the optical fiber conductive slip ring 140 and the rotary platform 120 rotate around the rotation axis, that is, the optical fiber conductive slip ring 140 and the rotary platform 120 rotate synchronously around the same rotation axis, so that the position between the optical fiber conductive slip ring 140 and the crimping jig 130 on the rotary platform 120 is kept relatively stable, thereby facilitating the wiring design between the optical fiber conductive slip ring 140 and the crimping jig 130.

The optical fiber conductive slip ring 140 is electrically connected with the crimping jig 130, the optical fiber conductive slip ring 140 is used for receiving and transmitting detection data of the camera on the crimping jig 130, the optical fiber conductive slip ring 140 and the crimping jig 130 are set to rotate synchronously, so that connection points between the optical fiber conductive slip ring 140 and the corresponding crimping jig 130 are kept relatively stable, the rotating platform 120 is prevented from rotating in the process, the optical fiber conductive slip ring 140 is disconnected from the crimping jig 130, and transmission of detection results of the camera on the crimping jig 130 is influenced.

It should be noted that, the optical fiber conductive slip ring 140 in the embodiment of the present application is in optical fiber communication, and the bandwidth of the optical fiber conductive slip ring is larger than that of a traditional data line transmission mode, so that the data transmission capability is greatly improved, the transmission requirements of the screen-shooting integrated camera detection and correction data can be met, and the multi-station continuous rotation test working condition is realized.

Optionally, the rotating platform 120 is provided with a mounting opening 122, the mounting opening 122 penetrates through the rotating platform 120 along the thickness direction of the rotating platform 120, and the optical fiber conductive slip ring 140 penetrates through the mounting opening 122 to be rotatably connected with the base 110, so that the optical fiber conductive slip ring 140 and the rotating platform 120 rotate synchronously. In addition, the optical fiber conductive slip ring 140 penetrates through the mounting port 122 to be connected to the base 110, so that the base 110 can support the optical fiber conductive slip ring 140 to a certain extent, the optical fiber conductive slip ring 140 can be kept relatively stable in the process of rotating synchronously with the rotating platform 120, the electrical connection disconnection between the optical fiber conductive slip ring 140 and the corresponding crimping jig 130 is avoided, and the detection stability of the camera detection device 100 is improved.

The rotation axis penetrates through the mounting port 122, that is, the rotation axis penetrates through the optical fiber conductive slip ring 140, that is, the optical fiber conductive slip ring 140 is disposed at the rotation center of the rotation platform 120, so that when the rotation platform 120 and the optical fiber conductive slip ring 140 rotate synchronously, the rotation platform 120 rotates around the optical fiber conductive slip ring 140, and thus the relative distance between the optical fiber conductive slip ring 140 and each crimping jig 130 is equal, so as to ensure that the transmission distance of the detection data of the camera on each crimping jig 130 on the optical fiber conductive slip ring 140 is the same, and the signal loss which may be generated is also the same, thereby ensuring the consistency and reliability of the detection data.

Optionally, the camera detection device 100 further includes a driving mechanism, the driving mechanism is connected to the rotating platform 120, and the driving mechanism is configured to drive the crimping jig 130 on the rotating platform 120 to rotate around the rotation axis, that is, the driving mechanism drives the crimping jig 130 on the rotating platform 120 to rotate between a plurality of preset positions, so as to implement continuous testing of the camera on the crimping jig 130 between the plurality of preset positions, thereby improving the detection efficiency of the camera detection device 100.

When crimping tool 130 rotates to first position A, camera detection device 100 is used for carrying out the material loading to the camera, first position A corresponds camera detection device 100's material loading station promptly, through set up the material loading station in camera detection device 100, make the camera that waits to detect all get into rotary platform 120 from the same position, thereby guarantee that every camera gets into the initial position behind the rotary platform 120 and keep unanimous, avoid carrying out retest or missing the survey to certain camera in continuous test process, thereby guarantee going on in order of whole testing process.

When the crimping jig 130 rotates to the second position B, the camera detection device 100 is used for testing and correcting the camera, that is, the second position B corresponds to the testing and correcting station of the camera detection device 100. At this time, the backlight source is used to light the camera in the crimping jig 130, and obtain the test picture and the test data of the lighted camera, and then the test data is transmitted to the processor through the optical fiber conductive slip ring 140, and the processor analyzes and corrects the test data to determine whether the camera meets the design requirements of the qualified product.

When the crimping jig 130 rotates to the third position C, the camera detection device 100 is used for retesting the camera, that is, the third position C corresponds to the retesting station of the camera detection device 100. After the initial detection and correction of the camera are completed at the second position B, the camera needs to be retested at the third position C to confirm whether the deviation occurs in the last detection, so that the accuracy and reliability of the detection result of the camera detection device 100 are ensured.

It should be noted that, when the camera detection device 100 performs repeated detection on the camera, the same test mode and test parameters as those in the second position B need to be adopted to ensure comparability of the two-time test structure, and avoid influence on the test structure due to the change of the test mode or the test parameters, so as to further ensure accuracy and reliability of the detection result of the camera detection device 100.

When crimping tool 130 rotates to fourth position D, camera detection device 100 is used for unloading the camera, fourth position D corresponds camera detection device 100's unloading station promptly, through set up the unloading station in camera detection device 100, make the camera that waits to detect all leave rotary platform 120 from the same position, thereby guarantee that the final position when every camera leaves rotary platform 120 keeps unanimous, avoid carrying out the retest or missing the survey to certain camera in the continuous test process, thereby guarantee going on in order of whole testing process.

The first position a and the fourth position D of the camera detection device 100 may be the same or different, that is, the feeding station and the discharging station of the camera detection device 100 may be the same or different. When the feeding station and the discharging station of the camera detection device 100 are the same, the positions of the camera entering and leaving the rotating platform 120 are the same, the space occupation of the rotating platform 120 can be saved by the structural design, and the overall structure of the camera detection device 100 is simplified.

When camera detection device 100's material loading station and unloading station are inequality, the camera gets into and leaves rotary platform 120's position inequality, this kind of structural design makes and installs crimping tool 130 to rotary platform 120 with the camera and takes out these two actions with the camera from crimping tool 130 on rotary platform 120 and can separately go on, and mutual interference can not appear, thereby shorten the whole required time of material loading and unloading process, improve camera detection device 100's detection efficiency.

In addition, the feeding station and the discharging station of the camera detection device 100 are separately designed, so that confusion between the camera to be detected and the tested camera can be avoided, repeated testing or missing testing of some cameras can be avoided, the camera detection device 100 can be ensured to be orderly carried out, and the testing reliability of the camera detection device 100 is improved.

It should be noted that, in addition to the testing and correcting station corresponding to the second position B and the retesting station corresponding to the third position C, the crimping jig 130 can be driven by the driving mechanism to rotate to a plurality of positions, that is, a plurality of other stations are correspondingly arranged in the circumferential direction of the rotary platform 120, so as to perform a plurality of process detections on the camera, meet the multi-station rotation testing requirements of the camera detection device 100, expand the application range of the camera detection device 100, and improve the applicability of the camera detection device 100.

The number of positions where the driving mechanism drives the crimping jig 130 to rotate around the rotation axis can be adjusted according to actual detection requirements and the structure of the camera detection device 100, and is not limited to the first position a, the second position B, the third position C, and the fourth position D in the embodiment of the present application, and all of them are within the protection scope of the embodiment of the present application.

Optionally, the driving mechanism is configured to drive the crimping jig 130 to rotate around the rotation axis in sequence along the first position a, the second position B, the third position C, and the fourth position D, that is, the driving mechanism rotates in sequence among the first position a, the second position B, the third position C, and the fourth position D according to the detection sequence when driving the crimping jig 130 to rotate around the rotation axis, so as to implement the processes of loading, testing and correcting, retesting, unloading, and the like of the camera.

Wherein, the direction of rotation of actuating mechanism drive crimping tool 130 around the axis of rotation is directly relevant with the mode of setting up first position A, second position B, third position C and fourth position D, through the regulation design of the mode of setting up corresponding first position A, second position B, third position C and fourth position D on revolving platform 120, can realize the regulation and control of the mode of rotation around the axis of rotation of actuating mechanism drive crimping tool 130 to satisfy the different detection demands of camera detection device 100.

Optionally, the first position a, the second position B, the third position C, and the fourth position D are sequentially distributed along the rotation direction of the crimping jig 130. That is, when the driving mechanism drives the crimping jig 130 to rotate around the rotation axis, the driving mechanism sequentially rotates to the first position a, the second position B, the third position C and the fourth position D along the same direction, so that the rotating platform 120 can continuously rotate along the same direction, the continuous rotation test of the camera detection device 100 is facilitated, and the detection efficiency of the camera detection device 100 is improved.

It should be noted that, according to actual test requirements, the rotary platform 120 can also rotate back and forth between a plurality of preset positions in a forward and reverse rotation manner to meet different test requirements, and the specific rotation manner can be correspondingly designed and adjusted according to actual use conditions, and here, no special limitation is made, and only the requirement of multi-station rotary test of the camera detection device 100 needs to be met.

Optionally, the first position a, the second position B, the third position C, and the fourth position D are uniformly distributed along the circumferential direction of the rotating platform 120, that is, the crimping jig 130 rotates from the first position a to the second position B, rotates from the second position B to the third position C, and rotates from the third position C to the fourth position D and rotates from the fourth position D to the first position a at the same rotation angle, wherein the rotation angles are all 90 degrees. The rotation angles of the crimping jig 130 between the positions are set to be the same, so that the drive control of the driving mechanism to the rotating platform 120 is facilitated, the rapid and continuous test of the camera detection device 100 is realized, and the detection efficiency of the camera detection device 100 is improved.

It should be noted that, when a plurality of other stations corresponding to the detection items are further provided along the circumferential direction of the rotary platform 120, the angle of each rotation of the crimping jig 130 on the driving mechanism driving the rotary platform 120 is divided equally according to the number of the detection items, for example, when six positions are distributed along the circumferential direction of the rotary platform 120, the angle of each rotation of the crimping jig 130 on the driving mechanism driving the rotary platform 120 is 60 degrees, and when eight positions are distributed along the circumferential direction of the rotary platform 120, the angle of each rotation of the crimping jig 130 on the driving mechanism driving the rotary platform 120 is 45 degrees, so as to facilitate the driving control of the driving mechanism driving the rotary platform 120, to implement the rapid and continuous test of the camera detection apparatus 100, and to improve the detection efficiency of the camera detection apparatus 100.

Specifically, for the sake of clarity, the detection method of the camera detection device 100 is described in detail with reference to one embodiment, but the detection method is not limited to the following detection method, and those skilled in the art will be able to change the embodiment and the application scope according to the idea of the present application, which falls within the protection scope of the present application.

First, the crimping jig 130 is installed in the installation area 121 on the rotating platform 120 and is communicated with the optical fiber conductive slip ring 140, and then the camera is installed in the first crimping jig 130 at the first position a, so as to realize the loading of the first camera.

Then, the driving mechanism drives the rotating platform 120 to rotate, so that the first crimping jig 130 rotates to the second position B, and the first crimping jig 130 automatically crimps the first camera, so that the first camera is conducted with the first crimping jig 130. And the backlight source is utilized to light the first camera, the corresponding detection picture and detection data are transmitted to the data processor through the optical fiber conductive slip ring 140, and the detection result is analyzed and corrected through the data processor so as to complete the test and correction of the first camera.

When detecting first camera, install the second camera on being located the second crimping tool 130 of first position A to realize the material loading of second camera.

The rotating platform 120 is continuously rotated to rotate the first pressing jig 130 to the third position C, and the second pressing jig 130 is rotated to the second position B. Retesting the first camera at the third position C in the same test mode to ensure the accuracy and reliability of the test result; and simultaneously, testing and correcting the second camera positioned at the second position B by adopting the same testing mode so as to complete retesting of the first camera and testing and correcting of the second camera.

When detecting first camera and second camera, install the third camera on being located the third crimping tool 130 of first position A to realize the material loading of third camera.

The rotating platform 120 is continuously rotated to rotate the first pressing jig 130 to the fourth position D, the second pressing jig 130 to the third position C, and the third pressing jig 130 to the second position B. And (3) retesting the second camera at the third position C by adopting the same testing mode, testing and correcting the third camera at the second position B, and simultaneously blanking the first camera at the fourth position D.

When carrying out the unloading to first camera, detect second camera and third camera, install the fourth camera on being located the fourth crimping tool 130 of first position A to realize the material loading of fourth camera.

By repeating the above steps, the multi-station continuous rotation test of the camera detection device 100 can be realized. By adopting the test mode, the accuracy and the reliability of the test structure of the camera detection device 100 are ensured, the applicability of the camera detection device 100 can be improved, and the detection efficiency of the camera detection device 100 is improved.

The foregoing describes in detail a camera detection device provided in an embodiment of the present application, and a specific example is applied to explain the principle and the implementation of the present application, and the description of the foregoing embodiment is only used to help understand the method and the core idea of the present application; meanwhile, for those skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (10)

1. A camera detection device, characterized in that camera detection device includes:

a base;

the rotating platform is arranged on the base and is rotationally connected with the base, and the extending direction of the rotating axis of the rotating platform and the plane where the rotating platform is located form an included angle; the rotating platform is provided with an installation area;

the compression joint jig is arranged on the installation area of the rotary platform and used for installing the camera; the rotary platform is used for driving the crimping jig to rotate around the rotation axis between a plurality of preset positions so as to carry out a plurality of detections on the camera.

2. The camera detection device according to claim 1, wherein a plurality of the mounting regions are disposed on the rotary platform, and are distributed along a circumferential direction of the rotary platform; and each mounting area is provided with the crimping jig.

3. The camera detection device according to claim 2, wherein a plurality of the crimping jigs are juxtaposed on each of the mounting regions.

4. The camera inspection device of claim 1, wherein the camera inspection device comprises a fiber optic slip ring mounted on the rotating platform, the fiber optic slip ring and the rotating platform rotating about the axis of rotation.

5. The camera detection device according to claim 4, wherein the optical fiber conductive slip ring is electrically connected to the crimping jig, and the optical fiber conductive slip ring is configured to receive and transmit detection data of the camera on the crimping jig.

6. The camera detection device according to claim 4, wherein a mounting opening is formed in the rotating platform, the mounting opening penetrates through the rotating platform along a thickness direction of the rotating platform, and the optical fiber conductive slip ring penetrates through the mounting opening to be rotatably connected with the base; the rotation axis passes through the mounting opening.

7. The camera detection device according to claim 1, further comprising a driving mechanism, wherein the driving mechanism is connected to the rotary platform, and the driving mechanism is configured to drive the crimping jig on the rotary platform to rotate around the rotation axis;

when the crimping jig rotates to a first position, the camera detection device is used for feeding the camera; when the crimping jig rotates to the second position, the camera detection device is used for testing and correcting the camera; when the crimping jig rotates to a third position, the camera detection device is used for retesting the camera; when the crimping jig rotates to the fourth position, the camera detection device is used for discharging the camera.

8. The camera detecting device according to claim 7, wherein the driving mechanism is configured to drive the crimping jig to rotate around the rotation axis in sequence along the first position, the second position, the third position, and the fourth position.

9. The camera detection device according to claim 8, wherein the first position, the second position, the third position, and the fourth position are sequentially distributed along a rotation direction of the crimping jig.

10. The camera inspection device of claim 8, wherein the first, second, third, and fourth positions are evenly distributed along a circumference of the rotating platform.

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