CN114710656A - Camera module Flare device and method and electronic device - Google Patents

Abstract

The invention discloses a Flare device, a method and an electronic device for a camera module, belonging to the technical field of camera module testing, comprising a base, a lifting mechanism, a swing mechanism and a bearing platform. A wheel structure, a fastening seat, a rotating seat and an adjustment table, the first direct-drive synchronous wheel structure is installed on the fastening seat, the fastening seat is fixed on the base, and the rotating seat is movably installed on the The fastening seat, the rotating seat and the first direct drive synchronous wheel structure are connected by a first transmission belt, so as to drive the first transmission belt through the first direct drive synchronous wheel structure to drive the rotating seat to rotate ; The adjusting table is detachably installed on the rotating seat, and the rotating seat is located between the adjusting table and the fastening seat; the swing mechanism includes a support table, a deceleration motor, a second direct-drive synchronous wheel structure and a swing arm , the support table is fixed on the base. The invention achieves the technical effects of improving the stability of the test and improving the test efficiency.

Description

A kind of device, method and electronic device for camera module Flare

technical field

The invention belongs to the technical field of camera module testing, and particularly relates to a Flare device, a method and an electronic device for a camera module.

Background technique

The camera lens is composed of multiple lenses, which are made of glass or plastic materials, and the surface of the lens will reflect part of the incident light. When strong light enters the lens, the light reflected by the surface of each lens will be reflected multiple times inside the lens and the camera, resulting in "flare", which is Flare. In the manufacturing process of the camera module, the Flare test is an essential link.

At present, in the existing camera module testing technology, it is usually limited by equipment structure problems, and the requirements of stray light and ghosting cannot be realized in the module automatic test. The existing Flare test can only manually adjust different scenes and multiple times. Turning the equipment to complete the test requirements of module ghosting and stray light requires a lot of labor and time. Relying on manual experience to adjust the position of the strong point light source and the camera module makes the test stability poor, the test efficiency is low, and the product test cycle is long. Management is difficult.

To sum up, in the existing camera module testing technology, there are technical problems of poor stability and low testing efficiency.

SUMMARY OF THE INVENTION

The technical problems to be solved by the present invention are the technical problems of poor stability and low test efficiency.

In order to solve the above technical problems, the present invention provides a Flare equipment for a camera module, the equipment includes: a base, a lifting mechanism, a swing mechanism and a bearing platform, and the lifting mechanism includes a first direct-drive synchronous wheel structure, A fastening seat, a rotating seat and an adjustment table, the first direct-drive synchronous wheel structure is installed on the fastening seat, the fastening seat is fixed on the base, and the rotating seat is movably installed on the fastening seat. a fixing seat, the rotating seat and the first direct drive synchronous wheel structure are connected by a first transmission belt, so that the first transmission belt is driven by the first direct drive synchronous wheel structure to drive the rotating seat to rotate; the The adjusting table is detachably installed on the rotating seat, and the rotating seat is located between the adjusting table and the fastening seat; the swing mechanism includes a support table, a deceleration motor, a second direct-drive synchronous wheel structure and a swing The support table is fixed on the base; the reduction motor is installed on the support table; the reduction motor is structurally connected to the second direct drive synchronous wheel; the swing arm is connected to the second direct drive The drive synchronizing wheel structure is connected to drive the second direct-drive synchronizing wheel structure to drive the swing arm to swing; the bearing platform is connected to the swing arm, and the bearing platform is located in the swing arm. between the arm and the adjustment table.

Further, the rotating seat and the adjusting table are detachably connected by bolts.

Further, the swing mechanism further includes: a vertical correction rod, the vertical correction rod is installed on the support table, the vertical correction rod is perpendicular to the support table, and the length of the vertical correction rod is smaller than the swing arm length.

Further, the swing arm is provided with a clamping groove; the bearing platform is clamped in the clamping groove.

Further, the reduction motor and the second direct-drive synchronous wheel structure are connected by a second transmission belt.

Further, the second direct drive synchronous wheel structure is parallel to the swing arm, the second direct drive synchronous wheel structure and the swing arm are fixedly connected by a connecting shaft, and the second direct drive synchronous wheel structure is connected by a connecting shaft. The connecting shaft drives the swing arm to swing.

Further, the swing arm is located between the reduction motor and the carrying platform.

According to yet another aspect of the present invention, the present invention also provides a Flare method for a camera module, the method comprising: feeding a test object to an adjustment table and placing a strong point light source on a bearing table, the test object comprising: Camera module; drive the rotating seat through the first direct drive synchronous wheel structure to drive the adjustment table to perform the rotation test within the rotation test angle range, the rotation test angle range is 0° to 360°; drive the second direct drive through the deceleration motor The synchronous wheel structure is used to drive the swing arm to perform the swing test within the swing test angle range, and the swing test angle range is 0° to 180°.

According to another aspect of the present invention, the present invention also provides an electronic device for a camera module Flare, comprising a memory, a processor and a computer program stored in the memory and running on the processor, the processor executing During the procedure, the following steps are implemented: feeding the test object to the adjustment table and placing the strong point light source on the bearing table, the test object including a camera module; driving the adjustment table by driving the rotating seat through the first direct drive synchronous wheel structure The rotation test is carried out within the rotation test angle range, and the rotation test angle range is 0° to 360°; the second direct drive synchronous wheel structure is driven by the deceleration motor to drive the swing arm to perform the swing test within the swing test angle range. The swing test angle range is 0° to 180°.

According to another aspect of the present invention, the present invention also provides a computer-readable storage medium for the camera module Flare, on which a computer program is stored, and when the program is executed by the processor, the following steps are implemented: feeding the test object. To the adjustment table and place the strong point light source on the bearing table, the test object includes a camera module; the first direct drive synchronous wheel structure drives the rotating base to drive the adjustment table to perform a rotation test within the rotation test angle range. The test angle range is 0° to 360°; the second direct drive synchronous wheel structure is driven by the deceleration motor to drive the swing arm to perform the swing test within the swing test angle range, and the swing test angle range is 0° to 180°.

Beneficial effects:

The invention provides a Flare device for a camera module, which is installed on a fastening seat through a first direct-drive synchronous wheel structure in the lifting mechanism, the fastening seat is fixed on the base, the rotating seat is movably installed on the fastening seat, and the rotating seat It is connected with the first direct drive synchronous wheel structure through a first transmission belt, so as to drive the first transmission belt through the first direct drive synchronous wheel structure to drive the rotating base to rotate. The adjusting table is detachably mounted on the rotating seat, and the rotating seat is located between the adjusting table and the fastening seat. In the swing mechanism, a support table is fixed on the base, a deceleration motor is installed on the support table, the deceleration motor is structurally connected to the second direct-drive synchronizing wheel, and the swing arm and the second direct-drive synchronizing wheel are structurally connected. The structure is connected to drive the second direct-drive synchronous wheel structure through the deceleration motor to drive the swing arm to swing. The bearing platform is connected with the swing arm, and the bearing platform is located between the swing arm and the adjustment platform. In this way, when the camera module needs to be Flare tested, the camera module is placed on the adjustment table, and the first direct drive synchronous wheel structure is rotated so that the adjustment table drives the camera module to rotate to the required angle position, and then The strong point light source is placed on the bearing platform installed on the swing arm, and the second direct drive synchronous wheel structure is driven by the deceleration motor to drive the swing arm to swing, so as to realize the Flare test of the camera module. Then it can improve the stability of the test and improve the test efficiency. In this way, the technical effect of improving the stability of the test and improving the test efficiency is achieved.

Description of drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the accompanying drawings required in the embodiments will be briefly introduced below. Obviously, the drawings in the following description are only some of the present invention. In the embodiments, for those of ordinary skill in the art, other drawings can also be obtained according to these drawings without any creative effort.

1 is a schematic diagram 1 of a Flare device for a camera module provided by an embodiment of the present invention;

2 is a schematic diagram 2 of a Flare device for a camera module provided by an embodiment of the present invention;

3 is a schematic diagram 3 of a Flare device for a camera module provided by an embodiment of the present invention;

4 is a schematic diagram 4 of a Flare device for a camera module provided by an embodiment of the present invention;

5 is a schematic diagram 5 of a Flare device for a camera module provided by an embodiment of the present invention;

6 is a schematic diagram 6 of a Flare device for a camera module provided by an embodiment of the present invention;

7 is a flowchart of a method for Flare of a camera module provided by an embodiment of the present invention;

8 is a structural diagram of an electronic device for a camera module Flare provided by an embodiment of the present invention;

FIG. 9 is a structural diagram of a computer-readable storage medium for a camera module Flare according to an embodiment of the present invention.

Detailed ways

The invention discloses a Flare device for a camera module, which is installed on a fastening seat 25 through a first direct drive synchronous wheel structure 21 in the lifting mechanism, the fastening seat 25 is fixed on the base 1, and the rotating seat 22 is movably installed on the The fastening seat 25 , the rotating seat 22 and the first direct drive synchronous wheel structure 21 are connected by the first transmission belt 23 , so as to drive the rotating seat 22 to rotate by driving the first transmission belt 23 through the first direct drive synchronous wheel structure 21 . The adjusting table 24 is detachably mounted on the rotating seat 22 , and the rotating seat 22 is located between the adjusting table 24 and the fastening seat 25 . In the swing mechanism, the support table 31 is fixed on the base 1 , the deceleration motor 32 is installed on the support table 31 , the deceleration motor 32 is connected with the second direct drive synchronous wheel structure 33 , and the swing arm 34 is connected to the support table 31 . The second direct-drive synchronous wheel structure 33 is connected to drive the second direct-drive synchronous wheel structure 33 through the reduction motor 32 to drive the swing arm 34 to swing. The bearing platform 4 is connected to the swing arm 34 , and the bearing platform 4 is located between the swing arm 34 and the adjustment platform 24 . In this way, in the process of performing the Flare test on the camera module, the camera module is placed on the adjustment table 24, and the first direct drive synchronous wheel structure 21 is rotated so that the adjustment table 24 drives the camera module to rotate to the required angular position Then, the strong point light source is placed on the bearing platform 4 installed on the swing arm 34, and the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to swing, so as to realize the Flare test on the camera module. Then it can improve the stability of the test and improve the test efficiency. In this way, the technical effect of improving the stability of the test and improving the test efficiency is achieved.

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, but not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art fall within the protection scope of the present invention; wherein the keyword "and/or" involved in this implementation means and or both In other words, A and/or B mentioned in the embodiments of the present invention represent two situations of A and B, A or B, and describe the three states that A and B exist, such as A and/or B, means: only include A but not B; only include B but not A; include A and B.

It will be understood that, although the terms "first", "second", etc. may be used herein to describe various elements, components, regions, layers and/or sections, these elements, components, regions, layers and/or sections should not be subject to these terms. These terms are only used to distinguish one element, component, region, layer or section from another element, component, region, layer or section. Thus, a first element, component, region, layer or section discussed below could be termed a second element, component, region, layer or section without departing from the teachings of the example embodiments. Spatially relative terms, such as "below", "above", etc., may be used herein to facilitate describing one element or feature's relationship to another element or feature. It will be understood that spatially relative terms encompass different orientations of the device in use or operation in addition to the orientation shown in the figures. For example, if the device in the figures is turned over, elements or features described as "below" would then be oriented "above" the other elements or features. Thus, the exemplary term "below" can encompass both an orientation of above and below. The device may be oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

Meanwhile, in the embodiment of the present invention, when a component is referred to as being "fixed to" another component, it may be directly on the other component or there may also be a central component. When a component is considered to be "connected" to another component, it may be directly connected to the other component or there may be a co-existence of an intervening component. When a component is considered to be "set on" another component, it may be directly set on the other component or there may be a co-existing centered component. The terms "vertical", "horizontal", "left", "right" and similar expressions used in the embodiments of the present invention are only for the purpose of illustration and are not intended to limit the present invention.

Example 1

Please refer to FIG. 1, FIG. 2, FIG. 3, FIG. 4, FIG. 5 and FIG. 6. FIG. 1 is a schematic diagram 1 of a Flare device for a camera module provided by an embodiment of the present invention, and FIG. 2 is provided by an embodiment of the present invention. A schematic diagram 2 of a Flare device for a camera module, FIG. 3 is a schematic diagram 3 of a Flare device for a camera module provided by an embodiment of the present invention, and FIG. 4 is a schematic diagram of a camera module provided by an embodiment of the present invention. Schematic diagram four of a module Flare device, FIG. 5 is a schematic diagram of a camera module Flare device provided by an embodiment of the present invention, and FIG. 6 is a schematic diagram of a camera module Flare device provided by an embodiment of the present invention. six. A Flare device for a camera module provided by an embodiment of the present invention includes a base 1, a lifting mechanism, a swing mechanism, and a bearing platform 4. The base 1, the lifting mechanism, the swing mechanism, and the bearing platform 4 will now be described in detail. :

For base 1 and lift mechanism:

The lifting mechanism includes a first direct drive synchronous wheel structure 21 , a fastening seat 25 , a rotating seat 22 and an adjustment table 24 , the first direct drive synchronous wheel structure 21 is mounted on the fastening seat 25 , and the fastening seat 25 Fixed on the base 1, the rotating seat 22 is movably installed on the fastening seat 25, the rotating seat 22 and the first direct drive synchronous wheel structure 21 are connected by the first transmission belt 23, so as to pass the The first direct drive synchronous wheel structure 21 drives the first transmission belt 23 to drive the rotating base 22 to rotate; the adjusting table 24 is detachably mounted on the rotating base 22, and the rotating base 22 is located in the adjusting base 22. between the table 24 and the fastening seat 25 . Wherein, the rotating base 22 and the adjusting table 24 are detachably connected by bolts.

Specifically, the base 1 has a space for accommodating the rotating base 22 , the support table 31 , the second direct-drive synchronizing wheel structure 33 , the swing arm 34 and the vertical alignment rod 35 . In the lifting mechanism, the fastening seat 25 is fixedly mounted on the base 1 , and the base 1 provides support for the fastening seat 25 . The fastening seat 25 can be provided with an opening for placing the rotating seat 22, and the rotating seat 22 can be rotated in the opening. The seat 22 can be rotated within the opening. The rotating base 22 may be in a circular shape, and a groove for placing the first transmission belt 23 may be provided on the outer side of the rotating base 22 , so that the first transmission belt 23 is embedded in the groove. The first direct drive synchronous wheel structure 21 can be a grooved runner, the runner is rotatably mounted on the fastening seat 25 through the central axis, and the first transmission belt 23 can be embedded in the groove on the outside of the runner. The first direct drive synchronous wheel structure 21 can be connected with the rotating shaft of the motor, and the first direct drive synchronous wheel structure 21 is driven to rotate by the rotating shaft of the motor, and the rotating first direct drive synchronous wheel structure 21 can drive the first transmission belt 23 to rotate , the rotating first transmission belt 23 can drive the rotating base 22 to rotate, and the rotating rotating base 22 can drive the adjusting table 24 to rotate. The camera module can be placed on the adjustment table 24. For example, a vacuum adsorption device can be installed on the adjustment table 24, and the camera module can be adsorbed by the vacuum adsorption device. In this way, the end face of the product lens can be adsorbed by vacuum suction, which can avoid manual contact with the lens. The lens end face is scratched. During the rotation of the adjusting table 24, the camera module can be driven to perform a rotation test within the required rotation test angle range. The rotation test angle range can be 0° to 360°. If the rotation test angle is R1, then 0° ≤R1≤360°. The first direct drive synchronous wheel structure 21 can be driven to rotate to a certain angle by the rotating shaft of the motor, so that the camera module located on the adjustment table 24 can be rotated to the required rotation test angle. In addition, the adjustment table 24 can also adopt a split structure, the top end and the bottom end of the adjustment table 24 are connected by a threaded adjustment handle, and the distance between the two ends of the adjustment table 24 is adjusted by rotating the threaded adjustment handle to realize During the process of rotating the threaded adjustment handle, the height of the top end is adjusted, so that the camera module located on the top end of the adjustment table 24 can be adjusted to the required test height.

For the swing mechanism:

The swing mechanism includes a support table 31, a reduction motor 32, a second direct drive synchronous wheel structure 33, a swing arm 34 and a vertical alignment rod 35. The support table 31 is fixed on the base 1; the reduction motor 32 is installed on the the support table 31 ; the deceleration motor 32 is connected to the second direct drive synchronous wheel structure 33 ; the swing arm 34 is connected to the second direct drive synchronous wheel structure 33 to drive the The second direct-drive synchronous wheel structure 33 drives the swing arm 34 to swing. The vertical correction rod 35 is installed on the support table 31 , the vertical correction rod 35 is perpendicular to the support table 31 , and the length of the vertical correction rod 35 is smaller than the length of the swing arm 34 . During the swinging process of the swing arm 34 , the swing amplitude of the swing arm 34 can be observed by observing and measuring the angle at which the swing arm 34 deviates from the vertical correction rod 35 . Wherein, the swing arm 34 is provided with a clamping slot; the bearing platform 4 is clamped in the clamping slot. The reduction motor 32 and the second direct drive synchronous wheel structure 33 are connected by a second transmission belt 36 . The second direct drive synchronous wheel structure 33 and the swing arm 34 are parallel to each other, the second direct drive synchronous wheel structure 33 and the swing arm 34 are fixedly connected by a connecting shaft, and the second direct drive synchronous wheel structure 33 and the swing arm 34 are fixedly connected. 33 drives the swing arm 34 to swing through the connection shaft. The swing arm 34 is located between the deceleration motor 32 and the bearing platform 4 . The bearing platform 4 is connected to the swing arm 34 , and the bearing platform 4 is located between the swing arm 34 and the adjustment platform 24 .

Specifically, the support table 31 in the swing mechanism can be fixedly installed on the base 1 . The deceleration motor 32 can be installed on the support table 31. For example, an L-shaped fastener can be arranged between the deceleration motor 32 and the support table 31, and the bottom of the L-shaped fastener is installed on the support table 31 to reduce the speed. The rotating shaft of the motor 32 passes through the top of the L-shaped fastener, and the rotating shaft of the deceleration motor 32 can be connected to the second direct drive synchronous wheel structure 33 after passing through the top of the L-shaped fastener, and the deceleration motor 32 can drive the second direct drive The synchronous wheel structure 33 rotates. For example, the second direct-drive synchronous wheel structure 33 may include two moving wheels, a smaller moving wheel is connected with the rotating shaft of the deceleration motor 32, and the other larger moving wheel is movably installed on the L-shaped tight end. In the middle of the firmware, the reduction motor 32 and the second direct drive synchronous wheel structure 33 are connected by the second transmission belt 36, which means that the second transmission belt 36 is embedded in the outer groove of the smaller driving wheel and the larger driving wheel respectively. inside the outer groove. When the rotating shaft of the reduction motor 32 drives the smaller moving wheel to rotate, the smaller moving wheel will drive the second transmission belt 36 to pull the larger moving wheel to rotate. The larger moving wheel and the bottom of the swing arm 34 are fixedly connected by a connecting shaft, that is, the rotation of the larger moving wheel can drive the swing arm 34 to rotate. In this way, the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to perform the swing test within the swing test angle range. The swing test angle range can be 0° to 180°, and the swing test angle can be R2, then 0 °≤R2≤180°.

It should be noted that a snap groove may be provided along the length direction of the swing arm 34, the snap groove may include a plurality of snap grooves, and one end of the bearing platform 4 may be provided with a protrusion matching the snap groove. Head, the bearing platform 4 can be snapped into the clamping groove at the corresponding height position through the protruding head, so that the bearing platform 4 is fixed at the height position, and the bearing platform 4 can be provided with a space for placing a strong point light source, It is realized that the strong point light source is installed on the carrying platform 4 . In this way, when the strong light enters the lens, the strong point light source is moved to the required swing angle by the swing arm 34 within the swing test angle range, and the camera module is rotated to the desired swing angle by the adjustment table 24 within the rotation test angle range. the required rotation test angle. There is no need to manually adjust the position of the strong point light source and the camera module, which can improve the stability of the test and improve the efficiency of the test.

The present invention provides a Flare device for a camera module. The first direct-drive synchronous wheel structure 21 in the lifting mechanism is installed on the fastening seat 25, the fastening seat 25 is fixed on the base 1, and the rotating seat 22 is movably installed on the fastening seat 25. The fixing base 25 , the rotating base 22 and the first direct drive synchronous wheel structure 21 are connected by the first transmission belt 23 , so as to drive the rotating base 22 to rotate by driving the first transmission belt 23 through the first direct drive synchronous wheel structure 21 . The adjusting table 24 is detachably mounted on the rotating seat 22 , and the rotating seat 22 is located between the adjusting table 24 and the fastening seat 25 . In the swing mechanism, the support table 31 is fixed on the base 1 , the deceleration motor 32 is installed on the support table 31 , the deceleration motor 32 is connected with the second direct drive synchronous wheel structure 33 , and the swing arm 34 is connected to the support table 31 . The second direct-drive synchronous wheel structure 33 is connected to drive the second direct-drive synchronous wheel structure 33 through the reduction motor 32 to drive the swing arm 34 to swing. The bearing platform 4 is connected to the swing arm 34 , and the bearing platform 4 is located between the swing arm 34 and the adjustment platform 24 . In this way, in the process of performing the Flare test on the camera module, the camera module is placed on the adjustment table 24, and the first direct drive synchronous wheel structure 21 is rotated so that the adjustment table 24 drives the camera module to rotate to the required angular position Then, the strong point light source is placed on the bearing platform 4 installed on the swing arm 34, and the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to swing, so as to realize the Flare automatic test on the camera module. Then it can improve the stability of the test and improve the test efficiency. In this way, the technical effect of improving the stability of the test and improving the test efficiency is achieved.

In order to provide a detailed description of a method for Flare used in a camera module provided by the present invention, the above embodiment provides a detailed description of a device used for Flare in a camera module. Based on the same inventive concept, the present application also provides a For the Flare method of the camera module, see Embodiment 2 for details.

Embodiment 2

Please refer to FIG. 7. FIG. 7 is a flowchart of a method for Flare of a camera module provided by an embodiment of the present invention. Embodiment 2 of the present invention provides a method for Flare of a camera module, including:

Step S100, feeding the test object to the adjustment table 24 and placing the strong point light source on the bearing table 4, the test object including a camera module;

Step S110, the first direct drive synchronous wheel structure 21 drives the rotating base 22 to drive the adjustment table 24 to perform a rotation test within a rotation test angle range, and the rotation test angle range is 0° to 360°;

In step S120, the second direct-drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to perform swing test within the swing test angle range, and the swing test angle range is 0° to 180°.

The present invention provides a Flare method for a camera module, feeding a test object to the adjustment table 24 and placing a strong point light source on the bearing table 4, the test object includes a camera module; through the first direct drive synchronous wheel structure 21 drives the rotary base 22 to drive the adjustment table 24 to perform a rotation test within the range of the rotation test angle, and the range of the rotation test angle is 0° to 360°; the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 Perform a swing test within a swing test angle range of 0° to 180°. In this way, in the process of performing the Flare test on the camera module, the camera module is placed on the adjustment table 24, and the first direct drive synchronous wheel structure 21 is rotated so that the adjustment table 24 drives the camera module to rotate to the required angular position Then, the strong point light source is placed on the bearing platform 4 installed on the swing arm 34, and the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to swing, so as to realize the Flare test on the camera module. Then it can improve the stability of the test and improve the test efficiency. In this way, the technical effect of improving the stability of the test and improving the test efficiency is achieved.

In order to provide an electronic device for the camera module Flare provided by the present invention, the above embodiment has described in detail one device for the camera module Flare. Based on the same inventive concept, the present application also provides an electronic device for the camera module Flare. For the electronic equipment of the camera module Flare, see Example 3 for details.

Embodiment 3

Please refer to FIG. 8. FIG. 8 is a structural diagram of an electronic device for a camera module Flare according to an embodiment of the present invention. The third embodiment of the present invention provides an electronic device for a camera module Flare, including a memory 310, a processor 320, and a computer program 311 stored in the memory 310 and running on the processor 320, and the processor 320 executes The described procedure implements the following steps:

The test object is loaded to the adjustment table 24 and the strong point light source is placed on the bearing table 4, and the test object includes a camera module;

The rotating base 22 is driven by the first direct-drive synchronous wheel structure 21 to drive the adjustment table 24 to perform a rotation test within a rotation test angle range, and the rotation test angle range is 0° to 360°;

The second direct-drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to perform the swing test within the swing test angle range, and the swing test angle range is 0° to 180°.

The present invention provides an electronic device for the camera module Flare, the test object is fed to the adjustment table 24 and the strong point light source is placed on the bearing table 4, and the test object includes the camera module; through the first direct drive synchronization The wheel structure 21 drives the rotating base 22 to drive the adjustment table 24 to perform a rotation test within the rotation test angle range, and the rotation test angle range is 0° to 360°; the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 The swing arm 34 performs a swing test within a swing test angle range of 0° to 180°. In this way, in the process of performing the Flare test on the camera module, the camera module is placed on the adjustment table 24, and the first direct drive synchronous wheel structure 21 is rotated so that the adjustment table 24 drives the camera module to rotate to the required angular position Then, the strong point light source is placed on the bearing platform 4 installed on the swing arm 34, and the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to swing, so as to realize the Flare test on the camera module. Then it can improve the stability of the test and improve the test efficiency. In this way, the technical effect of improving the stability of the test and improving the test efficiency is achieved.

In order to provide a computer-readable storage medium for a camera module Flare provided by the present invention, the above-mentioned embodiments describe in detail one device for a camera module Flare. Based on the same inventive concept, the present application also provides a A computer-readable storage medium for the camera module Flare, see Embodiment 4 for details.

Embodiment 4

Please refer to FIG. 9. FIG. 9 is a structural diagram of a computer-readable storage medium 400 for a camera module Flare according to an embodiment of the present invention. The fourth embodiment of the present invention provides a computer-readable storage medium 400 for a camera module Flare, on which a computer program 411 is stored, and when the program is executed by a processor, the following steps are implemented:

The test object is loaded to the adjustment table 24 and the strong point light source is placed on the bearing table 4, and the test object includes a camera module;

The rotating base 22 is driven by the first direct-drive synchronous wheel structure 21 to drive the adjustment table 24 to perform a rotation test within a rotation test angle range, and the rotation test angle range is 0° to 360°;

The second direct-drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to perform the swing test within the swing test angle range, and the swing test angle range is 0° to 180°.

The present invention provides a computer-readable storage medium 400 for the camera module Flare, the test object is loaded on the adjustment table 24 and the strong point light source is placed on the bearing table 4, and the test object includes the camera module; The direct drive synchronous wheel structure 21 drives the rotating base 22 to drive the adjustment table 24 to perform a rotation test within the range of the rotation test angle, and the rotation test angle range is 0° to 360°; the second direct drive synchronous wheel is driven by the deceleration motor 32 The structure 33 drives the swing arm 34 to perform the swing test within the swing test angle range, and the swing test angle range is 0° to 180°. In this way, in the process of performing the Flare test on the camera module, the camera module is placed on the adjustment table 24, and the first direct drive synchronous wheel structure 21 is rotated so that the adjustment table 24 drives the camera module to rotate to the required angular position Then, the strong point light source is placed on the bearing platform 4 installed on the swing arm 34, and the second direct drive synchronous wheel structure 33 is driven by the deceleration motor 32 to drive the swing arm 34 to swing, so as to realize the Flare test on the camera module. Then it can improve the stability of the test and improve the test efficiency. In this way, the technical effect of improving the stability of the test and improving the test efficiency is achieved.

Finally, it should be noted that the above specific embodiments are only used to illustrate the technical solutions of the present invention and not to limit them. Although the present invention has been described in detail with reference to examples, those of ordinary skill in the art should understand that the technical solutions of the present invention can be Modifications or equivalent substitutions without departing from the spirit and scope of the technical solutions of the present invention should be included in the scope of the claims of the present invention.

Claims (10)

1. A Flare device for a camera module, characterized in that it comprises: the lifting mechanism comprises a first direct-drive synchronous wheel structure, a fastening seat, a rotating seat and an adjusting platform, the first direct-drive synchronous wheel structure is mounted on the fastening seat, the fastening seat is fixed on the base, the rotating seat is movably mounted on the fastening seat, and the rotating seat and the first direct-drive synchronous wheel structure are connected through a first transmission belt so as to drive the first transmission belt to drive the rotating seat to rotate through the first direct-drive synchronous wheel structure; the adjusting platform is detachably arranged on the rotating seat, and the rotating seat is positioned between the adjusting platform and the fastening seat; the swing mechanism comprises a supporting platform, a speed reducing motor, a second direct-drive synchronous wheel structure and a swing arm, and the supporting platform is fixed on the base; the speed reducing motor is arranged on the support platform; the speed reducing motor is structurally connected with the second direct-drive synchronous wheel; the swing arm is connected with the second direct-drive synchronous wheel structure so as to drive the second direct-drive synchronous wheel structure to drive the swing arm to swing through the speed reduction motor; the plummer with the swing arm is connected, the plummer is located the swing arm with between the regulation platform.

2. Flare apparatus for camera modules according to claim 1, characterized in that:

the rotary seat and the adjusting platform are detachably connected through bolts.

3. The apparatus for camera module Flare according to claim 1, wherein the swing mechanism further comprises:

the vertical correcting rod is arranged on the supporting platform, the vertical correcting rod is perpendicular to the supporting platform, and the length of the vertical correcting rod is smaller than that of the swinging arm.

4. Flare apparatus for camera module according to claim 1, characterized in that:

the swing arm is provided with a clamping groove; the bearing table is clamped in the clamping groove.

5. Flare apparatus for camera modules according to claim 1, characterized in that:

and the speed reducing motor is connected with the second direct-drive synchronous wheel structure through a second transmission belt.

6. Flare apparatus for camera modules according to claim 1, characterized in that:

the second directly drives the synchronizing wheel structure with the swing arm parallels, the second directly drives the synchronizing wheel structure with the swing arm passes through connecting axle fixed connection, the second directly drives the synchronizing wheel structure and passes through the connecting axle drives the swing arm swings.

7. Flare apparatus for camera modules according to claim 1, characterized in that:

the swing arm is located between the speed reduction motor and the bearing table.

8. A method for camera module Flare, the method comprising:

loading a test object to an adjusting table and placing a strong point light source on a bearing table, wherein the test object comprises a camera module;

the first direct-drive synchronous wheel structure drives the rotating seat to drive the adjusting table to perform a rotation test within a rotation test angle range, wherein the rotation test angle range is 0-360 degrees;

the second direct-drive synchronous wheel structure is driven by the speed reduction motor to drive the swing arm to perform swing test within a swing test angle range, wherein the swing test angle range is 0-180 degrees.

9. An electronic device for a camera module Flare, comprising a memory, a processor and a computer program stored on the memory and executable on the processor, wherein the processor implements the following steps when executing the program:

loading a test object to an adjusting table and placing a strong point light source on a bearing table, wherein the test object comprises a camera module;

the first direct-drive synchronous wheel structure drives the rotating seat to drive the adjusting table to perform a rotation test within a rotation test angle range, wherein the rotation test angle range is 0-360 degrees;

the second direct-drive synchronous wheel structure is driven by the speed reduction motor to drive the swing arm to perform swing test within a swing test angle range, wherein the swing test angle range is 0-180 degrees.

10. A computer-readable storage medium for a camera module Flare, on which a computer program is stored, which program, when executed by a processor, performs the steps of:

loading a test object to an adjusting table and placing a strong point light source on a bearing table, wherein the test object comprises a camera module;

the first direct-drive synchronous wheel structure drives the rotating seat to drive the adjusting table to perform a rotation test within a rotation test angle range, wherein the rotation test angle range is 0-360 degrees;

the second direct-drive synchronous wheel structure is driven by the speed reduction motor to drive the swing arm to perform swing test within a swing test angle range, wherein the swing test angle range is 0-180 degrees.

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