CN112848652A - Ceramic high-precision automatic printing equipment and process thereof - Google Patents

Abstract

The invention discloses a ceramic high-precision automatic printing device, which comprises a workbench, wherein a feeding mechanism is arranged on one side of the workbench, a divider is arranged on the surface of the middle part of the workbench, a rotating table is arranged on the top end of the divider, at least four clamping mechanisms are circumferentially arranged on the surface of the rotating table, a supporting seat is arranged outside one side of the workbench, a first air cylinder fixing seat is arranged on the supporting seat, a first air cylinder is arranged on the first air cylinder fixing seat, the driving end of the first air cylinder penetrates through the first air cylinder fixing seat from outside to inside and is connected with a first material pushing plate, a supporting column is arranged outside one side of the workbench, a second air cylinder is arranged on the top end of the inner side of the supporting column, the driving end of the second air cylinder penetrates through the top surface of the supporting column from top to bottom and is connected with a printing device, and a discharging mechanism is, the ceramic surface produced by the printing equipment and the printing process has good printing effect and accurate printing position.

Description

Ceramic high-precision automatic printing equipment and process thereof

Technical Field

The invention relates to the technical field of ceramic printing, in particular to high-precision automatic ceramic printing equipment and a process thereof.

Background

The ceramic printing is one of ceramic decoration, and the traditional ceramic printing modes comprise three modes, namely, printing patterns by using a stamp carved with decorative patterns, blank making printing by using a mould carved with patterns and screen printing; with the progress of science and technology, some devices capable of adhering stained paper to the white tire type surface for printing are designed; however, when some existing automatic printing equipment carries out printing processing on a white matrix type, the position of the white matrix type is not accurately fixed, so that stained paper cannot be accurately attached to the surface of the white matrix type, and the effect and the processing efficiency of ceramic printing are reduced; therefore, it is necessary to design a high-precision automatic ceramic printing device and a process thereof.

Disclosure of Invention

Aiming at the technical defects, the invention provides the printing equipment and the printing process with good ceramic surface printing effect and accurate printing position.

In order to achieve the purpose, the invention is realized by the following technical scheme:

the invention provides a high-precision automatic ceramic printing device, which comprises a workbench, wherein a feeding mechanism is arranged on one side of the workbench, a divider is arranged on the surface of the middle part of the workbench, a rotating table is arranged on the top end of the divider, at least four clamping mechanisms are circumferentially arranged on the surface of the rotating table, a supporting seat is arranged outside one side of the workbench, the supporting seat is provided with a first air cylinder fixing seat which is provided with a first air cylinder, the driving end of the first cylinder penetrates through the first cylinder fixing seat from outside to inside and is connected with a first material pushing plate, a supporting column is arranged outside one side of the workbench, a second cylinder is arranged on the top end of the inner side of the supporting column, the driving end of the second air cylinder penetrates through the top surface of the supporting column from top to bottom and is connected with the printing device, and a discharging mechanism is arranged outside one side of the workbench.

Further, feed mechanism is the same with discharge mechanism's structure, feed mechanism includes base, curb plate, transfer roller, conveyer belt and first motor, be provided with the base on one side of workstation, the curb plate sets up on the both sides of base surface, two be provided with a plurality of transfer roller through the pivot between the curb plate, the conveyer belt cover is established on the outside of transfer roller, first motor sets up on one side of base through first motor locating plate, the drive end of first motor runs through in the curb plate, one of them all be provided with first belt pulley, two on the pivot of transfer roller and the drive end of first motor all be provided with first belt pulley, two through the transmission of first drive belt between the first belt pulley.

Further, clamping mechanism includes support frame, third cylinder, dress arm lock and connecting plate, the third cylinder sets up on the middle part of support frame, the connecting plate sets up on the drive end of third cylinder, the one end of dress arm lock is through the pivot setting on the support frame of third cylinder both sides, the both sides on connecting plate top are connected on the middle part of dress arm lock through the pivot.

Furthermore, a fourth cylinder is arranged at the top of the support frame, and a driving end of the fourth cylinder penetrates through the top surface of the support frame from bottom to top and is connected with a support plate.

Further, a fixing plate is arranged on the surface of the divider, at least four fifth cylinder fixing seats are circumferentially arranged on the surface of the fixing plate, a fifth cylinder is arranged on the fifth cylinder fixing seat, and a second material pushing plate is arranged at the driving end of the fifth cylinder.

Further, a second motor is arranged in the workbench below the divider, second belt pulleys are arranged on the driving end of the second motor and the input end of the divider, and the two second belt pulleys are driven by a second driving belt.

The invention also provides a high-precision automatic printing process for ceramics, which comprises the following steps:

1) soaking the white tire model in clear water for 40-50 minutes, uniformly placing the white tire model on the surface of a conveyor belt on the feeding mechanism for uniform feeding, and adjusting the height and fixing the position of the white tire model through the clamping mechanism;

2) placing stained paper in the printing device for intermittent sticking out;

3) the first cylinder drives the first material pushing plate to move inwards, and the fifth cylinder drives the second material pushing plate to move outwards, so that the white tire type position is aligned with the printing device;

4) the stained paper is attached to the white mould type surface through the printing end of the printing device, and the printed utensil is led out through the conveying belt on the discharging mechanism;

5) and after the water on the surface of the printed utensil is dried, placing the printed utensil in an oven for baking for four hours at the baking temperature of eight hundred ℃, and finishing the printing manufacturing process.

The invention has the beneficial effects that:

the white matrix type is transmitted to a supporting plate of a clamping mechanism through a feeding mechanism, the supporting plate is driven to move up and down through a fourth cylinder so as to adjust the height of the white matrix type, a connecting plate is driven to move downwards through a third cylinder so as to drive a clamping arm to clamp the white matrix type, the white matrix type is driven to rotate to a position between a first material pushing plate and a second material pushing plate through a divider, the first material pushing plate is driven to move inwards through the first cylinder, the second material pushing plate is driven to move outwards through a fifth cylinder so as to align the position of the white matrix type with a printing device, then the white matrix type is driven to rotate to the position below the printing device through the divider, stained paper is attached to the surface of the white matrix type through the printing device, finally the white matrix type is driven to rotate to one side of a discharging mechanism through the divider, a workpiece is pushed out to the discharging mechanism through the second material pushing plate and is discharged, the printing effect of the ceramic surface produced by the printing device is good and, the automation degree is high.

Drawings

FIG. 1 is a schematic view of a printing apparatus according to the present invention.

Fig. 2 is a schematic structural view of the feeding mechanism.

Fig. 3 is a schematic structural view of the clamping mechanism.

Fig. 4 is a schematic structural diagram of the first stripper plate arranged on the first cylinder.

FIG. 5 is a schematic structural view of the printing device disposed on the second cylinder.

Fig. 6 is a schematic structural diagram of the divider arranged on the workbench.

In the figure, a workbench 1, a divider 2, a rotary table 3, a support base 4, a first cylinder fixing base 5, a first cylinder 6, a first material pushing plate 7, a support column 8, a second cylinder 9, a printing device 10, a base 11, a side plate 12, a conveying roller 13, a conveying belt 14, a first motor 15, a first belt pulley 16, a first conveying belt 17, a support frame 18, a third cylinder 19, a clamping arm 20, a connecting plate 21, a fourth cylinder 22, a support plate 23, a fixing plate 24, a fifth cylinder fixing base 25, a fifth cylinder 26, a second material pushing plate 27, a feeding mechanism 28, a discharging mechanism 29, a second motor 30, a second belt pulley 31 and a second conveying belt 32.

Detailed Description

As shown in fig. 1 to 6, the invention provides a high-precision automatic ceramic printing device, which comprises a workbench 1, wherein a feeding mechanism 28 is arranged on one side of the workbench 1, a divider 2 is arranged on the surface of the middle part of the workbench 1, a rotary table 3 is arranged on the top end of the divider 2, at least four clamping mechanisms are circumferentially arranged on the surface of the rotary table 3, a support base 4 is arranged outside one side of the workbench 1, a first cylinder fixing base 5 is arranged on the support base 4, a first cylinder 6 is arranged on the first cylinder fixing base 5, the driving end of the first cylinder 6 penetrates through the first cylinder fixing base 5 from outside to inside and is connected with a first material pushing plate 7, a support pillar 8 is arranged outside one side of the workbench 1, a second cylinder 9 is arranged on the top end of the inner side of the support pillar 8, the driving end of the second cylinder 9 penetrates through the top surface of the support pillar 8 from top to bottom and is connected with a printing device, a discharging mechanism 29 is arranged outside one side of the workbench 1.

Feed mechanism 28 is the same with discharge mechanism 29's structure, feed mechanism 28 includes base 11, curb plate 12, transfer roller 13, conveyer belt 14 and first motor 15, be provided with base 11 on one side of workstation 1, curb plate 12 sets up on the both sides on base 11 surface, two be provided with a plurality of transfer roller 13 through the pivot between the curb plate 12, the cover of conveyer belt 14 is established on the outside of transfer roller 13, first motor 15 sets up on one side of base 11 through first motor locating plate, in the drive end of first motor 15 runs through curb plate 12, one of them all be provided with first belt pulley 16, two on the pivot of transfer roller 13 and the drive end of first motor 15 all be provided with first belt pulley 16, two through the transmission of first transfer belt 17 between the first belt pulley 16.

The clamping mechanism comprises a support frame 18, a third cylinder 19, a clamping arm 20 and a connecting plate 21, the third cylinder 19 is arranged on the middle of the support frame 18, the connecting plate 21 is arranged on a driving end of the third cylinder 19, one end of the clamping arm 20 is arranged on the support frame 18 on two sides of the third cylinder 19 through a rotating shaft, and two sides of the top end of the connecting plate 21 are connected to the middle of the clamping arm 20 through a rotating shaft.

The top of the support frame 18 is provided with a fourth cylinder 22, and the driving end of the fourth cylinder 22 penetrates through the top surface of the support frame 18 from bottom to top and is connected with a support plate 23.

The surface of the divider 2 is provided with a fixing plate 24, the surface of the fixing plate 24 is circumferentially provided with at least four fifth cylinder fixing seats 25, the fifth cylinder fixing seats 25 are provided with fifth cylinders 26, and the driving ends of the fifth cylinders 26 are provided with second material pushing plates 27.

A second motor 30 is arranged in the workbench below the divider 2, a driving end of the second motor 30 and an input end of the divider 2 are both provided with second belt pulleys 31, and the two second belt pulleys 31 are driven by a second driving belt 32.

The invention also provides a high-precision automatic printing process for ceramics, which comprises the following steps:

1) soaking the white tire type in clean water for 40-50 minutes, uniformly placing the white tire type on the surface of a conveyor belt 14 on a feeding mechanism 28, driving a conveying roller 13 to rotate through a first motor 15, uniformly feeding the white tire type through the conveyor belt 14, conveying the white tire type onto a support plate 23, driving the support plate 23 to move up and down through a fourth cylinder 22 to adjust the height of the white tire type, driving a connecting plate 21 to move downwards through a third cylinder 19, and driving a clamping arm 20 to clamp the white tire type;

2) placing the stained paper in the printing device 10 for intermittent sticking out;

3) the second motor 30 drives the divider 2 to work, the white tire model is driven by the divider 2 to rotate to a position between the first material pushing plate 7 and the second material pushing plate 27, the first material pushing plate 7 is driven to move inwards by the first cylinder 6, and the second material pushing plate 27 is driven to move outwards by the fifth cylinder 26, so that the white tire model is aligned with the printing device 10;

4) the white matrix type is driven by the divider 2 to rotate to the lower part of the printing device 10, stained paper is attached to the surface of the white matrix type by the printing end of the printing device 10, the white matrix type is driven by the divider 2 to rotate to one side of the discharging mechanism 29, a workpiece is pushed out of the discharging mechanism 29 by the second material pushing plate 27 and is led out by the conveying belt 14 on the discharging mechanism 29;

5) and after the water on the surface of the printed utensil is dried, placing the printed utensil in an oven for baking for four hours at the baking temperature of eight hundred ℃, and finishing the printing manufacturing process.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. A ceramic high-precision automatic printing device comprises a workbench and is characterized in that a feeding mechanism is arranged on one side of the workbench, a divider is arranged on the surface of the middle part of the workbench, a rotating table is arranged on the top end of the divider, at least four clamping mechanisms are circumferentially arranged on the surface of the rotating table, a supporting seat is arranged outside one side of the workbench, the supporting seat is provided with a first air cylinder fixing seat which is provided with a first air cylinder, the driving end of the first cylinder penetrates through the first cylinder fixing seat from outside to inside and is connected with a first material pushing plate, a supporting column is arranged outside one side of the workbench, a second cylinder is arranged on the top end of the inner side of the supporting column, the driving end of the second air cylinder penetrates through the top surface of the supporting column from top to bottom and is connected with the printing device, and a discharging mechanism is arranged outside one side of the workbench.

2. The ceramic high-precision automatic printing equipment according to claim 1, wherein the feeding mechanism and the discharging mechanism are identical in structure, the feeding mechanism comprises a base, side plates, a conveying roller, a conveying belt and a first motor, the base is arranged on one side of the workbench, the side plates are arranged on two sides of the surface of the base, a plurality of conveying rollers are arranged between the two side plates through rotating shafts, the conveying belt is sleeved on the outer side of the conveying roller, the first motor is arranged on one side of the base through a first motor positioning plate, the driving end of the first motor penetrates into the side plates, a first belt pulley is arranged on each of the rotating shaft of the conveying roller and the driving end of the first motor, and the two first belt pulleys are driven through the first conveying belt.

3. The ceramic high-precision automatic printing equipment as claimed in claim 1, wherein the clamping mechanism comprises a support frame, a third cylinder, clamping arms and a connecting plate, the third cylinder is arranged in the middle of the support frame, the connecting plate is arranged at a driving end of the third cylinder, one end of each clamping arm is arranged on the support frame at two sides of the third cylinder through a rotating shaft, and two sides of the top end of the connecting plate are connected to the middle of each clamping arm through rotating shafts.

4. The ceramic high-precision automatic printing equipment as claimed in claim 3, wherein a fourth cylinder is arranged at the top of the support frame, and a driving end of the fourth cylinder penetrates through the top surface of the support frame from bottom to top and is connected with a support plate.

5. The ceramic high-precision automatic printing equipment as claimed in claim 1, wherein a fixed plate is arranged on the surface of the divider, at least four fifth cylinder fixing seats are circumferentially arranged on the surface of the fixed plate, a fifth cylinder is arranged on the fifth cylinder fixing seats, and a second material pushing plate is arranged on a driving end of the fifth cylinder.

6. The ceramic high-precision automatic printing equipment as claimed in claim 1, wherein a second motor is arranged in the workbench below the divider, a second belt pulley is arranged on each of the driving end of the second motor and the input end of the divider, and the second belt pulleys are driven by a second driving belt.

7. The ceramic high-precision automatic printing process according to any one of claims 1 to 6, characterized by comprising the following steps:

1) soaking the white tire model in clear water for 40-50 minutes, uniformly placing the white tire model on the surface of a conveyor belt on the feeding mechanism for uniform feeding, and adjusting the height and fixing the position of the white tire model through the clamping mechanism;

2) placing stained paper in the printing device for intermittent sticking out;

3) the first cylinder drives the first material pushing plate to move inwards, and the fifth cylinder drives the second material pushing plate to move outwards, so that the white tire type position is aligned with the printing device;

4) the stained paper is attached to the white mould type surface through the printing end of the printing device, and the printed utensil is led out through the conveying belt on the discharging mechanism;

5) and after the water on the surface of the printed utensil is dried, placing the printed utensil in an oven for baking for four hours at the baking temperature of eight hundred ℃, and finishing the printing manufacturing process.

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