CN217637208U - Ceramic tile size detection device - Google Patents

Abstract

The utility model provides a pottery brick size detection device, include: the fixed bracket is used for fixedly supporting a sample to be tested along the horizontal direction; the first movable support is provided with a first photoelectric sensor; the second movable support is provided with a second photoelectric sensor; and a third movable support provided with a third photoelectric sensor. After the sample to be detected is horizontally placed on the fixed support, when the corresponding movable support moves to the preset position corresponding to the photoelectric sensor, the photoelectric sensor can automatically read and obtain a result, the operation process is relatively simple, and the improvement of the detection efficiency is facilitated.

Description

Ceramic tile size detection device

Technical Field

The utility model relates to a ceramic tile detects technical field, especially relates to a pottery brick size detection device.

Background

Based on GB/T3810.2-2016, ceramic tile test method part 2: the inspection of size and surface quality requires corresponding detection of the size (including length, right angle, edge straightness, edge curvature, warp degree and center curvature) of the ceramic tile, and currently, aiming at the inspection requirement in GB/T3810.2-2016, six dial indicators (respectively corresponding to the length, the right angle, the edge straightness, the edge curvature, the warp degree and the center curvature) are generally adopted to carry out manual reading detection, so that the operation is complex and the detection efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model provides a pottery brick size detection device aims at solving present complex operation when the size to pottery brick, the lower problem of detection efficiency.

In order to solve the above problems, the utility model adopts the technical scheme that a ceramic tile size detection device is provided, include:

the fixed bracket is used for fixedly supporting a sample to be tested along the horizontal direction;

a first movable support provided with a first photoelectric sensor and moving when the first movable support moves

When the first movable support rotates the first photoelectric sensor to a second preset position, the first photoelectric sensor is adjacent to one corner of the sample to be tested and measures the distance from the adjacent edge of the sample to be tested along the horizontal direction;

the second movable support is provided with a second photoelectric sensor, when the second movable support moves the second photoelectric sensor to a third preset position, the second photoelectric sensor measures the distance from the center of the adjacent edge of the sample to be measured along the horizontal direction, and when the second movable support moves the second photoelectric sensor to a fourth preset position, the second photoelectric sensor measures the distance from the center of the edge of the sample to be measured along the vertical direction; and

and the third movable support is provided with a third photoelectric sensor, when the third movable support moves to a fifth preset position from the third photoelectric sensor, the third photoelectric sensor measures the distance from the adjacent corner of the sample to be measured along the vertical direction, and when the third movable support moves to a sixth preset position from the third photoelectric sensor, the third photoelectric sensor measures the distance from the geometric center of the sample to be measured along the vertical direction.

In one embodiment, when the first movable support rotates the first photosensor to the second preset position, the distance between the first photosensor and the corner adjacent to the sample to be measured is 5mm along the extending direction of the first photosensor adjacent to the adjacent edge of the sample to be measured.

In one embodiment, the first movable support comprises a first fixing part, a first rotating shaft and a first cantilever, the first rotating shaft is rotatably connected to the first fixing part along the self axial direction, one end of the first cantilever is fixed on the first rotating shaft, the other end of the first cantilever is fixedly provided with a first photoelectric sensor, when the first rotating shaft rotates and drives the first photoelectric sensor to be located at a first preset position through the first cantilever, the first photoelectric sensor is spaced relative to an adjacent edge of the sample to be tested along the horizontal direction, and when the first rotating shaft rotates and drives the first photoelectric sensor to be located at a second preset position through the first cantilever, the first photoelectric sensor is adjacent to a corner of the sample to be tested and spaced relative to an adjacent edge of the sample to be tested along the horizontal direction;

the second movable support comprises a second fixing part, a second rotating shaft and a second cantilever, the second rotating shaft is rotatably connected to the second fixing part along the axial direction of the second rotating shaft, one end of the second cantilever is fixed on the second rotating shaft, the other end of the second cantilever is fixedly provided with a second photoelectric sensor, when the second rotating shaft rotates and drives the second photoelectric sensor to be located at a third preset position through the second cantilever, the second photoelectric sensor is opposite to the center of an adjacent edge of the sample to be detected at intervals along the horizontal direction, and when the second rotating shaft rotates and drives the second photoelectric sensor to be located at a fourth preset position through the second cantilever, the second photoelectric sensor is opposite to the center of the adjacent edge of the sample to be detected at intervals along the vertical direction;

the third movable support comprises a third fixing portion, a third rotating shaft and a third cantilever, the third rotating shaft is connected to the third fixing portion in a rotating mode along the axial direction of the third rotating shaft, one end of the third cantilever is fixed to the third rotating shaft, a third photoelectric sensor is fixedly arranged at the other end of the third cantilever, the third rotating shaft rotates and drives the third photoelectric sensor to be located at a fifth preset position through the third cantilever, the third photoelectric sensor is located at an adjacent corner of the sample to be detected at intervals along the vertical direction, the third rotating shaft rotates and drives the third photoelectric sensor to be located at a sixth preset position through the third cantilever, and the third photoelectric sensor is located at the geometric center of the sample to be detected at intervals along the vertical direction.

In one embodiment, the third suspension arm includes a third fixed arm and a third movable arm movably connected to the third fixed arm along the extending direction of the third fixed arm.

In one embodiment, the ceramic tile dimension detecting device further comprises a turntable, wherein the turntable is used for horizontally rotating the sample to be detected around the geometric center of the sample to be detected.

In one embodiment, the turntable includes a fourth fixing portion, a lifting rod movably connected to the fourth fixing portion along a vertical direction, and a turntable disposed at an end of the lifting rod away from the fourth fixing portion.

In one embodiment, the fixing bracket comprises a support for horizontally supporting the sample to be measured, and a limiting piece abutting against the edge of the sample to be measured along the horizontal direction.

The beneficial effects of the utility model reside in that: first photoelectric sensor, second photoelectric sensor and third photoelectric sensor set up respectively on first movable support, second movable support and third movable support, will await measuring sample level place back on the fixed bolster, when corresponding movable support will correspond photoelectric sensor and move to predetermineeing the position, photoelectric sensor can automatic reading and obtain the result to simplify operation process, improve detection efficiency.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic top view of a ceramic tile dimension detecting apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a position relationship between a fixed support and a turntable and a sample to be tested in the ceramic tile dimension detection apparatus shown in FIG. 1;

FIG. 3 is a schematic view of another position relationship between the fixing bracket and the turntable and the sample to be tested in the ceramic tile dimension detecting apparatus shown in FIG. 1;

fig. 4 is a schematic top view of a structural diagram of a positional relationship between a first photoelectric sensor and a sample to be tested when the first photoelectric sensor is located at a first preset position in the ceramic tile size detection apparatus shown in fig. 1;

fig. 5 is a schematic top view of the position relationship between the first photoelectric sensor and the sample to be tested when the first photoelectric sensor is at the second preset position in the ceramic tile size detection apparatus shown in fig. 1;

FIG. 6 is a left side view structural diagram of a positional relationship between a second photoelectric sensor and a sample to be tested when the second photoelectric sensor is located at a third preset position in the ceramic tile size detection apparatus shown in FIG. 1;

fig. 7 is a left side view structural schematic diagram of a positional relationship between a second photoelectric sensor and a sample to be detected when the second photoelectric sensor in the ceramic tile size detection apparatus shown in fig. 1 is at a fourth preset position;

fig. 8 is a schematic top view of the structure of the ceramic tile size detecting apparatus shown in fig. 1 when the third photoelectric sensor is at a fifth preset position;

fig. 9 is a schematic top view of the ceramic tile size detecting apparatus shown in fig. 1, wherein the third photoelectric sensor is located at a sixth preset position relative to the sample to be detected.

In the figure: 10. a sample to be tested; 100. fixing a bracket; 110. a support; 120. a limiting member; 200. a first movable support; 201. a first photosensor; 210. a first fixed part; 220. a first rotating shaft; 230. a first cantilever; 300. a second movable support; 301. a second photosensor; 310. a second fixed part; 320. a second rotating shaft; 330. a second cantilever; 400. a third movable support; 401. a third photosensor; 410. a third fixed part; 420. a third rotating shaft; 430. a third cantilever; 431. a third fixed arm; 432. a third movable arm; 500. a turntable; 510. a fourth fixing part; 520. a lifting rod; 530. a turntable.

Detailed Description

In the following description, for purposes of explanation and not limitation, specific details are set forth, such as particular system structures, techniques, etc. in order to provide a thorough understanding of the embodiments of the invention. However, it will be apparent to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known systems, devices, circuits, and methods are omitted so as not to obscure the description of the present invention with unnecessary detail.

It will be appreciated by those skilled in the art that the terms "left", "right", "upper" and "lower" in the foregoing description are relative terms and are not intended to limit the invention. It is also to be understood that the terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in the specification and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

To make the objects, features and advantages of the present invention more obvious and understandable, the embodiments of the present invention are clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, other ways of implementing the invention may be devised different from those described herein, and it will be apparent to those skilled in the art that the invention can be practiced without departing from the spirit and scope of the invention.

Referring to fig. 1, an embodiment of the present invention provides a ceramic tile dimension detecting device, for performing dimension detection on a sample 10 to be tested of a ceramic tile based on inspection requirements in GB/T3810.2-2016, wherein the ceramic tile dimension detecting device includes a fixing bracket 100, a first movable bracket 200, a second movable bracket 300, and a third movable bracket 400, wherein the fixing bracket 100 is configured to support and fix the sample 10 to be tested in a horizontal direction, and the first movable bracket 200, the second movable bracket 300, and the third movable bracket 400 are respectively provided with a first photoelectric sensor 201, a second photoelectric sensor 301, and a third photoelectric sensor 401 in a one-to-one correspondence manner, so that the length, the right angle, the edge straightness, the edge curvature, the warp curvature, and the center curvature of the sample 10 to be tested are measured by moving the first photoelectric sensor 201, the second photoelectric sensor 301, and the third photoelectric sensor 401 to corresponding positions, respectively.

Specifically, referring to fig. 4, when the first movable support 200 moves the first photoelectric sensor 201 to the first preset position, the first photoelectric sensor 201 may measure a distance from an adjacent edge of the sample 10 to be measured along the horizontal direction, so as to calculate a length of the sample 10 to be measured; referring to fig. 5, when the first movable support 200 moves the first photoelectric sensor 201 to the second preset position, the first photoelectric sensor 201 may be adjacent to a corner of the sample 10 to be measured and measure a distance from an adjacent edge of the sample 10 to be measured along the horizontal direction, so as to calculate a right angle of the sample 10 to be measured; referring to fig. 6, when the second movable bracket 300 moves the second photoelectric sensor 301 to the third preset position, the second photoelectric sensor 301 may measure the distance from the center of the adjacent edge of the sample 10 to be measured along the horizontal direction, so as to calculate the edge straightness of the sample 10 to be measured; referring to fig. 7, when the second movable support 300 moves the second photoelectric sensor 301 to the fourth preset position, the second photoelectric sensor 301 may measure the distance from the center of the adjacent edge of the sample 10 to be measured along the vertical direction, so as to calculate the edge curvature of the sample 10 to be measured; referring to fig. 8, when the third movable bracket 400 moves the third photosensor 401 to a fifth preset position, the third photosensor 401 may measure a distance from an adjacent corner of the sample to be measured 10 along the vertical direction, so as to calculate a warping degree of the sample to be measured 10; referring to fig. 9, when the third movable support 400 moves the third photoelectric sensor 401 to a sixth preset position, the third photoelectric sensor 401 may measure a distance from a geometric center of the sample 10 to be measured along a vertical direction, and further, the distance is used to calculate a center curvature of the sample 10 to be measured.

The ceramic tile size detection device has the advantages that the first movable support 200, the second movable support 300 and the third movable support 400 are respectively matched with the first photoelectric sensor 201, the second photoelectric sensor 301 and the third photoelectric sensor 401, so that automatic measurement of six data by the three sensors is realized, on one hand, the measurement error caused by manual reading of a dial indicator in the prior art is reduced, on the other hand, the manual operation steps in the detection process are also simplified, and the detection efficiency is effectively improved.

Further, referring to fig. 1 and fig. 2, in the present embodiment, the fixing bracket 100 includes a support 110 and a limiting member 120, wherein the support 110 is used for horizontally supporting the sample 10 to be tested, and the limiting member 120 abuts against an edge of the sample 10 to be tested along a horizontal direction, so as to place the sample 10 to be tested at a position required to be tested by the support 110. It can be understood that the support 110 and the limiting member 120 both avoid the movement tracks of the first movable bracket 200, the second movable bracket 300 and the third movable bracket 400.

Further, referring to fig. 4 and 5, in the present embodiment, the first movable bracket 200 includes a first fixing portion 210, a first rotating shaft 220 and a first cantilever 230, wherein the first rotating shaft 220 is rotatably connected to the first fixing portion 210 along an axial direction thereof, one end of the first cantilever 230 is fixed to the first rotating shaft 220, and the other end is fixedly provided with a first photoelectric sensor 201, when the first rotating shaft 220 rotates and the first photoelectric sensor 201 is driven by the first cantilever 230 to be located at a first preset position, the first photoelectric sensor 201 is spaced from an adjacent edge of the sample 10 to be tested along a horizontal direction, and when the first rotating shaft 220 rotates and the first photoelectric sensor 201 is driven by the first cantilever 230 to be located at a second preset position, the first photoelectric sensor 201 is adjacent to a corner of the sample 10 to be tested and is spaced from another adjacent edge of the sample 10 to be tested along the horizontal direction.

It should be noted that, in this embodiment, an adjacent edge corresponding to when the first photosensor 201 is located at the first preset position and an adjacent edge corresponding to when the first photosensor 201 is located at the second preset position are two different edges directly connected to the sample 10 to be measured, in some other embodiments, an adjacent edge corresponding to when the first photosensor 201 is located at the first preset position and an adjacent edge corresponding to when the first photosensor 201 is located at the second preset position may be the same edge of the sample 10 to be measured, or two different edges of the sample 10 to be measured in other position relationships.

Specifically, in the present embodiment, the extending direction of the first rotating shaft 220 is parallel to the horizontal plane, and when the first photoelectric sensor 201 is located at the first preset position, the first cantilever 230 is parallel to the corresponding adjacent edge of the sample 10 to be measured, and when the first photoelectric sensor 201 is located at the second preset position, the first cantilever 230 is parallel to the corresponding adjacent edge of the sample 10 to be measured.

Specifically, in this embodiment, when the first photosensor 201 is located at the second preset position, along the extending direction of the adjacent edge of the first photosensor 201 adjacent to the sample 10 to be detected, the distance from the first photosensor 201 to the adjacent corner of the sample 10 to be detected is 5mm, so as to meet the requirement of the detection position in GB/T3810.2-2016 on the right angle detection of the sample 10 to be detected.

Further, referring to fig. 6 and 7, in the present embodiment, the second movable bracket 300 includes a second fixed portion 310, a second rotating shaft 320 and a second cantilever 330, wherein the second rotating shaft 320 is rotatably connected to the second fixed portion 310 along an axial direction thereof, one end of the second cantilever 330 is fixed to the second rotating shaft 320, and the other end of the second cantilever 330 is fixedly provided with the second photoelectric sensor 301, when the second rotating shaft 320 rotates and the second photoelectric sensor 301 is driven to be located at a third preset position by the second cantilever 330, the second photoelectric sensor 301 is spaced from a center of an adjacent edge of the sample 10 to be measured along a horizontal direction, and when the second rotating shaft 320 rotates and the second photoelectric sensor 301 is driven to be located at a fourth preset position by the second cantilever 330, the second photoelectric sensor 301 is spaced from a center of an adjacent edge of the sample 10 to be measured along a vertical direction.

It should be noted that, in this embodiment, an adjacent edge corresponding to the second photosensor 301 located at the third preset position and an adjacent edge corresponding to the second photosensor 301 located at the fourth preset position are the same edge of the sample 10 to be measured, in other embodiments, an adjacent edge corresponding to the second photosensor 301 located at the third preset position and an adjacent edge corresponding to the second photosensor 301 located at the fourth preset position may also be different edges of the sample 10 to be measured.

Specifically, in this embodiment, the second rotating shaft 320 is disposed obliquely to the horizontal plane, and when the second photoelectric sensor 301 is located at the third predetermined position, the second cantilever 330 is vertically disposed and perpendicular to the corresponding adjacent edge of the sample 10 to be tested, and when the second photoelectric sensor 301 is located at the fourth predetermined position, the second cantilever 330 is horizontally disposed and perpendicular to the corresponding adjacent edge of the sample 10 to be tested.

Further, referring to fig. 8 and 9, in the present embodiment, the third movable bracket 400 includes a third fixing portion 410, a third rotating shaft 420 and a third cantilever 430, the third rotating shaft 420 is rotatably connected to the third fixing portion 410 along its axial direction, one end of the third cantilever 430 is fixed to the third rotating shaft 420, and the other end is fixedly provided with a third photosensor 401, when the third rotating shaft 420 rotates and the third photosensor 401 is driven by the third cantilever 430 to be located at a fifth preset position, the third photosensor 401 is vertically spaced from an adjacent corner of the sample to be measured 10, and when the third rotating shaft 420 rotates and the third photosensor 401 is driven by the third cantilever 430 to be located at a sixth preset position, the third photosensor 401 is vertically spaced from a geometric center of the sample to be measured 10.

Specifically, in the present embodiment, the third rotating shaft 420 is disposed parallel to the horizontal plane, and when the third photoelectric sensor 401 is located at the fifth preset position or at the sixth preset position, the third cantilever 430 is parallel to the horizontal plane.

It should be noted that, in this embodiment, after the sample 10 is placed on the support 110, the third photoelectric sensor 401, the third fixing portion 410, the third rotating shaft 420 and the third cantilever 430 are all located below the sample 10, so that the third photoelectric sensor 401 performs distance detection on the corresponding position of the sample 10 from bottom to top, in other embodiments, after the sample 10 is placed on the support 110, the third photoelectric sensor 401 and the third cantilever 430 may also be located above the sample 10, so that the third photoelectric sensor 401 performs distance detection on the corresponding position of the sample 10 from top to bottom.

More specifically, in this embodiment, the third cantilever 430 includes a third fixed arm 431 and a third movable arm 432, and the third movable arm 432 is movably connected to the third fixed arm 431 along the extending direction of the third fixed arm 431, so as to flexibly adjust the length of the third cantilever 430, and further ensure that the third photoelectric sensor 401 can move to a corresponding position when detecting samples 10 to be detected with different sizes.

Further, in some other embodiments, the first suspension arm 230 includes a first fixed arm (not shown) and a first movable arm (not shown), the first movable arm is movably connected to the first fixed arm along the extending direction of the first fixed arm, the second suspension arm 330 includes a second fixed arm (not shown) and a second movable arm (not shown), the second movable arm is movably connected to the second fixed arm along the extending direction of the second fixed arm, so as to adjust the lengths of the first suspension arm 230 and the second suspension arm 330.

Further, referring to fig. 2 and fig. 3, in the present embodiment, the ceramic tile dimension detecting apparatus further includes a turntable 500, where the turntable 500 is configured to horizontally rotate the sample 10 to be detected around the geometric center of the sample 10 to be detected, so that when the first photoelectric sensor 201, the second photoelectric sensor 301, and the third photoelectric sensor 401 finish detecting the position of one edge or one corner of the sample 10 to be detected, the sample 10 to be detected is rotated, so that the first photoelectric sensor 201, the second photoelectric sensor 301, and the third photoelectric sensor 401 can finish detecting all positions of the sample 10 to be detected based on GB/T3810.2-2016 requirements for the sample 10 to be detected.

Specifically, in this embodiment, the turntable 500 includes a fourth fixing portion 510, a lifting rod 520 and a turntable 530, the lifting rod 520 is movably connected to the fourth fixing portion 510 along a vertical direction, and the turntable 530 is disposed at one end of the lifting rod 520 far away from the fourth fixing portion 510 and is opposite to the geometric center of the sample 10 to be tested at an interval, so that before the sample 10 to be tested is rotated, the turntable 530 is lifted by the lifting rod 520 to slightly lift the sample 10 to be tested, and then the turntable 530 rotates the sample 10 to be tested 90 ° around the geometric center of the sample 10 to be tested, and the lifting rod 520 descends to enable the sample 10 to be tested to return to the support 110 again, thereby avoiding interference between the sample 10 to be tested and the support 110 and the limiting member 120 during the rotation process.

The above-described embodiments only represent several embodiments of the present invention, and should not be interpreted as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several changes and modifications can be made, which are within the scope of the present invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. A ceramic tile size detection apparatus, comprising:

the fixed bracket is used for fixedly supporting a sample to be tested along the horizontal direction;

the first movable support is provided with a first photoelectric sensor, when the first movable support moves the first photoelectric sensor to a first preset position, the first photoelectric sensor measures the distance from the adjacent edge of the sample to be measured along the horizontal direction, and when the first movable support rotates the first photoelectric sensor to a second preset position, the first photoelectric sensor is adjacent to one corner of the sample to be measured and measures the distance from the adjacent edge of the sample to be measured along the horizontal direction;

the second movable support is provided with a second photoelectric sensor, when the second movable support moves the second photoelectric sensor to a third preset position, the second photoelectric sensor measures the distance from the center of the adjacent edge of the sample to be measured along the horizontal direction, and when the second movable support moves the second photoelectric sensor to a fourth preset position, the second photoelectric sensor measures the distance from the center of one edge of the sample to be measured along the vertical direction; and

the third movable support is provided with a third photoelectric sensor, works as the third movable support moves when third photoelectric sensor to the fifth preset position, third photoelectric sensor measures apart from along vertical direction the distance of the adjacent corner of the sample that awaits measuring works as the third movable support moves when third photoelectric sensor to the sixth preset position, third photoelectric sensor measures apart from along vertical direction the distance of the sample geometric centre that awaits measuring.

2. The ceramic tile dimension detecting apparatus of claim 1, wherein when the first movable support rotates the first photoelectric sensor to a second preset position, the first photoelectric sensor is located at a distance of 5mm from a corner adjacent to the sample to be detected along an extending direction of the first photoelectric sensor adjacent to an adjacent edge of the sample to be detected.

3. The ceramic tile dimension detecting apparatus according to claim 1, wherein the first movable support includes a first fixing portion, a first rotating shaft and a first cantilever, the first rotating shaft is rotatably connected to the first fixing portion along its axial direction, one end of the first cantilever is fixed to the first rotating shaft, the other end of the first cantilever is fixedly provided with the first photoelectric sensor, when the first rotating shaft rotates and drives the first photoelectric sensor to be located at a first preset position through the first cantilever, the first photoelectric sensor is spaced from an adjacent edge of the sample to be detected along the horizontal direction, when the first rotating shaft rotates and drives the first photoelectric sensor to be located at a second preset position through the first cantilever, the first photoelectric sensor is adjacent to a corner of the sample to be detected and is spaced from an adjacent edge of the sample to be detected along the horizontal direction;

the second movable support comprises a second fixing part, a second rotating shaft and a second cantilever, the second rotating shaft is rotatably connected to the second fixing part along the axial direction of the second rotating shaft, one end of the second cantilever is fixed on the second rotating shaft, the other end of the second cantilever is fixedly provided with the second photoelectric sensor, when the second rotating shaft rotates and drives the second photoelectric sensor to be located at a third preset position through the second cantilever, the second photoelectric sensor is spaced relative to the center of an adjacent edge of the sample to be detected along the horizontal direction, and when the second rotating shaft rotates and drives the second photoelectric sensor to be located at a fourth preset position through the second cantilever, the second photoelectric sensor is spaced relative to the center of an adjacent edge of the sample to be detected along the vertical direction;

the third movable support includes third fixed part, third pivot and third cantilever, the third pivot along self axial rotate connect in on the third fixed part, the one end of third cantilever is fixed in the third pivot, the other end is fixed to be set up the third photoelectric sensor, the third pivot is rotatory and pass through the third cantilever drives when the third photoelectric sensor is located the fifth preset position, the third photoelectric sensor is relative along vertical direction interval a sample adjacent corner awaits measuring, the third pivot is rotatory and pass through the third cantilever drives when the third photoelectric sensor is located the sixth preset position, the third photoelectric sensor is relative along vertical direction interval the geometric centre of sample awaits measuring.

4. The ceramic tile dimension detecting apparatus of claim 3, wherein the third cantilever comprises a third fixed arm and a third movable arm movably connected to the third fixed arm along the extending direction of the third fixed arm.

5. The ceramic tile dimension detecting apparatus as claimed in claim 1, further comprising a turntable for horizontally rotating the sample to be tested around the geometric center of the sample to be tested.

6. The ceramic tile dimension detecting apparatus as claimed in claim 5, wherein the turntable includes a fourth fixing portion, a lifting rod and a rotating disc, the lifting rod is movably connected to the fourth fixing portion along a vertical direction, and the rotating disc is disposed at an end of the lifting rod away from the fourth fixing portion.

7. The ceramic tile dimension detecting apparatus as claimed in claim 1, wherein the fixing bracket includes a support for horizontally supporting the sample to be tested, and a stopper abutting against an edge of the sample to be tested in a horizontal direction.

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