CN107655427A - A kind of ceramic tile flatness detecting device - Google Patents

Abstract

The invention relates to the technical field of ceramic production equipment, and discloses a tile flatness detection device, including a detection platform, a first longitudinal guide rail, a second longitudinal guide rail and a first transverse guide rail, one end of the first transverse guide rail is slidably connected to the A longitudinal guide rail, the other end of the first transverse guide rail is slidably connected to the second longitudinal guide rail; the tile flatness detection device also includes a detection assembly and a controller, the detection assembly is slidably connected to the first transverse guide rail, and detects The output of the assembly is electrically connected to the first input of the controller. The controller controls the first transverse guide rail to slide on the first longitudinal guide rail and the second longitudinal guide rail, so that the detection assembly slides between the first longitudinal guide rail and the second longitudinal guide rail, so that the detection assembly can automatically and fully detect the tiles The surface can effectively avoid the long detection time and high manpower consumption due to the manual inspection of the flatness of the sampling tiles, so as to improve the production efficiency of the tiles.

Description

A tile flatness detection device

technical field

The invention relates to the technical field of ceramic production equipment, in particular to a tile flatness detection device.

Background technique

Ceramic tile is a building material formed by grinding, mixing, pressing, glazing, sintering and other processes of refractory metal oxides and semi-metal oxides. It is usually inlaid on the surface of the building, which plays a decorative role while protecting the building. However, due to the processing technology, ceramic tiles usually have deformations such as bending, warping, and twisting during the sintering process, resulting in uneven surface of the tiles, which affects the quality of the tiles. Therefore, in order to ensure the quality of ceramic tiles, in the process of ceramic tile production, it is necessary to conduct random inspections on the flatness of ceramic tiles, so as to find unqualified products in time.

At present, the sampling inspection of the flatness of tiles generally adopts manual sampling and manual inspection. Due to the low degree of automation of tile inspection, the inspection time is long and the labor consumption is large, which makes the production efficiency of tiles low.

Contents of the invention

The purpose of the present invention is to provide a tile flatness detection device to solve the technical problems of long detection time and large manpower consumption due to the manual detection method for the sampling inspection of the existing tile flatness, so as to improve the production efficiency of tiles .

In order to solve the above-mentioned technical problems, the present invention provides a ceramic tile flatness detection device, including a detection platform and a first longitudinal guide rail, a second longitudinal guide rail and a first transverse guide rail arranged on the detection platform, the first longitudinal guide rail Set opposite to the second longitudinal guide rail, one end of the first transverse guide rail is slidably connected to the first longitudinal guide rail, and the other end of the first transverse guide rail is slidably connected to the second longitudinal guide rail superior;

The tile flatness detection device also includes a detection component and a controller, the detection component is slidably connected to the first transverse guide rail, and the output end of the detection component is connected to the first input end of the controller electrical connection.

As a preferred solution, the controller is further configured to: control the detection component to slide along the four sides and diagonals of the square tile.

As a preferred solution, the detection assembly includes a first slider and a sensor connected to the first slider, and the detection assembly is slidably connected to the first transverse guide rail through the first slider; The output end of the sensor is electrically connected with the output end of the detection component.

As a preferred solution, one end of the first slider is provided with a first flange extending downward, and the sensor is connected to the first flange.

As a preferred solution, the sensor is a laser displacement sensor.

As a preferred solution, the detection platform is provided with a first motor, the output shaft of the first motor is connected to one end of the first transverse guide rail, and the input end of the first motor is connected to the first end of the controller. The control terminal is electrically connected.

As a preferred solution, the tile flatness detection device further includes a second slider and a third slider, one end of the first transverse guide rail is slidably connected to the first longitudinal guide rail through the second slider , the other end of the first transverse guide rail is slidably connected to the second longitudinal guide rail through the third slider.

As a preferred solution, the detection platform is also provided with a second motor, the output shaft of the second motor is respectively connected to one end of the first longitudinal guide rail and one end of the second longitudinal guide rail, and the second motor The input terminal is electrically connected to the second control terminal of the controller.

As a preferred solution, a connecting rod is provided on the second motor, one end of the connecting rod is connected to the output shaft of the second motor, and is connected to one end of the first longitudinal guide rail, and the other end of the connecting rod One end is connected to one end of the second longitudinal guide rail.

As a preferred solution, the tile flatness detection device is also provided with a plurality of positioning pieces for positioning around the tiles, and a plurality of positioning pieces are arranged between the first longitudinal guide rail and the second longitudinal guide rail .

The invention provides a ceramic tile flatness detection device, which includes a detection platform and a first longitudinal guide rail, a second longitudinal guide rail and a first transverse guide rail arranged on the detection platform, the first longitudinal guide rail is opposite to the second longitudinal guide rail, and the first One end of the transverse guide rail is slidably connected to the first longitudinal guide rail, and the other end of the first transverse guide rail is slidably connected to the second longitudinal guide rail; the ceramic tile flatness detection device also includes a detection component and a controller, and the detection component is slidably It is connected to the first transverse guide rail, and the output end of the detection component is electrically connected to the first input end of the controller. The controller controls the detection assembly to slide on the first transverse guide rail, and at the same time controls the first transverse guide rail to slide on the first longitudinal guide rail and the second longitudinal guide rail, so that the detection assembly can slide between the first longitudinal guide rail and the second longitudinal guide rail Sliding, so that the detection component can automatically and fully detect the surface of the tiles, so as to improve the automation of tile detection, thereby effectively avoiding the long detection time and manpower consumption caused by manual detection of the flatness of the tiles, so as to improve the tiles. Productivity.

Description of drawings

Fig. 1 is a schematic structural view of a tile flatness detection device in an embodiment of the present invention;

Fig. 2 is a schematic diagram of the detection track of the detection component in the embodiment of the present invention.

Among them, 1. Detection platform; 11. Adjusting base; 12. Pulley; 2. First longitudinal guide rail; 21. Second slider; 3. Second longitudinal guide rail; 31. Third slider; 4. First transverse guide rail ;5, detection component; 51, the first slider; 511, the first flanging; 52, the sensor; 6, the first motor; 7, the second motor; 71, the connecting rod; 8, the positioning piece; 9, square tile ;91, upper edge; 92, lower edge; 93, left edge; 94, right edge.

Detailed ways

The specific implementation manners of the present invention will be further described in detail below in conjunction with the accompanying drawings and embodiments. The following examples are used to illustrate the present invention, but are not intended to limit the scope of the present invention.

In the description of the present invention, the descriptions of directions such as up, down, left, right, front and back are all limited to FIG. The description of will also change according to the change of the placement method, and the present invention will not repeat them here.

As shown in Fig. 1, a kind of ceramic tile flatness detection device of the preferred embodiment of the present invention comprises a detection platform 1 and a first longitudinal guide rail 2, a second longitudinal guide rail 3 and a first transverse guide rail arranged on the detection platform 1 4. The first longitudinal guide rail 2 is opposite to the second longitudinal guide rail 3, one end of the first transverse guide rail 4 is slidably connected to the first longitudinal guide rail 2, and the first transverse guide rail 4 The other end is slidably connected to the second longitudinal guide rail 3;

The tile flatness detection device also includes a detection component 5 and a controller, the detection component 5 is slidably connected to the first transverse guide rail 4, and the output end of the detection component 5 is connected to the controller The first input end is electrically connected.

In the embodiment of the present invention, the controller controls the detection assembly 5 to slide on the first transverse guide rail 4, and at the same time controls the first transverse guide rail 4 to slide on the first longitudinal guide rail 2 and the second longitudinal guide rail 3, so that the detection assembly 5 It can slide between the first longitudinal guide rail 2 and the second longitudinal guide rail 3, so that the detection assembly 5 can automatically and fully detect the surface of the tiles, so as to improve the automation of tile detection, thereby effectively avoiding the manual detection of tiles. The flatness results in long detection time and high manpower consumption, so as to improve the production efficiency of ceramic tiles.

As shown in Figure 2, in order to ensure that the detection assembly 5 can fully detect the surface of the tiles to ensure the detection accuracy of the tile flatness detection device, the controller in this embodiment is also used to: control the detection The assembly 5 slides along the four sides and the diagonals of the square tile 9 . The controller controls the detection assembly 5 to slide along the four sides and diagonals of the square ceramic tile 9 to ensure that the sensor 52 can fully scan the surface of the tile, thereby ensuring that the detection assembly 5 can fully The surface of the ceramic tile is detected, thereby ensuring the detection accuracy of the tile flatness detection device.

Specifically, the controller controls the detection component 5 to slide along the upper edge 91 of the square tile 9 from the detection starting point, and then slides along the right edge 94 of the square tile 9; then, the detection component 5 slides along the The diagonal line connecting the upper edge 91 and the right edge 94 of the square tile 9 slides, and then slides along the left edge 93 of the square tile 9; 92 and the diagonal line connecting the right edge 94 slide, then slide along the lower edge 92 of the square tile 9; finally, the detection assembly 5 returns to the detection starting point.

As shown in Figure 2, the detection assembly 5 slides along the four sides and diagonal lines of the square tile 9, specifically: the detection track of the detection assembly 5 starts from a, and the detection assembly 5 moves from a to b slides, and then slides from b to c to detect the upper edge 91 of the square tile 9; then, the detection component 5 transitions from c to d, and then slides from d to e to detect the upper edge 91 of the square tile 9. Right edge 94; Then, the detection assembly 5 transitions from e to f, and then slides from f to g, so as to detect the diagonal line connecting the upper edge 91 and the right edge 94 of the square tile 9; then, the The detection component 5 transitions from g to h, and then slides from h to i to detect the left edge 93 of the square tile 9; then, the detection component 5 transitions from i to j, and then slides from j to k to detect The diagonal line connecting the lower edge 92 and the right edge 94 of the square tile 9; then, the detection assembly 5 slides from k to l, and then slides from l to m to detect the lower edge of the square tile 9 92; Finally, the detection component 5 slides from m to a, and the detection component 5 returns to the detection starting point a.

As shown in Figure 1, in order to facilitate the detection assembly 5 to be slidably connected to the first transverse guide rail 4, the detection assembly 5 in this embodiment includes a first slider 51 and a The sensor 52 on the block 51, the detection assembly 5 is slidably connected to the first transverse guide rail 4 through the first slider 51; the output end of the sensor 52 is connected to the output end of the detection assembly 5 electrical connection. By setting the first slider 51 , the detection assembly 5 is facilitated to slide on the first transverse guide rail 4 . In addition, by electrically connecting the output end of the sensor 52 to the output end of the detection assembly 5, so that the output end of the sensor 52 is electrically connected to the input end of the controller, thereby realizing the connection between the sensor 52 and the input end of the controller. Information transmission before the controller; the sensor 52 detects the surface of the tile according to the preset detection track, and feeds back the information of the detected tile surface to the controller, and the controller sends the sensor 52 After the detected information is compared with the tile standard information, the result of tile flatness is obtained.

In the embodiment of the present invention, in order to facilitate the connection of the sensor 52 to the first slider 51, one end of the first slider 51 in this embodiment is provided with a first flange 511 extending downward, so The sensor 52 is connected to the first flange 511 . By setting the first flange 511 on the first slider 51 and connecting the sensor 52 to the first flange 511, it is convenient for the sensor 52 to be connected to the first slider. 52, thereby facilitating said sensor 52 to detect the surface of the tile.

In the embodiment of the present invention, the sensor 52 can be set according to actual usage conditions, as long as the sensor 52 can detect the flatness of the surface of the tile. In order to simplify the design and structure and reduce the cost, the sensor 52 in this embodiment is a laser displacement sensor.

As shown in Figure 1, in order to improve the degree of automation of the tile flatness detection device, the detection platform 1 in this embodiment is provided with a first motor 6, and the output shaft of the first motor 6 is connected to the first One end of the transverse guide rail 4 is connected, and the input end of the first motor 6 is electrically connected with the first control end of the controller. By connecting the output shaft of the first motor 6 to the first transverse guide rail 4, and electrically connecting the output terminal of the first motor 6 to the first control terminal of the controller, the control is realized The controller controls the detection assembly 5 to slide on the first transverse guide rail 4, so that the detection assembly 5 can slide on the first transverse guide rail 4 according to the preset detection track, thereby improving the ceramic tile. The degree of automation of the flatness detection device.

As shown in Figure 1, in order to facilitate the sliding of the first transverse guide rail 4 on the first longitudinal guide rail 2 and the second longitudinal guide rail 3, the tile flatness detection device in this embodiment also includes a second slide block 21 and a third slider 31, one end of the first transverse guide rail 4 is slidably connected to the first longitudinal guide rail 2 through the second slider 21, and the other end of the first transverse guide rail 4 The third sliding block 31 is slidably connected to the second longitudinal guide rail 3 . By setting the second slider 21 and the third slider 31 respectively, so that one end of the first transverse guide rail 4 can slide on the first longitudinal guide rail 2 through the second slider 21, And the other end of the first transverse guide rail 4 can slide on the second longitudinal guide rail 3 through the third slide block 31, so that the first transverse guide rail 4 can be moved between the first longitudinal guide rail 2 and the first longitudinal guide rail 3 Sliding on the second longitudinal rail 3.

In the embodiment of the present invention, in order to further improve the degree of automation of the tile flatness detection device, the detection platform 1 in this embodiment is also provided with a second motor 7, and the output shaft of the second motor 7 is connected to the One end of the first longitudinal guide rail 2 is connected to one end of the second longitudinal guide rail 3, and the input end of the second motor 7 is electrically connected to the second control end of the controller. By connecting the output shaft of the second motor 7 with the first longitudinal guide rail 2 and the second longitudinal guide rail 3 respectively, and connecting the output end of the second motor 7 with the second control of the controller Terminals are electrically connected to realize that the controller controls the first transverse guide rail 4 to slide on the first longitudinal guide rail 2 and the second longitudinal guide rail 3, so that all the parts connected to the first transverse guide rail 4 The detection assembly 5 can slide between the first longitudinal guide rail 2 and the second longitudinal guide rail 3, so that the detection assembly 5 can move between the first longitudinal guide rail 2 and the second longitudinal guide rail 3 according to a preset detection track. Sliding between the second longitudinal guide rails 3, to further improve the degree of automation of the ceramic tile flatness detection device.

In the embodiment of the present invention, in order to facilitate the connection between the output shaft of the second motor 7 and the first longitudinal guide rail 2 and the second longitudinal guide rail 3, the second motor 7 in this embodiment is provided with a connection Rod 71, one end of the connecting rod 71 is connected to the output shaft of the second motor 7, and is connected to one end of the first longitudinal guide rail 2, and the other end of the connecting rod 71 is connected to the second longitudinal guide rail 3 is connected at one end. By connecting the connecting rod 71 with the output shaft of the second motor 7, the first longitudinal guide rail 2 and the second longitudinal guide rail 3, the output shaft of the second motor 7 can pass through the The connecting rods 71 are respectively connected with the first longitudinal guide rail 2 and the second longitudinal guide rail 3, so as to facilitate the connection between the output shaft of the second motor 7 and the first longitudinal guide rail 2 and the second longitudinal guide rail 3 connect.

As shown in Figure 1, in order to position the tiles to ensure that the detection assembly 5 can fully detect the surface of the tiles, the tile flatness detection device in this embodiment is also provided with a plurality of positioning holes around the tiles. A positioning piece 8 , and a plurality of positioning pieces 8 are arranged between the first longitudinal guide rail 2 and the second longitudinal guide rail 3 . By setting the positioning member 8 between the first longitudinal guide rail 2 and the second longitudinal guide rail 3, the tiles can be positioned so as to ensure that the tiles can be positioned on the within the detection range of the detection component 5, thereby ensuring that the detection component 5 can fully detect the surface of the ceramic tile.

In the embodiment of the present invention, the shape of the positioning member 8 can be set according to actual usage conditions, as long as the positioning member 8 can position the tiles. In order to simplify the design and structure and reduce the cost, the shape of the positioning member 8 in this embodiment is L-shaped.

In the embodiment of the present invention, the number of the positioning pieces 8 can also be set according to the actual usage, as long as the positioning pieces 8 can position the tiles. In order to further simplify the design and structure and reduce the cost, there are two positioning members 8 in this embodiment.

In the embodiment of the present invention, in order to ensure that the positioning member 8 can play a good positioning effect on the tiles, when the shape of the positioning member 8 is L-shaped, two positioning members 8 are symmetrically arranged on the second Between a longitudinal guide rail 2 and the second longitudinal guide rail 3 , the shape of the forward projection of the two positioning members 8 on the detection platform 1 matches the cross-sectional shape of the square tile 9 .

In the embodiment of the present invention, in order to improve the convenience of the tile flatness detection device, the bottom of the detection platform 1 in this embodiment is provided with a plurality of adjustment bases 11, and the plurality of adjustment bases 11 are evenly distributed in the circumferential direction. The bottom of the detection platform 1, one end of the adjustment base 11 is connected to the bottom of the detection platform 1, and the other end of the adjustment base 11 is against the ground; the bottom of the detection platform 1 is also provided with a plurality of The pulleys 12, a plurality of the pulleys 12 are arranged symmetrically on the bottom of the detection platform 1, and the pulleys 12 are slidably connected to the bottom of the detection platform 1 through a fixing piece. By setting the adjustment base 11 at the bottom of the detection platform 1 to adjust the height of the detection platform 1, it is convenient to use the tile flatness detection device to detect the flatness of the tiles, thereby improving the flatness of the tiles The convenience of the detection device. In addition, by setting the pulley 12 at the bottom of the detection platform 1, it is convenient to move the tile flatness detection device, thereby further improving the convenience of the tile flatness detection device

The invention provides a tile flatness detection device, comprising a detection platform 1 and a first longitudinal guide rail 2, a second longitudinal guide rail 3 and a first transverse guide rail 4 arranged on the detection platform 1, the first longitudinal guide rail 2 and the second longitudinal guide rail The guide rails 3 are arranged oppositely, one end of the first transverse guide rail 4 is slidably connected to the first longitudinal guide rail 2, and the other end of the first transverse guide rail 4 is slidably connected to the second longitudinal guide rail 3; the tile flatness detection device also includes The detection component 5 and the controller, the detection component 5 is slidably connected to the first transverse guide rail 4, and the output terminal of the detection component 5 is electrically connected with the first input terminal of the controller. The controller controls the detection assembly 5 to slide on the first transverse guide rail 4, and simultaneously controls the first transverse guide rail 4 to slide on the first longitudinal guide rail 2 and the second longitudinal guide rail 3, so that the detection assembly 5 can slide on the first longitudinal guide rail 2 Slide between the second longitudinal guide rail 3, so that the detection assembly 5 can automatically and fully detect the surface of the tiles, so as to improve the automation of tile detection, thereby effectively avoiding the detection time caused by manual detection of the flatness of tiles Long and labor-intensive, in order to improve the production efficiency of ceramic tiles.

The above is only a preferred embodiment of the present invention, it should be pointed out that for those of ordinary skill in the art, without departing from the technical principle of the present invention, some improvements and replacements can also be made, these improvements and replacements It should also be regarded as the protection scope of the present invention.

Claims (10)

1. a kind of ceramic tile flatness detecting device, it is characterised in that including detection platform and in the detection platform First longitudinal direction guide rail, second longitudinal direction guide rail and first cross slide way, the first longitudinal direction guide rail and the second longitudinal direction guide rail phase To setting, one end of the first cross slide way is slidably attached at the first longitudinal direction guide rail, the first cross slide way The other end be slidably attached on the second longitudinal direction guide rail；

The ceramic tile flatness detecting device also includes detection components and controller, and the detection components are slidably attached at institute State in first cross slide way, and the output end of the detection components electrically connects with the first input end of the controller.

2. ceramic tile flatness detecting device as claimed in claim 1, it is characterised in that the controller is additionally operable to：Control institute Detection components are stated along four sides of square tile and diagonal slide.

3. ceramic tile flatness detecting device as claimed in claim 1, it is characterised in that the detection components include the first sliding block And the sensor on first sliding block is connected to, the detection components are slidably attached at institute by first sliding block State in first cross slide way；The output end of the sensor electrically connects with the output end of the detection components.

4. ceramic tile flatness detecting device as claimed in claim 3, it is characterised in that one end of first sliding block be provided with to First flange of lower extension, the sensor are connected on first flange.

5. ceramic tile flatness detecting device as claimed in claim 3, it is characterised in that the sensor senses for laser displacement Device.

6. the ceramic tile flatness detecting device as described in claim any one of 1-5, it is characterised in that in the detection platform Provided with the first motor, the output shaft of first motor is connected with one end of the first cross slide way, first motor Input electrically connects with the first control terminal of the controller.

7. the ceramic tile flatness detecting device as described in claim any one of 1-5, it is characterised in that the ceramic tile flatness Detection means also includes the second sliding block and the 3rd sliding block, one end of the first cross slide way by second sliding block slidably Ground is connected on the first longitudinal direction guide rail, and the other end of the first cross slide way is slideably connected by the 3rd sliding block It is connected on the second longitudinal direction guide rail.

8. ceramic tile flatness detecting device as claimed in claim 7, it is characterised in that be additionally provided with second in the detection platform Motor, the output shaft of second motor respectively with one end of the first longitudinal direction guide rail and one end of the second longitudinal direction guide rail Connection, the input of second motor electrically connect with the second control terminal of the controller.

9. ceramic tile flatness detecting device as claimed in claim 8, it is characterised in that second motor is provided with connection Bar, one end of the connecting rod and the output axis connection of second motor, and be connected with one end of the first longitudinal direction guide rail, The other end of the connecting rod is connected with one end of the second longitudinal direction guide rail.

10. the ceramic tile flatness detecting device as described in claim any one of 1-5, it is characterised in that the ceramic tile flatness Multiple keepers for being used to position ceramic tile surrounding are additionally provided with detection means, and multiple keepers are located at the first longitudinal direction Between guide rail and the second longitudinal direction guide rail.