CN221214765U - Ceramic large plate brick discharging machine with centering function - Google Patents

Abstract

The utility model discloses a ceramic large plate brick laying machine with a centering function, which also comprises a centering module and a jacking module; the centering module comprises a mounting frame, a sliding cylinder, a pushing wheel and at least two fixing rods; the two fixing rods are arranged below the conveying line at intervals front and back, and the left and right ends of the fixing rods are exposed out of the left and right sides of the conveying line; the left end and the right end of the fixed rod are respectively provided with a sliding cylinder, the output end of the sliding cylinder extends outwards, and the mounting frame is arranged at the output end of the sliding cylinder; the pushing wheel is arranged at the top of the mounting frame, is positioned above the conveying line and faces to the brick discharging mechanism positioned in the middle of the conveying line; the side surface of the pushing wheel is used for propping against the side surface of the ceramic large plate to be packaged. The ceramic large plate to be packaged is pushed to move left and right through the cooperation of the four sliding cylinders and the corresponding pushing wheels, and the center point of the ceramic large plate to be packaged is aligned upwards to the center point of the brick feeding mechanism, so that the ceramic large plate to be packaged and the packing box can be prevented from being misplaced.

Description

Ceramic large plate brick discharging machine with centering function

Technical Field

The utility model relates to the technical field of ceramic tile production equipment, in particular to a ceramic large plate tile discharging machine with a centering function.

Background

After polishing and grading, the ceramic large plates are required to be placed into a wooden packing box for packing.

Because the ceramic large plate is large in size and weight, the ceramic large plate supported by the jacking module is required to be sucked through an electric vacuum chuck in the brick discharging machine, then the brick discharging machine horizontally translates the sucked ceramic large plate to the upper part of the packing box, and then the ceramic large plate is lowered and put into the packing box.

The ceramic large plate is conveyed through the conveying line, the ceramic large plate is stopped above the jacking module through the brick blocking module, if the position of the ceramic large plate when being placed on the conveying line is offset, or the ceramic large plate is offset in the process of conveying to the upper part of the jacking module, the ceramic large plate can be caused to be misplaced due to the offset when being translated to the upper part of the packing box, the edge of the misplaced ceramic large plate collides with the side edge of the packing box, and the brick discharging mechanism suspending the electric vacuum chuck collides with the side edge of the packing box, so that the ceramic large plate, the packing box and/or the brick discharging mechanism are damaged.

Disclosure of utility model

Aiming at the defects, the utility model aims to provide a ceramic large plate brick laying machine with a centering function, which pushes a ceramic large plate to be boxed to move left and right by the cooperation of a sliding cylinder and a pushing wheel so as to correct the deviation of the ceramic large plate to be boxed.

To achieve the purpose, the utility model adopts the following technical scheme:

The ceramic large plate brick discharging machine with the centering function comprises a conveying line, a brick discharging mechanism, a centering module and a jacking module;

The jacking module is used for upwards supporting the ceramic large plate to be boxed;

the centering module comprises a mounting frame, a sliding cylinder, a pushing wheel and at least two fixing rods;

The two fixing rods are arranged below the conveying line at intervals in the front-back direction, and the left end and the right end of each fixing rod are exposed out of the left side and the right side of the conveying line;

The left end and the right end of the fixed rod are respectively provided with the sliding cylinder, the output end of the sliding cylinder extends outwards, and the mounting frame is arranged at the output end of the sliding cylinder; the pushing wheel is arranged at the top of the mounting frame, is positioned above the conveying line and faces to the brick discharging mechanism positioned in the middle of the conveying line; the side surface of the pushing wheel is used for propping against the side surface of the ceramic large plate to be boxed.

Further, the device also comprises a height sensor and a PLC controller;

The conveying line comprises a plurality of conveying belts extending along the front-back direction; the conveying belt is used for supporting and conveying the large ceramic plates to be boxed;

The height sensor is arranged right below the brick-discharging mechanism and is positioned between two adjacent conveying belts;

The jacking module, the sliding cylinder and the height sensor are respectively connected with the PLC controller through signals.

Further, the mounting frame is provided with a supporting plate;

the upright support plate is arranged at the bottom of the mounting frame, and the output end of the sliding cylinder is fixed on the plate surface of the support plate, which corresponds to the direction of the support plate, of the fixing rod.

Preferably, the four mounting frames are symmetrically distributed with the center point of the brick-discharging mechanism as a center, and the pushing wheels of the four mounting frames face to four corners of the brick-discharging mechanism respectively.

Further, the mounting frame is provided with two pushing wheels;

The axial lines of the four driving wheels of the two mounting frames which are adjacent in front and back are positioned on the same vertical plane;

and the center points of all the pushing wheels are positioned on the same horizontal plane.

Further, the centering module further comprises a guide rod, a sliding cylinder fixing plate and a guide sleeve;

The left end and the right end of the fixed rod are respectively provided with the sliding cylinder fixed plate, and the sliding cylinder is arranged on the plate surface of the sliding cylinder fixed plate facing the middle part of the corresponding fixed rod;

One ends of the two guide sleeves are respectively close to the front edge and the rear edge of the sliding cylinder fixing plate, the other ends of the two guide sleeves extend towards the middle part of the corresponding fixing rod, and the two guide sleeves are respectively positioned in front of or behind the sliding cylinder; one end of the guide rod extending along the left-right direction is exposed out of the other end of the guide sleeve, and the other end of the guide rod penetrates through the guide sleeve and the sliding cylinder fixing plate and is connected with the corresponding plate surface of the support plate.

Specifically, the jacking module comprises a plurality of bases, a plurality of top wheels, a plurality of lifting frames and a plurality of lifting motors;

The bases extending in the left-right direction are arranged below the conveying line at intervals in the front-back direction; the two lifting motors are arranged on the top surface of the base at left and right intervals, and the output ends of the lifting motors extend upwards; the lifting frames extending along the left-right direction are arranged on the top surfaces of the output ends of the two lifting motors at left-right intervals; the top wheel frames are arranged on the top surface of the lifting frame at intervals left and right, and the top wheel is positioned between two left and right adjacent conveying belts.

Preferably, the top wheel is rotatable along a central axis extending in the front-rear direction.

Further, the brick blocking device also comprises a brick blocking module;

the brick blocking module is positioned in front of the brick discharging mechanism;

a first sensor, a second sensor and a third sensor which are sequentially arranged from back to front are also arranged between the two left and right adjacent conveying belts;

The first sensor is close to the rear input end of the conveying line, the second sensor is close to the middle of the brick discharging mechanism, and the third sensor is close to the brick blocking module;

The first inductor, the second inductor, the third inductor and the brick blocking module are respectively connected with the PLC controller through signals.

Preferably, the top wheel and the pushing wheel are made of wear-resistant elastic materials.

The technical scheme of the utility model has the beneficial effects that: the ceramic large plate brick discharging machine with the centering function pushes the ceramic large plate to be packaged to move left and right through the cooperation of the four sliding cylinders and the corresponding pushing wheels, so that the center point of the ceramic large plate to be packaged is upwards aligned with the center point of the brick discharging mechanism, the deviation of the ceramic large plate to be packaged is corrected, the dislocation of the ceramic large plate to be packaged and a packaging box can be avoided, and the ceramic large plate to be packaged, the packaging box and/or the brick discharging mechanism to be packaged are prevented from being damaged.

Drawings

FIG. 1 is a schematic structural view of the ceramic large plate brick machine with centering function of the utility model;

FIG. 2 is an enlarged partial view of portion A of FIG. 1;

FIG. 3 is an enlarged partial view of portion B of FIG. 1;

Wherein: a conveying line 1; a centering module 2; a jacking module 3; a first inductor 4; a height sensor 5; a brick discharging mechanism 6; a second inductor 7; a third inductor 8; a conveyor belt 11; a mounting frame 21, a sliding cylinder 22 and a pushing wheel 23; a fixing rod 24; a support plate 25; a guide bar 26; a slide cylinder fixing plate 27; a guide sleeve 28; a base 30; a top wheel 31; a lifting frame 32, a lifting motor 33; a vacuum chuck 61.

Detailed Description

The technical scheme of the utility model is further described below by means of specific embodiments in combination with the accompanying drawings 1-3.

The drawings are for illustrative purposes only and are not to be construed as limiting the present patent; for the purpose of better illustrating the embodiments, certain elements of the drawings may be omitted, enlarged or reduced and do not represent the actual product dimensions; it will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted", "connected" and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected or integrally connected; can be mechanically or electrically connected; the two elements may be directly connected or indirectly connected through an intermediate medium, so to speak, the two elements are communicated internally. It will be understood by those of ordinary skill in the art that the terms described above are in the specific sense of the present utility model.

The ceramic large plate brick discharging machine with the centering function comprises a conveying line 1, a brick discharging mechanism 6, a centering module 2 and a jacking module 3;

The jacking module 3 is used for upwards supporting the ceramic large plate to be boxed;

the centering module 2 comprises a mounting frame 21, a sliding cylinder 22, a pushing wheel 23 and at least two fixing rods 24;

the two fixing rods 24 are arranged below the conveying line 1 at intervals in the front-back direction, and the left and right ends of the fixing rods 24 are exposed to the left and right sides of the conveying line 1;

The sliding cylinder 22 is mounted at the left end and the right end of the fixed rod 24, the output end of the sliding cylinder 22 extends outwards, and the mounting frame 21 is mounted at the output end of the sliding cylinder 22; the pushing wheel 23 is arranged at the top of the mounting frame 21, and the pushing wheel 23 is positioned above the conveying line 1 and faces to the brick-discharging mechanism 6 positioned in the middle of the conveying line 1; the side surface of the pushing wheel 23 is used for propping against the side surface of the ceramic large plate to be boxed.

Fig. 1-2 are schematic structural views of the ceramic large plate brick machine with centering function.

The ceramic large plate brick laying machine with the centering function comprises a brick blocking module, a jacking module 3 and a PLC controller, wherein a conveying line 1 comprises a plurality of conveying belts 11 extending along the front-rear direction; a first sensor 4, a second sensor 7 and a third sensor 8 are sequentially arranged between two adjacent conveyor belts 11 from back to front; the output end of the sliding cylinder 22 in the unactuated state is in the extended state.

The ceramic large plate brick feeding machine with centering function of the utility model is characterized in that when the ceramic large plate brick feeding machine runs, the front end of the ceramic large plate to be boxed enters the rear input end of the conveying line 1, the first sensor 4 is triggered, the motors for driving the conveying belts 11 are started, the conveying belts 11 convey the ceramic large plate to be boxed forwards, when the front end of the ceramic large plate to be boxed passes through the center point of the brick feeding mechanism 6, the second sensor 7 is triggered, the brick blocking cylinder in the brick blocking module behind the brick feeding mechanism 6 is started, the baffle plate in the brick blocking module is pushed by the brick blocking cylinder to be lifted upwards, the baffle plate is exposed out of the top surface of the conveying line 1, when the front end of the ceramic large plate to be boxed which is going forward is close to the baffle plate, the third sensor 8 is triggered, the motors for driving the conveying belts 11 are stopped, then the front end of the ceramic large plate to be boxed is driven by the inertia of the conveying line 11 to move forwards, the baffle is touched to stop, then the jacking module 3 upwards supports the ceramic large plate to be boxed, the bottom surface of the lifted ceramic large plate to be boxed is separated from the top surface of the conveying line 11, at the moment, four sliding cylinders 22 are synchronously started and enable corresponding output ends to retract, the four mounting frames 21 on the left side and the right side are driven to be close to the ceramic large plate to be boxed, the side surfaces of the pushing wheels 23 are abutted against the left side surface or the right side surface of the ceramic large plate to be boxed, the ceramic large plate to be boxed is pushed to move left and right through the cooperation of the four sliding cylinders 22 and the corresponding pushing wheels 23, the center point of the ceramic large plate to be boxed is upwards aligned with the center point of the brick-descending mechanism 6, so that the deviation of the ceramic large plate to be boxed is corrected, finally the sucker motor of the brick-descending mechanism 6 is started, and the electric vacuum sucker 61 is pushed to downwards suck the top surface of the ceramic large plate to be boxed, the ceramic large plate to be packaged is accurately moved to the upper side of the packaging box, so that dislocation of the ceramic large plate to be packaged and the packaging box is avoided, and damage to the ceramic large plate to be packaged, the packaging box and/or the brick discharging mechanism 6 is avoided.

Further, the device also comprises a height sensor 5 and a PLC controller;

The conveyor line 1 includes a plurality of conveyor belts 11 extending in the front-rear direction; the conveying belt 11 is used for supporting and conveying the ceramic large plates to be boxed;

The height sensor 5 is arranged right below the brick-laying mechanism 6, and the height sensor 5 is positioned between two adjacent conveying belts 11;

The jacking module 3, the sliding cylinder 22 and the height sensor 5 are respectively connected with the PLC in a signal mode.

As shown in fig. 1-2, the lifting module 3 lifts up the ceramic large plate to be packaged, so that the ceramic large plate to be packaged leaves the top surface of the conveying line 11, when the plate surface of the ceramic large plate to be packaged reaches a set height, namely, the plate surface of the ceramic large plate to be packaged and the plurality of pushing wheels 23 are positioned on the same horizontal plane, the height sensor 5 is triggered, the height sensor 5 sends a signal to the PLC controller, the PLC controller sends a lifting stopping signal to the lifting module 3 and simultaneously sends a starting signal to the sliding cylinder 22 after receiving the signal, thereby avoiding the occurrence of the phenomenon that the side surface of the pushing wheel 23 is misplaced with the side surface of the ceramic large plate to be packaged, further ensuring the position accuracy of the ceramic large plate to be packaged by the movement of the sliding cylinder 22 and the pushing wheel 23, and ensuring the operation effectiveness of the centering function of the ceramic large plate brick machine with the centering function.

Further, the mounting frame 21 is provided with a support plate 25;

The upright support plate 25 is mounted at the bottom of the mounting frame 21, and the output end of the sliding cylinder 22 is fixed on the plate surface of the fixing rod 24 corresponding to the orientation of the support plate 25.

As shown in fig. 1-2, the end of the output end of the slide cylinder 22 is fixed to the mounting structure of the support plate 25, with good running stability.

Preferably, the four mounting frames 21 are symmetrically distributed with the center point of the lower brick mechanism 6 as a center, and the pushing wheels 23 of the four mounting frames 21 face four corners of the lower brick mechanism 6 respectively.

As shown in fig. 1-2, this arrangement improves the smoothness of moving the ceramic large plates to be boxed.

Further, the mounting frame 21 is provided with two pushing wheels 23;

The axial lines of the four driving wheels 23 of the two mounting frames 21 adjacent to each other in the front and back are positioned on the same vertical plane;

all the center points of the pushing wheels 23 are positioned on the same horizontal plane.

As shown in fig. 1, this can avoid the phenomenon that the plurality of pushing wheels 23 are not simultaneously abutted against the ceramic large plate to be boxed, avoid the occurrence of rotation of one corner of the ceramic large plate to be boxed, and further avoid the occurrence of dislocation of the side surfaces of the pushing wheels 23 and the side surfaces of the ceramic large plate to be boxed.

Further, the centering module 2 further comprises a guide rod 26, a sliding cylinder fixing plate 27 and a guide sleeve 28;

the left end and the right end of the fixed rod 24 are respectively provided with the sliding cylinder fixed plate 27, and the sliding cylinder 22 is arranged on the plate surface of the sliding cylinder fixed plate 27 facing the middle part of the corresponding fixed rod 24;

One ends of the two guide sleeves 28 are respectively arranged close to the front edge and the rear edge of the sliding cylinder fixing plate 27, the other ends of the two guide sleeves 28 extend towards the middle part of the corresponding fixing rod 24, and the two guide sleeves 28 are respectively positioned in front of or behind the sliding cylinder 22; one end of the guide rod 26 extending in the left-right direction is exposed to the other end of the guide sleeve 28, and the other end of the guide rod 26 passes through the guide sleeve 28 and the sliding cylinder fixing plate 27 and is connected to the plate surface of the corresponding support plate 25.

As shown in fig. 3, after the sliding cylinder 22 is started, the output end of the sliding cylinder 22 drives the supporting plate 25 to move towards the middle part of the fixed rod 24 along the guide rod 26, so that the pushing wheel 23 abuts against the side surface of the ceramic large plate to be packaged, and the moving stability of the pushing wheel 23 can be further improved.

Specifically, the jacking module 3 includes a plurality of bases 30, a plurality of top wheels 31, a plurality of lifting frames 32, and a plurality of lifting motors 33;

the plurality of pedestals 30 extending in the left-right direction are arranged below the conveyor line 1 at intervals in the front-rear direction; two lifting motors 33 are mounted on the top surface of the base 30 at left and right intervals, and the output ends of the lifting motors 33 extend upwards; the lifting frame 32 extending in the left-right direction is mounted on the top surfaces of the output ends of the two lifting motors 33 at left-right intervals; a plurality of top wheels 31 are arranged at intervals left and right and are mounted on the top surface of the lifting frame 32, and the top wheels 31 are positioned between two adjacent conveyor belts 11 left and right.

As shown in fig. 1 and 2, when the lifting motor 33 in the lifting module 3 is started, the lifting motor 33 pushes the lifting frame 32 to rise, so that the plurality of top wheels 31 mounted on the top surface of the lifting frame 32 lift up the ceramic large plate to be packaged, and the bottom surface of the rising ceramic large plate to be packaged is separated from the top surface of the conveying line 11.

Preferably, the top wheel 31 is rotatable along a central axis extending in the front-rear direction.

As shown in fig. 1 and 2, the top wheel 31 is rotatable along a central axis extending in the front-rear direction, so that friction and abrasion between the bottom surface of the ceramic large plate to be packaged and the outer peripheral surface of the top wheel 31 can be reduced, and the load of pushing the ceramic large plate to be packaged to move left and right by the pushing wheel 23 can be reduced.

Further, the brick blocking device also comprises a brick blocking module;

The brick blocking module is positioned in front of the brick discharging mechanism 6;

a first sensor 4, a second sensor 7 and a third sensor 8 which are sequentially arranged from back to front are also arranged between the two left and right adjacent conveyor belts 11;

the first inductor 4 is close to the rear input end of the conveying line 1, the second inductor 7 is close to the middle part of the brick-falling mechanism 6, and the third inductor 8 is close to the brick-blocking module;

The first sensor 4, the second sensor 7, the third sensor 8 and the brick blocking module are respectively connected with a PLC controller through signals.

When the ceramic large plate brick feeding machine with the centering function operates, the front end of the ceramic large plate to be boxed enters the rear input end of the conveying line 1, the first sensor 4 is triggered, the PLC controller receives signals and sends out signals to start a motor for driving the plurality of conveying belts 11, the plurality of conveying belts 11 convey the ceramic large plate to be boxed forwards, when the front end of the ceramic large plate to be boxed passes through the center point of the brick feeding mechanism 6, the second sensor 7 is triggered, the PLC controller receives signals and sends out signals to start a brick blocking cylinder in the brick blocking module, the baffle plate in the brick blocking module is pushed to be lifted upwards by the brick blocking cylinder, the baffle plate is exposed to the top surface of the conveying line 1, when the front end of the ceramic large plate to be boxed which is going forward is close to the baffle plate, the third sensor 8 is triggered, the PLC controller receives signals and sends out signals to stop the motor for driving the plurality of conveying belts 11, and then the front end of the ceramic large plate to be boxed moves forwards under the inertia of the conveying belt 11 and stops, and then the front end of the ceramic conveying belt is contacted with the baffle plate to be boxed upwards, and the ceramic large plate to be boxed is lifted upwards is separated from the top surface of the ceramic large plate to be boxed 11.

Preferably, the top wheel 31 and the pushing wheel 23 are made of wear-resistant elastic materials.

The top wheel 31 and the pushing wheel 23 are made of wear-resistant elastic plastics or elastic rubber, so that rigid collision with the side surface of the ceramic large plate to be boxed can be avoided, and the service life is long.

In summary, as shown in fig. 1-3, in the embodiment of the utility model, the ceramic large plate brick-discharging machine with centering function pushes the ceramic large plate to be packaged to move left and right by matching the four sliding cylinders 22 with the corresponding pushing wheels 23, and makes the center point of the ceramic large plate to be packaged upwards aligned with the center point of the brick-discharging mechanism 6, so that the dislocation of the ceramic large plate to be packaged and the packing box can be avoided, and the deviation of the ceramic large plate to be packaged can be corrected, and the damage of the ceramic large plate to be packaged, the packing box and/or the brick-discharging mechanism 6 can be avoided.

The technical principle of the present utility model is described above in connection with the specific embodiments. The description is made for the purpose of illustrating the general principles of the utility model and should not be taken in any way as limiting the scope of the utility model. Other embodiments of the utility model will be apparent to those skilled in the art from consideration of this specification without undue burden.

Claims (10)

1. The ceramic large plate brick discharging machine with the centering function comprises a conveying line and a brick discharging mechanism, and is characterized by further comprising a centering module and a jacking module;

The jacking module is used for upwards supporting the ceramic large plate to be boxed;

the centering module comprises a mounting frame, a sliding cylinder, a pushing wheel and at least two fixing rods;

The two fixing rods are arranged below the conveying line at intervals in the front-back direction, and the left end and the right end of each fixing rod are exposed out of the left side and the right side of the conveying line;

The left end and the right end of the fixed rod are respectively provided with the sliding cylinder, the output end of the sliding cylinder extends outwards, and the mounting frame is arranged at the output end of the sliding cylinder; the pushing wheel is arranged at the top of the mounting frame, is positioned above the conveying line and faces to the brick discharging mechanism positioned in the middle of the conveying line; the side surface of the pushing wheel is used for propping against the side surface of the ceramic large plate to be boxed.

2. The ceramic large plate brick machine with centering function of claim 1, further comprising a height sensor and a PLC controller;

The conveying line comprises a plurality of conveying belts extending along the front-back direction; the conveying belt is used for supporting and conveying the large ceramic plates to be boxed;

The height sensor is arranged right below the brick-discharging mechanism and is positioned between two adjacent conveying belts;

The jacking module, the sliding cylinder and the height sensor are respectively connected with the PLC controller through signals.

3. The ceramic large plate brick machine with centering function according to claim 1, wherein the mounting frame is provided with a support plate;

the upright support plate is arranged at the bottom of the mounting frame, and the output end of the sliding cylinder is fixed on the plate surface of the support plate, which corresponds to the direction of the support plate, of the fixing rod.

4. The ceramic large plate brick laying machine with the centering function according to claim 1, wherein four mounting frames are symmetrically distributed with a center point of the brick laying mechanism as a center, and pushing wheels of the four mounting frames face four corners of the brick laying mechanism respectively.

5. The ceramic large plate brick machine with centering function according to claim 1, wherein the mounting frame is provided with two pushing wheels;

The axial lines of the four driving wheels of the two mounting frames which are adjacent in front and back are positioned on the same vertical plane;

and the center points of all the pushing wheels are positioned on the same horizontal plane.

6. The ceramic large plate brick machine with centering function according to claim 3, wherein the centering module further comprises a guide rod, a sliding cylinder fixing plate and a guide sleeve;

The left end and the right end of the fixed rod are respectively provided with the sliding cylinder fixed plate, and the sliding cylinder is arranged on the plate surface of the sliding cylinder fixed plate facing the middle part of the corresponding fixed rod;

One ends of the two guide sleeves are respectively close to the front edge and the rear edge of the sliding cylinder fixing plate, the other ends of the two guide sleeves extend towards the middle part of the corresponding fixing rod, and the two guide sleeves are respectively positioned in front of or behind the sliding cylinder; one end of the guide rod extending along the left-right direction is exposed out of the other end of the guide sleeve, and the other end of the guide rod penetrates through the guide sleeve and the sliding cylinder fixing plate and is connected with the corresponding plate surface of the support plate.

7. The ceramic large plate brick machine with centering function of claim 2, wherein the jacking module comprises a plurality of bases, a plurality of top wheels, a plurality of lifting frames and a plurality of lifting motors;

The bases extending in the left-right direction are arranged below the conveying line at intervals in the front-back direction; the two lifting motors are arranged on the top surface of the base at left and right intervals, and the output ends of the lifting motors extend upwards; the lifting frames extending along the left-right direction are arranged on the top surfaces of the output ends of the two lifting motors at left-right intervals; the top wheel frames are arranged on the top surface of the lifting frame at intervals left and right, and the top wheel is positioned between two left and right adjacent conveying belts.

8. The ceramic tile under-large-plate brick machine with centering function according to claim 7, wherein the top wheel is rotatable along a central axis extending in a front-rear direction.

9. The ceramic large plate brick machine with centering function of claim 7, further comprising a brick blocking module;

the brick blocking module is positioned in front of the brick discharging mechanism;

a first sensor, a second sensor and a third sensor which are sequentially arranged from back to front are also arranged between the two left and right adjacent conveying belts;

The first sensor is close to the rear input end of the conveying line, the second sensor is close to the middle of the brick discharging mechanism, and the third sensor is close to the brick blocking module;

The first inductor, the second inductor, the third inductor and the brick blocking module are respectively connected with the PLC controller through signals.

10. The ceramic tile machine with centering function of claim 7, wherein the top wheel and the pushing wheel are both made of wear-resistant elastic materials.