CN115783712A

CN115783712A - Ceramic tile steering device

Info

Publication number: CN115783712A
Application number: CN202310036139.0A
Authority: CN
Inventors: 罗浩乐
Original assignee: Foshan Xinhua Ceramics Co ltd
Current assignee: Foshan Xinhua Ceramics Co ltd
Priority date: 2023-01-10
Filing date: 2023-01-10
Publication date: 2023-03-14

Abstract

The invention relates to the field of ceramic tile processing, and discloses a ceramic tile steering device, which comprises: a frame; the first conveying mechanism comprises a first servo motor and a first conveying belt, the first servo motor is arranged on the rack and is in driving connection with the first conveying belt, and the top surface of the first conveying belt is a first conveying surface; the second conveying mechanism comprises a second servo motor and a second conveying belt, the second servo motor is arranged on the rack and is in driving connection with the second conveying belt, the first conveying belt and the second conveying belt are arranged in parallel at intervals, the top surface of the second conveying belt is a second conveying surface, and the first conveying surface and the second conveying surface are coplanar; and the servo control assembly enables the first conveying belt and the second conveying belt to operate at different linear speeds. This ceramic tile turns to device realizes that the ceramic tile turns to when advancing, and transfer efficiency is high, and structural arrangement is simple.

Description

Ceramic tile steering device

Technical Field

The invention relates to the field of ceramic tile processing, in particular to a ceramic tile steering device.

Background

The production line of ceramic tiles involves the transfer and turning of the tiles. When changing from wide to narrow or vice versa, the conventional solution is to design the gripping or lifting platform to move the tiles off the moving conveyor line and then to turn. However, the steering mode needs additional related mechanisms such as lifting rotation or clamping rotation, and the like, and has complex structure and high cost. In addition, the tile is usually in a state of stopping advancing when the tile is turned, so that the tile conveying efficiency is reduced.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art.

The invention provides a tile turning device, comprising:

a frame;

the first conveying mechanism comprises a first servo motor and a first conveying belt, the first servo motor is arranged on the rack and is in driving connection with the first conveying belt, and the top surface of the first conveying belt is a first conveying surface;

the second conveying mechanism comprises a second servo motor and a second conveying belt, the second servo motor is arranged on the rack and is in driving connection with the second conveying belt, the first conveying belt and the second conveying belt are arranged in parallel at intervals, the top surface of the second conveying belt is a second conveying surface, and the first conveying surface and the second conveying surface are coplanar;

the servo control assembly comprises a control panel, the control panel is in signal connection with the first servo motor and the second servo motor, and the control panel controls the first servo motor and the second servo motor to enable the first conveying belt and the second conveying belt to run at different linear speeds.

The invention has the beneficial effects that: this ceramic tile turns to device has disposed parallel first conveyer belt and second conveyer belt, and first conveyer belt and second conveyer belt support and transfer the ceramic tile in both sides respectively, and the servo control subassembly drives first conveyer belt and second conveyer belt and moves with different speed, and the ceramic tile takes place to turn to promptly when the difference appears in the both sides advancing speed of ceramic tile to this realizes that the ceramic tile turns to when advancing, and transfer efficiency is high, and the structural arrangement is simple.

As a sub-solution to the above technical solution, the tile turning device further comprises a distance adjusting mechanism, and the distance adjusting mechanism is used for adjusting the distance between the first conveying belt and the second conveying belt.

Some sub-schemes as above-mentioned technical scheme, the roll adjustment mechanism includes roll adjustment slide bar, first slide, second slide, first lead screw, first servo motor with first conveyer belt all is established on the first slide, second servo motor with the second conveyer belt all is established on the second slide, first slide with the second slide is all followed the roll adjustment slide bar slides, first lead screw rotationally erects in the frame, nevertheless the mounted position of first lead screw remains unchanged, first slide with be equipped with first screw and second screw on the second slide respectively, first screw with the direction of rotation of second screw is opposite, first lead screw simultaneously with first screw and second screw threaded connection.

As a sub-scheme of the above technical scheme, the distance adjusting mechanism further comprises a distance adjusting servo motor, the distance adjusting servo motor is arranged on the rack, the distance adjusting servo motor is in driving connection with the first lead screw, and the control panel is further in signal connection with the distance adjusting servo motor.

As a sub-scheme of the above technical scheme, the rack is further provided with a first arch structure and a second arch structure, the first arch structure and the second arch structure are both arch bridge-shaped and are protruded upwards, and the upper sides of the first conveying belt and the second conveying belt are respectively lapped on the first arch structure and the second arch structure.

As a sub-scheme of the foregoing technical solution, the control board makes the first conveyor belt run in a first period through the first servo motor, the first period includes a first uniform velocity section and a first speed change section, the control board makes the second conveyor belt run in a second period through controlling the second servo motor, the second period includes a second uniform velocity section, the first conveyor belt runs at the same speed as the second uniform velocity section in the first uniform velocity section, and the first conveyor belt in the first speed change section first decelerates to turn tiles and then accelerates to reach the speed of the first uniform velocity section.

As a sub-scheme of the above technical solution, a position sensor is arranged between the first conveying belt and the second conveying belt, the position sensor is fixed on the frame, the position sensor is in signal connection with the control board, and the position sensor is used for identifying whether the tile reaches the arching position and partially leaves the first conveying belt and the second conveying belt.

As some sub-schemes of the technical scheme, the rack is further provided with a limiting component, and the limiting component is used for limiting the first conveying belt and the second conveying belt which fall off when the ceramic tiles turn.

As a sub-scheme of the above technical scheme, the limiting assembly includes a plurality of limiting wheels, all of the limiting wheels are disposed at the downstream of the first conveying belt and the second conveying belt, and the limiting wheels are linearly arranged.

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 schematic view of the tile turning apparatus;

FIG. 2 is a schematic structural diagram of a first conveying mechanism;

FIG. 3 is a schematic diagram of a first cycle and a second cycle;

fig. 4 is a schematic view showing the conveyance of a tile having a large length-width ratio.

In the drawings: t1-first period; t11-a first constant speed section; t12-first transmission stage; t2-second period; s-path difference; d-the pitch value;

11-a first conveyor belt; 12-a first servo motor; 13-a first dome;

21-a second conveyor belt;

31-a distance-adjusting slide bar; 32-a first slide; 33-a first screw rod;

41-a limiting wheel; 42-position sensor.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention and are not to be construed as limiting the present invention.

In the description of the present invention, it should be understood that the orientation or positional relationship referred to in the description of the orientation, such as upper, lower, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings only for the convenience of description of the present invention and simplification of the description, and does 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.

In the description of the present invention, a plurality of the terms are not limited to a certain number, and a plurality of the terms are two or more, and the terms larger, smaller, larger, and the like are understood to include the number of the terms, and the terms larger, smaller, and the like are understood to include the number of the terms. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated. Appearing throughout and/or representing three side-by-side scenarios, e.g., A and/or B represents a scenario satisfied by A, a scenario satisfied by B, or a scenario satisfied by both A and B.

In the description of the invention, there are phrases containing a plurality of juxtaposed features, where a phrase is defined to be the closest feature, such as: b and C arranged on A, and E connected with D, wherein B is arranged on A, and E is connected with D, and C is not limited; however, terms indicating relationships between features such as "spaced apart", "arranged in a ring", etc. do not fall within this category. If the phrase is preceded by the word "mean", it means that all the features in the phrase are limited, and if B, C and D are all arranged on A, it means that B, C and D are all arranged on A. The statement with the subject omitted is the subject of the previous statement, namely, the statement A is provided with B and includes C, which means that the statement A is provided with B and includes C.

In the description of the present invention, unless otherwise explicitly limited, terms such as arrangement, installation, connection and the like should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above terms in the present invention in combination with the specific contents of the technical solutions.

An embodiment of the present invention will be described below with reference to fig. 1 to 4.

This embodiment relates to a tile turns to device, includes:

a frame (not shown);

the first conveying mechanism comprises a first servo motor 12 and a first conveying belt 11, the first servo motor 12 is arranged on the rack, the first servo motor 12 is in driving connection with the first conveying belt 11, and the top surface of the first conveying belt 11 is a first conveying surface;

the second conveying mechanism comprises a second servo motor and a second conveying belt 21, the second servo motor is arranged on the rack and is in driving connection with the second conveying belt 21, the first conveying belt 11 and the second conveying belt 21 are arranged in parallel at intervals, the top surface of the second conveying belt 21 is a second conveying surface, and the first conveying surface and the second conveying surface are coplanar;

the servo control assembly comprises a control panel, the control panel is in signal connection with the first servo motor 12 and the second servo motor, and the control panel controls the first servo motor 12 and the second servo motor to enable the first conveying belt 11 and the second conveying belt 21 to run at different linear speeds.

This ceramic tile turns to device has configured parallel first conveyer belt 11 and second conveyer belt 21, and first conveyer belt 11 and second conveyer belt 21 support and transfer the ceramic tile in both sides respectively, and the servo control subassembly drives first conveyer belt 11 and second conveyer belt 21 and moves with different speed, and the ceramic tile takes place to turn to promptly when the difference appears in the both sides advancing speed of ceramic tile to this realizes that the ceramic tile turns to when advancing, and the transfer efficiency is high, and the structural arrangement is simple.

The ceramic tile in this embodiment turns to the device, mainly used realizes turning to 90 degrees of ceramic tile. For example, after the surface of the tile is treated for appearance, the direction of the tile needs to be adjusted before entering the polishing station to ensure that the polished grinding traces correspond to the pattern, such as the wood grain pattern.

In the tile turning device of the present embodiment, when the distance between the first conveyor belt 11 and the second conveyor belt 21 is small compared to the size of the tile, for example, the distance between the first conveyor belt 11 and the second conveyor belt 21 is less than 0.1 times the smaller value of the width or the length of the tile, the tile may fall off the first conveyor belt 11 and the second conveyor belt 21 when turning the tile, and for this reason, the tile turning device further includes a distance adjustment mechanism for adjusting the distance between the first conveyor belt 11 and the second conveyor belt 21. The distance between the first conveying belt 11 and the second conveying belt 21 is adjusted by the distance adjusting mechanism, so that the tile steering device can adapt to tiles with different sizes and properly increase the distance between the first conveying belt 11 and the second conveying belt 21, and the tiles are stably supported.

Further, the roll adjustment mechanism includes roll adjustment slide bar 31, first slide 32, second slide, first lead screw 33, first servo motor 12 with first conveyer belt 11 all establishes on first slide 32, second servo motor with second conveyer belt 21 all establishes on the second slide, first slide 32 with the second slide is all followed roll adjustment slide bar 31 slides, first lead screw 33 is rotationally erect in the frame, nevertheless the mounted position of first lead screw 33 keeps unchangeable, first slide 32 with be equipped with first screw and second screw on the second slide respectively, first screw with the direction of turning of second screw is opposite, first lead screw 33 simultaneously with first screw and second screw threaded connection. When the distance between the first conveyor belt 11 and the second conveyor belt 21 is adjusted by using the distance adjusting mechanism, the first screw rod 33 is firstly rotated, the first screw rod 33 drives the first slide seat 32 and the second slide seat to slide, and because the screwing directions of the first screw hole and the second screw hole which are in threaded connection with the first screw rod 33 are opposite, the first slide seat 32 and the second slide seat simultaneously slide along the distance adjusting slide rod 31 in opposite directions, at the moment, the distance between the first conveyor belt 11 and the second conveyor belt 21 is changed, and the adjustment of the distance between the first conveyor belt 11 and the second conveyor belt 21 is completed. In addition, because the first slide 32 and the second slide move in opposite directions simultaneously when the first screw 33 rotates, the central position between the first slide 32 and the second slide remains unchanged before and after adjustment, the butt joint position of an external conveying belt and the tile steering device can remain unchanged, and the tile steering device is convenient to load into a production line.

The distance adjusting mechanism further comprises a distance adjusting servo motor, the distance adjusting servo motor is arranged on the rack, the distance adjusting servo motor is in driving connection with the first lead screw 33, and the control panel is further in signal connection with the distance adjusting servo motor. The roll adjustment mechanism is equipped with roll adjustment servo motor and controls first lead screw 33, and roll adjustment servo motor and control panel signal connection, control panel overall control roll adjustment servo motor, first servo motor 12 and second servo motor, after roll adjustment servo motor has changed the distance between first conveyer belt 11 and the second conveyer belt 21, the speed difference between control panel accessible signal adjustment first servo motor 12 and the second servo motor and guarantee that turning to of ceramic tile is abundant.

Still be equipped with first domes 13 and second domes in the frame, first domes 13, second domes all are the arch bridge form and upwards protruding, first conveyer belt 11 with the upside of second conveyer belt 21 is taken around respectively on first domes 13 and the second domes. The upper end of first conveyer belt 11 is taken on the first domes 13 of upwards arching, the upper end of second conveyer belt 21 is taken on the second domes of upwards arching, when the ceramic tile is carried by first conveyer belt 11 and second conveyer belt 21, because the ceramic tile is the rigidity object, when the ceramic tile is ascending to the upper end of arching position, an end perk of ceramic tile, can reduce the area of contact of ceramic tile and first conveyer belt 11 and second conveyer belt 21 like this, reduce the frictional resistance between ceramic tile and first conveyer belt 11 and the second conveyer belt 21, thereby drive the ceramic tile through the speed difference of first conveyer belt 11 and second conveyer belt 21 and turn to. Similarly, when the tile is lowered from the upper end of the arched position, the tilting of the tail of the tile can also reduce the contact area between the tile and the first and

second conveyor belts

11 and 21, thereby reducing the frictional resistance generated when the tile is turned. Furthermore, it is more important that when some tiles with large length-width ratio are turned, for example, wood-like tiles with length-width ratio larger than 5, the distance between the first conveyor belt 11 and the second conveyor belt 21 can be adjusted simultaneously during the turning process, so as to ensure that the first conveyor belt 11 and the second conveyor belt 21 can support the tiles more stably during the whole turning process. For example, as shown in fig. 4, when the narrow direction of the tiles is the spacing direction between the first conveyor belt 11 and the second conveyor belt 21, the distance between the first conveyor belt 11 and the second conveyor belt 21 is small, and when the first conveyor belt 11 and the second conveyor belt 21 drive the tiles to turn in a differential manner, if the distance between the first conveyor belt 11 and the second conveyor belt 21 is kept unchanged, the tiles are partially contacted with the first conveyor belt 11 and the second conveyor belt 21 at the arched position and partially in the tilted state, and the tiles are easily dropped due to vibration when the first conveyor belt 11 and the second conveyor belt 21 drive the tiles to turn. For this reason, be equipped with the interval between the first conveyer belt 11 of roll adjustment servo motor instant adjustment and the second conveyer belt 21, the distance between the first conveyer belt 11 of roll adjustment servo motor action change and the second conveyer belt 21 when first conveyer belt 11 and second conveyer belt 21 turn to the ceramic tile to realize turning to the stability of the ceramic tile of length and width ratio greatly. In this embodiment, the first arch 13 is a support bar with an arc-shaped protrusion. The first arch structure has the advantages of simplicity and reliability by adopting the supporting strip.

In this embodiment, the first and

second arches

13 and 13 have the same structure, the first and second conveyors have the same structure, and the first and second conveyors have the difference only in the operating speeds of the first and second conveyors.

Further, the control board makes the first conveyor belt 11 run in a first period T1 through the first servo motor 12, the first period T1 includes a first uniform velocity section T11 and a first speed change section T12, the control board makes the second conveyor belt 21 run in a second period T2 by controlling the second servo motor, the second period T2 includes a second uniform velocity section, the first conveyor belt 11 runs at the same speed as the second uniform velocity section in the first uniform velocity section T11, the first conveyor belt 11 first decelerates in the first speed change section T12 to turn the tiles, and then accelerates to reach the speed of the first uniform velocity section T11. By setting the operation cycles of the first servo motor 12 and the second servo motor in this manner, the control logic of the first conveyor belt 11 and the second conveyor belt 21 can be simplified, and the turning of the tiles can be simply realized by the speed difference between the first conveyor belt 11 and the second conveyor belt 21. In the present embodiment, the first shift stage T12 can be determined by a test method. The test process is to predetermine the distance between the first conveyor belt 11 and the second conveyor belt 21 and the tiles to be steered, and then continuously adjust the acceleration time of the first speed change section T12, the speed difference between the accelerated tiles and the second constant speed section, and the deceleration time until the tiles can be steered by the first speed change section without exceeding too much. In this embodiment, the tiles are turned 90 degrees.

In addition, the determination of the first speed change section T12 may also be implemented by a calculation manner, referring to fig. 3, speed curves of the first period T1 and the second period T2 are shown in the figure, the first period T1 includes a first uniform speed section T11 and a first speed change section T12, the speed of the first uniform speed section T11 is consistent with the speed of the second uniform speed section, and the running speeds of the first conveying belt 11 and the second conveying belt 21 are consistent in the speed interval, at this time, the first conveying belt 11 and the second conveying belt 21 may be in three states, that is, firstly, the tiles are driven to ascend to the upper end of the arching position, secondly, the tiles are driven to leave from the upper end of the arching position after the turning is completed, and thirdly, the tiles are waited to enter the first conveying belt 11 and the second conveying belt 21. After passing through the first constant speed section T11, the first conveying belt 11 is first decelerated in the first speed change section T12 to generate a speed difference between the first conveying belt 11 and the second conveying belt 21 to drive the tiles to turn, and then accelerated to return the speeds of the first conveying belt 11 and the second conveying belt 21 to the same value, so as to output the tiles without generating a turning force to the tiles. Taking the road distance difference S generated by the first speed change section T12 and the second constant speed section, the distance value D between the first conveyor belt 11 and the second conveyor belt 21, and the angle value of tile turning as a, when S = a/2 x D, the tile turns through an angle a in the first speed change section T12. With this, S should be equal to 45xD when it is necessary to turn the tile 90 degrees. Therefore, when the first speed change stage T12 is set, the path difference S between the first speed change stage T12 and the second constant speed stage may be set to 45xD. The tile diverting arrangement in this embodiment is in use, the entire course of the first cycle T1 is typically completed in 5 to 15 seconds. Referring to fig. 3, a constant speed stage is further configured in the first speed changing section T12, when the tile passes through the top of the arching position, the contact area between the tile and the first conveying belt 11 and the second conveying belt 21 is the smallest, at this time, the tile is in the constant speed stage, so that the change of the acting force of the first conveying belt and the second conveying belt on the tile can be reduced, and the tile turning direction is more stable.

Further, a position sensor is arranged between the first conveying belt 11 and the second conveying belt 21, the position sensor is fixed on the rack, the position sensor is in signal connection with the control board, and the position sensor is used for identifying whether tiles reach the arching position and partially leave the first conveying belt 11 and the second conveying belt 21. The exact position of the tile in the arched position can be obtained by arranging a position sensor to achieve more stable turning of the tile. In this embodiment, the position sensor is located at the downstream of the top end of the arching position and is disposed upward, and taking the first conveyor belt 11 and the second conveyor belt 21 in this embodiment as an example of conveying from left to right, the position sensor is disposed at the right of the top end of the arching position. Further, after the position sensor acquires a signal that the tile reaches the arch position, the control board switches the first conveyor belt 11 to the first speed changing section T12 through the first servo motor 12, thereby further improving the stability of the operation.

Further, still be equipped with spacing subassembly in the frame, spacing subassembly is used for the restriction ceramic tile to turn to the time first conveyer belt 11 and the second conveyer belt 21 that drop. Under the ideal condition, can confirm the angle that turns to of ceramic tile through the path difference S of setting for first variable speed section T12 and the second section of uniform velocity, but under actual operating conditions, because vibration and first conveyer belt 11 that each servo motor during operation produced, factor such as can appear skidding between second conveyer belt 21 and the ceramic tile, the actual angle that turns to of ceramic tile may be less than the calculated value, therefore, when this ceramic tile of in-service use turns to the device, generally set for the difference S of actual path about 1.1 times of the path difference calculated value S, and dispose spacing subassembly restriction and drop in order to guarantee that the ceramic tile can turn to the target in place, the impact force of ceramic tile and spacing subassembly contact is less simultaneously, the ceramic tile is also less with the stroke that skids of first conveyer belt 11 and second conveyer belt 21.

The limiting assembly comprises a plurality of limiting wheels 41, the limiting wheels 41 are arranged at the downstream of the first conveying belt 11 and the downstream of the second conveying belt 21, and the limiting wheels 41 are arranged in a linear mode. The spacing assembly is configured in the form of a spacing wheel 41 with a low resistance to the subsequent transport of the tiles.

While the preferred embodiments of the present invention have been described in detail, the present invention is not limited to the embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are intended to be included within the scope of the present invention as defined in the appended claims.

Claims

1. Ceramic tile turns to device, its characterized in that: the method comprises the following steps:

a frame;

the conveying mechanism comprises a first servo motor (12) and a first conveying belt (11), the first servo motor (12) is arranged on the rack, the first servo motor (12) is in driving connection with the first conveying belt (11), and the top surface of the first conveying belt (11) is a first conveying surface;

the second conveying mechanism comprises a second servo motor and a second conveying belt (21), the second servo motor is arranged on the rack and is in driving connection with the second conveying belt (21), the first conveying belt (11) and the second conveying belt (21) are arranged in parallel at intervals, the top surface of the second conveying belt (21) is a second conveying surface, and the first conveying surface and the second conveying surface are coplanar;

the servo control assembly comprises a control board, the control board is in signal connection with the first servo motor (12) and the second servo motor, and the control board controls the first servo motor (12) and the second servo motor to enable the first conveying belt (11) and the second conveying belt (21) to run at different linear speeds.

2. The tile turning apparatus according to claim 1, wherein: the tile steering device further comprises a distance adjusting mechanism, and the distance adjusting mechanism is used for adjusting the distance between the first conveying belt (11) and the second conveying belt (21).

3. The tile turning apparatus according to claim 2, wherein: the roll adjustment mechanism includes roll adjustment slide bar (31), first slide (32), second slide, first lead screw (33), first servo motor (12) with first conveyer belt (11) all are established on first slide (32), second servo motor with second conveyer belt (21) all are established on the second slide, first slide (32) with the second slide is all followed roll adjustment slide bar (31) slide, establish first lead screw (33) rotatable in the frame, but the mounted position of first lead screw (33) remains unchanged, first slide (32) with be equipped with first screw and second screw on the second slide respectively, first screw with the turning to opposite direction of second screw, first lead screw (33) simultaneously with first screw and second screw threaded connection.

4. The tile turning apparatus according to claim 3, wherein: the distance adjusting mechanism further comprises a distance adjusting servo motor, the distance adjusting servo motor is arranged on the rack, the distance adjusting servo motor is in driving connection with the first screw rod (33), and the control panel is further in signal connection with the distance adjusting servo motor.

5. The tile turning device according to claim 4, wherein: still be equipped with first domes (13) and second domes in the frame, first domes (13), second domes all are the arch bridge form and upwards arch, first conveyer belt (11) with the upside of second conveyer belt (21) is taken respectively and is wound on first domes (13) and second domes.

6. The tile turning device according to claim 5, wherein: the control panel enables the first conveying belt (11) to run in a first period (T1) through the first servo motor (12), the first period (T1) comprises a first uniform speed section (T11) and a first speed change section (T12), the control panel enables the second conveying belt (21) to run in a second period (T2) through controlling the second servo motor, the second period (T2) comprises a second uniform speed section, the first conveying belt (11) in the first uniform speed section (T11) is identical to the second uniform speed section in running speed, the first conveying belt (11) in the first speed change section (T12) firstly decelerates to enable tiles to turn, and then accelerates to reach the speed of the first uniform speed section (T11).

7. The tile turning device according to claim 6, wherein: first conveyer belt (11) with be equipped with position sensor between second conveyer belt (21), position sensor fixes in the frame, position sensor with control panel signal connection, position sensor is used for discerning whether the ceramic tile reaches the hunch-up position and partly leaves first conveyer belt (11) and second conveyer belt (21).

8. The tile turning apparatus according to claim 1, wherein: the ceramic tile turning machine is characterized in that a limiting assembly is further arranged on the rack and used for limiting a first conveying belt (11) and a second conveying belt (21) which fall off when a ceramic tile turns.

9. The tile turning device according to claim 8, wherein: the limiting assembly comprises a plurality of limiting wheels (41), the limiting wheels (41) are arranged in a plurality of numbers, all the limiting wheels (41) are arranged at the downstream of the first conveying belt (11) and the downstream of the second conveying belt (21), and the limiting wheels (41) are linearly arranged.