CN212255132U - Cell-phone glass side defect detection device - Google Patents

Abstract

The invention provides a mobile phone glass side defect detection device, which comprises a camera unit, a side light source unit and a motion unit, and is characterized in that: the movement unit is an XYR three-axis movement platform and is used for bearing mobile phone glass and realizing horizontal, longitudinal and rotary movement in the horizontal direction; the camera unit is used for scanning the side face of the mobile phone glass and is fixed on the base station opposite to the XYR three-axis motion platform; the side light source unit is fixedly arranged on one side of the middle of the camera unit and the XYR three-axis motion platform and provides a light source for the camera unit.

Description

Cell-phone glass side defect detection device

Technical Field

The invention belongs to the field of optical detection, and particularly relates to a device for detecting defects on the side surface of mobile phone glass.

Background

With the increasing demand of people for product quality, the appearance quality becomes an important factor for consumers to select electronic products. The mobile phone cover plate glass is toughened glass, namely tempered glass, wherein a fixed support needs to be placed on the upper surface of the glass in the manufacturing process of the toughened glass to ensure the horizontal parallelism of the glass, but the flatness and the thickness of the glass after toughening treatment are difficult to ensure to be consistent due to the fact that the glass material and the metal fixed support have different material properties and have large difference of expansion coefficients, and various defects such as edge breakage, concave-convex, white spots, pressure injury, scratches, tooth defects, IR black and white spots and the like are easily generated on the surface and the side surface of the toughened glass in the processing and manufacturing process. The existence of various defects of the toughened glass not only affects the appearance of products such as mobile phone cover plate glass, but also affects the service performance of the products as mobile phone cover plates due to serious defects. Therefore, how to detect the defects of the cover plate glass of the mobile phone quickly, efficiently and intelligently not only relates to the development of enterprises, but also has very important significance to all related product industries.

To toughened glass defect detection, although multiple auxiliary detection equipment has appeared on the market at present in succession, but present check out test set mainly used detects the toughened glass surface, does not have efficient detection method to the flank defect always, and the tradition mode is mostly artifical naked eye discernment, and this kind of detection mode detection efficiency is low, and it is big to detect intensity of labour, and the manual work is long-time easily causes visual fatigue, leads to detection efficiency low, causes harmful effects to the follow-up use of product, can't satisfy assembly line batch operation demand.

Disclosure of Invention

In view of the above, the invention provides a mobile phone glass side defect detection device, which can replace manual detection of the side appearance of mobile phone glass, save cost and improve the overall production efficiency, the false detection rate of the mobile phone glass side defect detected by using the device is as low as 1%, the omission factor is only 0.5%, the standard of an automatic production line is completely met, the mobile phone glass side defect detected by using the device can reach 3.5S/piece, and the remarkable progress of manual to automatic conversion is realized.

The specific technical scheme is as follows:

the utility model provides a cell-phone glass side defect detection device, includes camera unit, side light source unit and motion unit, its characterized in that: the movement unit is an XYR three-axis movement platform and is used for bearing mobile phone glass and realizing horizontal, longitudinal and rotary movement in the horizontal direction;

the camera unit is used for scanning the side face of the mobile phone glass and is fixed on the base station opposite to the XYR three-axis motion platform;

the side light source unit is fixedly arranged on one side of the middle of the camera module and the XYR three-axis motion platform and provides a light source for the camera unit.

Further, XYR triaxial motion platform includes X axle module, Y axle module and rotary platform, and the fixed installation of X axle module is in on the base station, the setting of Y axle module activity is in on the X axle module, rotary platform passes through the cavity connecting plate setting and is in on the Y axle module.

Furthermore, an adsorption box is fixedly arranged on the rotary platform; the adsorption box is of a two-stage step structure and comprises a high-order table board and a low-order table board, and a vacuum chuck is arranged in the adsorption box.

Furthermore, platform calibration blocks are movably arranged on the high-order table top of the adsorption box, alignment combinations are fixed on the low-order table top, and the alignment combinations are two groups of positioning blocks which are respectively positioned on two mutually vertical side edges of the high-order table top.

Further, the platform calibration block is installed on the high-order table board through a positioning pin.

Further, all be provided with the sensor on X axle module, the Y axle module and the rotary platform.

Further, the camera unit comprises a line scan camera and a camera support base, and the line scan camera is fixed on the base platform through the camera support base.

Further, the side light source unit comprises a line light source and a supporting table, the line light source is fixedly arranged on the base table through the supporting table, and the line light source can perform vertical lifting motion and horizontal transverse movement on the supporting table to ensure the brightness of the scanning sight of the camera unit.

Furthermore, the Y-axis module comprises a Y-axis movement mechanism and a driving motor, and the Y-axis movement mechanism can be driven by the driving motor to carry out longitudinal movement of the Y axis; the X-axis module comprises an X-axis movement mechanism and a driving motor, and the X-axis movement mechanism can be driven by the driving motor to perform X-axis transverse movement; the rotary platform is connected with a driving motor, and the rotary platform can be driven by the driving motor to rotate around an R axis.

Additional aspects and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a top view of a device for detecting defects on a side surface of a glass of a mobile phone;

FIG. 2 is a right side view of the apparatus for detecting defects on the side of a glass of a mobile phone;

FIG. 3 is a schematic structural view of a device for detecting defects on a side surface of a glass of a mobile phone;

the system comprises a base, a platform, a positioning module, a rotary platform, a platform calibration block, an X-axis module, a Y-axis module, a rotary platform, a Y-axis module, a Y-axis;

2, a camera unit, 21, a line scan camera, and 22, a camera support;

3 is a side light source unit, 31 is a linear light source, and 32 is a support table;

and 4, a control unit.

Detailed Description

The embodiments described below with reference to the drawings are illustrative only and should not be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "back", "inner", "outer", "lateral", "longitudinal", and the like, indicate orientations and positional relationships based on the orientations and positional relationships shown in the drawings, are used for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

Fig. 1 and 2 show a schematic view of an embodiment of the mobile phone glass side defect detection device of the present invention, which is also a schematic view of a preferred embodiment. A mobile phone glass side defect detection device comprises a camera unit 2, a side light source unit 3 and a motion unit, wherein the motion unit is an XYR three-axis motion platform 1 and is used for bearing mobile phone glass and realizing horizontal, longitudinal and rotary motion in the horizontal direction; the camera unit 2 is used for scanning the side surface of the mobile phone glass and is fixed on the base station opposite to the XYR three-axis motion platform 1; the side light source unit 3 is fixedly arranged on one side of the middle of the camera unit 2 and the XYR three-axis motion platform 1 and provides a light source for the camera unit 2.

More specific implementation modes of the invention are specifically developed as follows:

the camera unit 2 includes a line-scan camera 21 and a camera support 22, and the line-scan camera 21 is fixed to the base by the camera support 22. In other embodiments, the line-scan camera 21 may be replaced with an area-array camera.

The side surface light source unit 3 comprises a line light source 31 and a support table 32, the line light source 31 is fixedly arranged on the base table 5 through the support table 32, the line light source 31 can perform vertical lifting movement and horizontal transverse movement on the support table 32, the position of the line light source 31 can be adjusted according to actual detection requirements, and the line scanning camera 21 is guaranteed to be bright constantly when scanning the sight line.

As further shown in fig. 3, the XYR three-axis motion platform 1 includes an X-axis module 11, a Y-axis module 12, and a rotation platform 13, where the Y-axis module 12 includes a Y-axis motion mechanism 121 and a driving motor 18, and the Y-axis motion mechanism 121 can perform Y-axis longitudinal motion under the driving of the driving motor 18; the X-axis module 11 includes an X-axis moving mechanism 111 and a driving motor 18, and the X-axis moving mechanism 111 can perform a lateral movement of the X-axis under the driving of the driving motor 18; the rotating platform 13 is connected with a driving motor 18, and the rotating platform 13 can rotate around the R axis under the driving of the driving motor 18. In the present embodiment, the Y-axis moving mechanism 121 and the X-axis moving mechanism 111 are preferably driven by ball screw, but it is understood that in other embodiments, chain drive, rail drive, etc. may be used to realize longitudinal and transverse movement. Wherein, X axle module 11 is fixed to be installed on base station 5, and Y axle module 12 is movable to be set up on X axle module 11, and rotary platform 13 passes through cavity connecting plate 16 and sets up on Y axle module 12. In the detection process, the mobile phone glass is placed on the rotating platform 13, the linear scanning camera 21 and the linear light source 31 are kept static, the appearance condition of the side surface of the mobile phone glass is detected through XYR three-axis linkage, the rotating platform 13 can be rotated and finely adjusted in the horizontal direction, the three-axis linkage ensures that the distance between the lens of the linear scanning camera 21 and the periphery of the mobile phone glass is always within a tolerance range of plus or minus 0.1, and the linear speed of linear scanning is ensured to be uniform.

The adsorption box 17 is fixedly arranged on the rotary platform 13; the adsorption box 17 is a two-stage step structure, and comprises a high-order table top and a low-order table top, and a vacuum chuck is arranged in the adsorption box. The platform calibration block 14 is movably arranged on the high-order table top of the adsorption box 17 through a positioning pin, the platform calibration block 14 is the same as the mobile phone glass to be detected in size, and the central position of the mobile phone glass product is calibrated through the platform calibration block 14 before detection. The alignment combination 15 is fixed on the low-order table top, the alignment combination 15 is two groups of positioning blocks 151 which are respectively positioned on two mutually perpendicular side edges of the high-order table top, and the positioning blocks 151 are used for positioning the placing position of the mobile phone glass on the rotary platform 13, so that the mobile phone glass is not deflected in the detection process.

Further, the process of detecting the mobile phone glass by the mobile phone glass side surface defect detection device is as follows: firstly, placing the platform calibration block 14 on the adsorption box 17, and positioning by using a pin hole, wherein the center of the platform calibration block 14 is coincided with the rotation center of the rotating platform 13; secondly, the alignment assembly 15 is tightly attached to the high-order table top of the adsorption box 17, a positioning block 151 on the alignment assembly 15 is adjusted, the positioning block 151 is just contacted with two mutually vertical side edges of the platform calibration block 14, and the positioning block 151 is fastened; removing the platform calibration block 14 and the positioning pin, and putting the mobile phone glass to be detected, so that the center of the mobile phone glass is superposed with the rotation center of the rotating platform 13; and fourthly, sucking the vacuum of the auxiliary box 17, removing the alignment combination 15, and starting the XYR three-axis linkage side detection.

Sensors are arranged on the X-axis module 11, the Y-axis module 12 and the rotary platform 13 and used for monitoring and feeding back the movement positions and states of the X-axis module 11, the Y-axis module 12 and the rotary platform 13.

In addition, it should be noted that the device for detecting defects on the side surface of the mobile phone glass further includes a control unit 4, the XYR three-axis motion platform 1, the camera unit 2, and the side light source unit 3 need to be electrically connected thereto, and complete the whole detection work under the control of the control unit.

Any reference in this specification to "this embodiment," "other embodiments," etc., means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. This schematic representation in various places throughout this specification does not necessarily refer to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.

While specific embodiments of the invention have been described in detail with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this invention. In particular, reasonable variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the foregoing disclosure, the drawings and the appended claims without departing from the spirit of the invention. Except variations and modifications in the component parts and/or arrangements, the scope of which is defined by the appended claims and equivalents thereof.

Claims (9)

1. The utility model provides a cell-phone glass side defect detection device, includes camera unit, side light source unit and motion unit, its characterized in that: the movement unit is an XYR three-axis movement platform and is used for bearing mobile phone glass and realizing horizontal, longitudinal and rotary movement in the horizontal direction;

the camera unit is used for scanning the side face of the mobile phone glass and is fixed on the base station opposite to the XYR three-axis motion platform;

the side light source unit is fixedly arranged on one side of the middle of the camera unit and the XYR three-axis motion platform and provides a light source for the camera unit.

2. The mobile phone glass side defect detection device of claim 1, wherein the XYR three-axis motion platform comprises an X-axis module, a Y-axis module and a rotary platform, the X-axis module is fixedly installed on the base, the Y-axis module is movably arranged on the X-axis module, and the rotary platform is arranged on the Y-axis module through a hollow connecting plate.

3. The mobile phone glass side defect detection device of claim 2, wherein an adsorption box is fixedly arranged on the rotary platform; the adsorption box is of a two-stage step structure and comprises a high-order table board and a low-order table board, and a vacuum chuck is arranged in the adsorption box.

4. The mobile phone glass side defect detection device of claim 3, wherein a platform calibration block is movably arranged on the high-order platform surface of the adsorption box, an alignment combination is fixed on the low-order platform surface, and the alignment combination comprises two groups of positioning blocks which are respectively positioned on two mutually vertical side edges of the high-order platform surface.

5. The device for detecting the defects on the side surfaces of the mobile phone glass according to claim 4, wherein the platform calibration block is installed on the high-order table top through a positioning pin.

6. The mobile phone glass side defect detection device of claim 2, wherein sensors are disposed on the X-axis module, the Y-axis module and the rotary platform.

7. The apparatus of claim 1, wherein the camera unit comprises a line scan camera and a camera support, and the line scan camera is fixed on the base platform through the camera support.

8. The device for detecting the defects on the side surface of the mobile phone glass as claimed in claim 1, wherein the side surface light source unit comprises a line light source and a support platform, the line light source is fixedly arranged on the base platform through the support platform, and the line light source can perform vertical lifting movement and horizontal transverse movement on the support platform, so that the brightness of the scanning line light of the camera unit is ensured.

9. The mobile phone glass side defect detection device of any one of claims 2-6, wherein the Y-axis module comprises a Y-axis motion mechanism and a driving motor, and the Y-axis motion mechanism can be driven by the driving motor to perform Y-axis longitudinal motion; the X-axis module comprises an X-axis movement mechanism and a driving motor, and the X-axis movement mechanism can be driven by the driving motor to perform X-axis transverse movement; the rotary platform is connected with a driving motor, and the rotary platform can be driven by the driving motor to rotate around an R axis.

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