CN111975956A - Ceramic processing system - Google Patents

Abstract

The invention relates to the technical field of ceramic equipment, in particular to a ceramic processing system which has the advantage of fixing the interior of a ceramic product and comprises a rotating support assembly, a lifting assembly, a transverse moving assembly, a glazing assembly, a driving assembly, four central support assemblies and four clamping jaw assemblies.

Description

Ceramic processing system

Technical Field

The invention relates to the technical field of ceramic equipment, in particular to a ceramic processing system.

Background

The invention discloses a ceramic processing method with publication number CN110774428A, and relates to the technical field of ceramic processing. The ceramic processing method comprises the following steps: fixedly placing a ceramic workpiece on a workbench; the plurality of spray heads are arranged beside the ceramic machined part at intervals from top to bottom of the outline of the ceramic machined part; the workbench rotates along with the ceramic workpiece; glaze is sprayed from the surface of the ceramic workpiece by each spray head. The invention can be suitable for ceramic workpieces with different shapes, the spraying is more uniform, comprehensive and free of viewing angle, and because each spray head is as close to the surface of the ceramic workpiece as possible, the spraying is accurate and fine, and the problems of glaze waste, cost increase and the like caused by splashing of the glaze can be avoided. In addition, the smaller the diameter of the spray head is, the more the quantity of the spray head is, and the denser the arrangement is, the more accurate and fine the spray coating is. The disadvantage of this invention is that the inner part of the ceramic article cannot be fixed.

Disclosure of Invention

The invention aims to provide a ceramic processing system which has the advantage of fixing the interior of a ceramic product.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a ceramic machining system, includes rotation support subassembly, lifting unit, sideslip subassembly, glazing subassembly, drive assembly, center supporting component and clamping jaw subassembly, lifting unit fixed connection is on rotation support subassembly, and the sideslip subassembly passes through threaded connection on lifting unit, and glazing subassembly sliding connection is on the sideslip subassembly, and drive assembly passes through threaded connection on rotation support subassembly, and center supporting component fixed connection is on rotation support subassembly, and clamping jaw subassembly is provided with four, and the last equipartition of rotation support subassembly has four clamping jaw subassemblies, and four equal sliding connection of clamping jaw subassembly are on drive assembly, and center supporting component sliding connection is on drive assembly.

The rotary supporting component comprises a bottom plate, a rib plate, a top plate, supporting rods, a rotary motor, a rotary plate, a mounting plate and a threaded pipe, the rib plate is fixedly connected to the middle of the right side of the bottom plate, the top plate is fixedly connected to the upper end of the right side of the bottom plate, the four supporting rods are fixedly connected to the bottom plate, the rotary motor is fixedly connected to the middle of the left side of the bottom plate, the rotary plate is fixedly connected to an output shaft of the rotary motor, the mounting plate is fixedly connected to the rotary plate, and.

The lifting assembly comprises lifting threaded screws, synchronous gears, synchronous belts and a lifting motor, the lower ends of the two lifting threaded screws are respectively rotatably connected to the front side and the rear side of the rib plate, the upper ends of the two lifting threaded screws are respectively rotatably connected to the front side and the rear side of the top plate, the two lifting threaded screws are respectively provided with the synchronous gears, the two synchronous gears are in synchronous belt transmission, the lifting motor is fixedly connected to the top plate, and one lifting threaded screw is fixedly connected to an output shaft of the lifting motor.

The transverse moving assembly comprises a lifting plate, transverse guide rods, a transverse moving screw rod, a transverse moving motor, a transverse moving sliding block and a combined sliding hole, the lifting plate is connected to the two lifting screw thread lead screws through threads, the transverse guide rods are fixedly connected to the lifting plate, the transverse moving screw rod is rotatably connected to the lifting plate, the transverse moving motor is fixedly connected to the front end of the lifting plate, the transverse moving screw rod is fixedly connected to an output shaft of the transverse moving motor, the transverse moving sliding block is slidably connected to the transverse guide rods, the transverse moving sliding block and the transverse moving screw rod are in threaded transmission, and the combined sliding hole is.

The glazing assembly comprises a probe frame, a probe wheel, a glazing sprayer, a communicating pipe, a combined rod and a spring, wherein the combined rod is connected in a combined sliding hole in a sliding mode, the probe frame is fixedly connected to the left end of the combined rod, the probe wheel is connected to the probe frame in a rotating mode, the glazing sprayer is fixedly connected to the combined rod, the communicating pipe is fixedly connected to the glazing sprayer, the left end of the spring is fixedly connected to the probe frame, and the right end of the spring is fixedly connected to a transverse sliding block.

The driving assembly comprises a center shaft air cylinder, a center shaft rod and a center shaft sucker, the center shaft air cylinder is fixedly connected to the rotating plate, the center shaft rod is fixedly connected to the air cylinder rod of the center shaft air cylinder, and the center shaft sucker is fixedly connected to the center shaft rod.

The central support component comprises a cross, lifting sliding grooves, an internal thread rotating cylinder and an adjusting frame, a plurality of lifting sliding grooves are uniformly distributed on the cross, the internal thread rotating cylinder is rotatably connected to the middle of the cross, the adjusting frame is fixedly connected to the middle of the internal thread rotating cylinder, and the internal thread rotating cylinder and a threaded pipe are connected through threads.

The clamping jaw assembly comprises a clamping jaw, an adjusting groove, a rotating groove, an adjusting rod and a fixed shaft rod, the adjusting groove and the rotating groove are formed in the clamping jaw, the upper end of the adjusting rod is connected in the adjusting groove in a rotating mode, the upper end of the fixed shaft rod is connected in the rotating groove in a rotating mode, the lower ends of the adjusting rods are connected in a plurality of lifting sliding grooves in a sliding mode respectively, and the fixed shaft rods are fixedly connected on the mounting plate.

The middle shaft rod is connected in the internal thread rotary drum in a sliding mode.

The ceramic processing system has the beneficial effects that: the invention relates to a ceramic processing system, which can realize the fixation of a ceramic by placing a plurality of clamping jaw assemblies in the ceramic, adjusting the plurality of clamping jaw assemblies to be outwards opened by a driving assembly to expand and support the inner wall of the ceramic, and supporting the bottom cover of the ceramic by a central supporting assembly, can process all positions of the outer surface of the ceramic, can not cause secondary processing and waste time due to the shielding of the outer surface caused by fixation, can also place the ceramic by the central supporting assembly, can drive the plurality of clamping jaw assemblies to fix the bottom edge of the ceramic by the driving assembly, is convenient to process the inner wall and the outer surface of the ceramic, can drive the plurality of clamping jaw assemblies to rotate by rotating the supporting assembly, further realizes the processing of the excircle of a rotator-shaped ceramic, and can automatically glaze the outer surface area of the ceramic by a glazing assembly, the lifting assembly can drive the transverse moving assembly to lift, the transverse moving assembly drives the glazing assembly to transversely slide, and the glazing assembly can automatically process the surface of the ceramic ware with the plane.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element 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, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

FIG. 1 is a schematic diagram of the overall construction of a ceramic processing system of the present invention;

FIG. 2 is a schematic structural view of the rotary support assembly of the present invention;

FIG. 3 is a schematic structural view of the lift assembly of the present invention;

FIG. 4 is a schematic illustration of the construction of the traversing assembly of the invention;

FIG. 5 is a schematic structural view of the glazing assembly of the present invention;

FIG. 6 is a schematic structural view of the drive assembly of the present invention;

FIG. 7 is a schematic structural view of the core support assembly of the present invention;

figure 8 is a schematic view of the jaw assembly of the present invention.

In the figure: rotating the support assembly 1; a bottom plate 1-1; rib plate 1-2; a top plate 1-3; 1-4 of a support rod; rotating the motor 1-5; rotating the plates 1-6; mounting plates 1-7; 1-8 parts of a threaded pipe; a lifting assembly 2; 2-1 of a lifting threaded screw rod; a synchronizing gear 2-2; 2-3 of a synchronous belt; 2-4 of a lifting motor; a traverse assembly 3; a lifting plate 3-1; a transverse guide rod 3-2; 3-3 of a transverse screw rod; 3-4 of a transverse moving motor; 3-5 of a transverse sliding block; 3-6 of combined sliding holes; a glazing assembly 4; a probe holder 4-1; 4-2 of a probe wheel; 4-3 of a glazing nozzle; a communicating pipe 4-4; 4-5 of a combined rod; 4-6 of a spring; a drive assembly 5; a middle shaft cylinder 5-1; 5-2 parts of a middle shaft rod; a middle shaft sucker 5-3; a center support assembly 6; 6-1 of a cross; a lifting chute 6-2; 6-3 of an internal thread rotary drum; 6-4 of an adjusting frame; a jaw assembly 7; a clamping jaw 7-1; an adjusting groove 7-2; a rotating groove 7-3; 7-4 of an adjusting rod; and a fixed shaft 7-5.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 8, and a ceramic processing system includes a rotation support assembly 1, a lifting assembly 2, a traverse assembly 3, a glazing assembly 4, a center support assembly 5, a drive assembly 6, and four clamping jaw assemblies 7, where the lifting assembly 2 is fixedly connected to the rotation support assembly 1, the traverse assembly 3 is connected to the lifting assembly 2 through a thread, the glazing assembly 4 is slidably connected to the traverse assembly 3, the drive assembly 6 is connected to the rotation support assembly 1 through a thread, the center support assembly 5 is fixedly connected to the rotation support assembly 1, the clamping jaw assemblies 7 are four in number, four clamping jaw assemblies 7 are uniformly distributed on the rotation support assembly 1, the four clamping jaw assemblies 7 are all slidably connected to the drive assembly 6, and the center support assembly 5 is slidably connected to the drive assembly 6.

The clamping jaw assemblies 7 can be placed in the ceramic ware, the clamping jaw assemblies 7 are adjusted to be opened outwards through the driving assembly 6, the inner wall of the ceramic ware is expanded and supported, the bottom cover of the ceramic ware is supported through the central supporting assembly 5, the ceramic ware is fixed, the outer surface of the ceramic ware can be processed at all positions, secondary processing and time waste caused by the shielding of the outer surface due to fixation can be avoided, the ceramic ware can be placed through the central supporting assembly 5, the clamping jaw assemblies 7 are driven to fix the bottom edge of the ceramic ware through the driving assembly 6, the inner wall and the outer surface of the ceramic ware can be processed conveniently, the clamping jaw assemblies 7 can be driven to rotate through the rotating supporting assembly 1, the processing of the excircle of the rotator-shaped ceramic ware can be further realized, and the external surface area of the ceramic ware can be glazed automatically through the glazing assembly 4, the lifting component 2 can also drive the transverse moving component 3 to lift, and the transverse moving component 3 drives the glazing component 4 to transversely slide, so that the glazing component 4 can automatically process the surface of the ceramic ware with the plane.

The second embodiment is as follows:

referring to fig. 1-8, the rotary support assembly 1 includes a bottom plate 1-1, a rib plate 1-2, a top plate 1-3, and a support rod 1-4, the novel rotary plate comprises rotary motors 1-5, rotary plates 1-6, mounting plates 1-7 and threaded pipes 1-8, rib plates 1-2 are fixedly connected to the middle of the right side of a bottom plate 1-1, a top plate 1-3 is fixedly connected to the upper end of the right side of the bottom plate 1-1, four support rods 1-4 are fixedly connected to the bottom plate 1-1, the rotary motors 1-5 are fixedly connected to the middle of the left side of the bottom plate 1-1, the rotary plates 1-6 are fixedly connected to output shafts of the rotary motors 1-5, the mounting plates 1-7 are fixedly connected to the rotary plates 1-6, and the threaded pipes 1-8 are fixedly connected to the middle of the mounting plates.

The rotating motors 1-5 are started, the rotating motors 1-5 drive the rotating plates 1-6 to rotate, the rotating plates 1-6 are supported by the supporting rods 1-4, the rotating plates 1-6 are prevented from inclining, the rotating plates 1-6 drive the mounting plates 1-7 to rotate, the mounting plates 1-7 drive the clamping jaw assemblies 7 to rotate, the rotating plates 1-6 drive the central supporting assembly 5 to rotate, rotation of the ceramic ware is achieved, workers can process the outer circle of the ceramic ware of the revolving body conveniently, and the processing is convenient and efficient.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-8, the lifting assembly 2 includes two lifting screw rods 2-1, synchronous gears 2-2, synchronous belts 2-3 and a lifting motor 2-4, the lower ends of the two lifting screw rods 2-1 are respectively rotatably connected to the front and rear sides of the rib plate 1-2, the upper ends of the two lifting screw rods 2-1 are respectively rotatably connected to the front and rear sides of the top plate 1-3, the two lifting screw rods 2-1 are respectively provided with the synchronous gears 2-2, the two synchronous gears 2-2 are driven by the synchronous belts 2-3, the lifting motor 2-4 is fixedly connected to the top plate 1-3, and the output shaft of the lifting motor 2-4 is fixedly connected to one of the lifting screw rods 2-1.

The lifting motor 2-4 is started, the lifting motor 2-4 drives the lifting threaded screw rod 2-1 fixedly connected with the lifting motor to rotate so as to drive the synchronous gear 2-2 at the front end to rotate, the synchronous gear 2-2 at the front end drives another synchronous gear 2-2 to rotate through the synchronous belt 2-3 so as to drive the lifting threaded screw rod 2-1 at the rear end to rotate, the two lifting threaded screw rods 2-1 drive the transverse moving component 3 to ascend and descend through threads, the transverse moving component 3 drives the glazing component 4 to ascend and descend, up-and-down movement of the glazing component 4 is realized, and the glazes on the ceramic wares with different heights.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-8, the traverse assembly 3 includes a lifting plate 3-1, a traverse guide rod 3-2, a traverse screw 3-3, a traverse motor 3-4, a traverse slide block 3-5 and a combined slide hole 3-6, the lifting plate 3-1 is connected to two lifting screw rods 2-1 through screw threads, the traverse guide rod 3-2 is fixedly connected to the lifting plate 3-1, the traverse screw 3-3 is rotatably connected to the lifting plate 3-1, the traverse motor 3-4 is fixedly connected to the front end of the lifting plate 3-1, the traverse screw 3-3 is fixedly connected to the output shaft of the traverse motor 3-4, the traverse slide block 3-5 is slidably connected to the traverse guide rod 3-2, the traverse slide block 3-5 and the traverse screw 3-3 are in screw thread transmission, the transverse moving slide block 3-5 is provided with a combined sliding hole 3-6.

The transverse moving motor 3-4 is started, the transverse moving motor 3-4 drives the transverse moving screw rod 3-3 to rotate, the transverse moving screw rod 3-3 drives the transverse moving slide block 3-5 to slide on the transverse guide rod 3-2 in a threaded mode, the transverse moving slide block 3-5 drives the glazing assembly 4 to move transversely, the lifting assembly 2 is matched to drive the transverse moving assembly 3 to lift, and therefore the glazing assembly 4 can conduct plane glazing on a ceramic device with a plane.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 8, the glazing assembly 4 includes a probe holder 4-1, a probe wheel 4-2, a glazing nozzle 4-3, a communicating pipe 4-4, a combined rod 4-5 and a spring 4-6, the combined rod 4-5 is slidably connected in a combined sliding hole 3-6, the probe holder 4-1 is fixedly connected to the left end of the combined rod 4-5, the probe wheel 4-2 is rotatably connected to the probe holder 4-1, the glazing nozzle 4-3 is fixedly connected to the combined rod 4-5, the communicating pipe 4-4 is fixedly connected to the glazing nozzle 4-3, the left end of the spring 4-6 is fixedly connected to the probe holder 4-1, and the right end of the spring 4-6 is fixedly connected to a traverse sliding block 3-5.

The communicating pipe 4-4 is connected to a glaze slip feeding device, the detecting wheel 4-2 is directly contacted with the ceramic, the rotation of the detecting wheel 4-2 can not scratch the surface of the ceramic, the detecting wheel 4-2 drives the combined rod 4-5 to slide, the combined rod 4-5 slides in the combined sliding hole 3-6, the length of the spring 4-6 can ensure that the detecting wheel 4-2 is always contacted with the outer surface of the ceramic, when glazing is needed, the glaze slip enters the communicating pipe 4-4 and is coated on the outer surface of the ceramic from the glazing nozzle 4-3, the detecting wheel 4-2 is always changed along with the change of the appearance of the ceramic, the glazing nozzle 4-3 is also changed along with the change of the detecting wheel 4-2, the distance between the glazing nozzle 4-3 and the ceramic is always fixed, and the glazing uniformity is ensured, the effects of more brightness, brightness and wear resistance after firing are achieved.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 8, the central support assembly 5 includes a central axis cylinder 5-1, a central axis rod 5-2 and a central axis suction cup 5-3, the central axis cylinder 5-1 is fixedly connected to the rotating plate 1-6, the central axis rod 5-2 is fixedly connected to the cylinder rod of the central axis cylinder 5-1, and the central axis suction cup 5-3 is fixedly connected to the central axis rod 5-2.

When the clamping jaw assemblies 7 are used for fixing the insides of the chinaware, the center shaft cylinder 5-1 is started, the cylinder rod of the center shaft cylinder 5-1 drives the middle shaft rod 5-2 to extend out, the center shaft rod 5-2 drives the center shaft sucker 5-3 to prop against the inner wall at the bottom end of the chinaware, the situation that the plurality of clamping jaw assemblies 7 slide on the inner wall of the chinaware due to the same diameter of the inner wall of the chinaware to scratch the chinaware to cause the defect of a product is prevented, when the plurality of clamping jaw assemblies 7 are used for fixing the outsides of the chinaware, the chinaware is firstly placed on the center shaft sucker 5-3, the center shaft cylinder 5-1 is started to adjust the placing position of the chinaware, the bottom fixing of different types of chinaware is realized by matching with the clamping and fixing of the plurality of clamping jaw assemblies 7, and the center shaft sucker 5-3 also prevents the, causing damage to the ceramic.

The seventh embodiment:

the embodiment is described below with reference to fig. 1-8, the driving assembly 6 includes a cross 6-1, a plurality of lifting chutes 6-2, an internally threaded rotating cylinder 6-3 and an adjusting bracket 6-4, the cross 6-1 is uniformly distributed with the plurality of lifting chutes 6-2, the internally threaded rotating cylinder 6-3 is rotatably connected to the middle of the cross 6-1, the adjusting bracket 6-4 is fixedly connected to the middle of the internally threaded rotating cylinder 6-3, and the internally threaded rotating cylinder 6-3 and the threaded pipe 1-8 are connected by threads.

When the external bottom clamping and fastening of the ceramic ware are carried out, the ceramic ware is placed on the middle shaft sucker 5-3, the adjusting frame 6-4 is rotated, the adjusting frame 6-4 drives the internal thread rotating cylinder 6-3 to rotate, the overlap ratio of the internal thread rotating cylinder 6-3 and the threaded pipe 1-8 is reduced, the internal thread rotating cylinder 6-3 drives the cross 6-1 to descend, the plurality of clamping jaw assemblies 7 clamp towards the middle, the external bottom end of the ceramic ware is fixed, when the internal clamping and fastening of the ceramic ware are carried out, the adjusting frame 6-4 is rotated, the distance between the cross 6-1 and the mounting plate 1-7 is shortened, the plurality of clamping jaw assemblies 7 expand outwards, the inner wall of the ceramic ware is fixed, when the external glazing or other processing of the ceramic ware is carried out, the clamping dead angle can not occur like the external clamping and fixing, the place that leads to pressing from both sides tightly can't realize processing, perhaps need carry out the secondary clamping and process, cause machining efficiency to hang down excessively.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1 to 8, the clamping jaw assembly 7 includes a clamping jaw 7-1, an adjusting groove 7-2, a rotating groove 7-3, an adjusting rod 7-4 and a fixed shaft rod 7-5, the clamping jaw 7-1 is provided with the adjusting groove 7-2 and the rotating groove 7-3, the upper end of the adjusting rod 7-4 is rotatably connected in the adjusting groove 7-2, the upper end of the fixed shaft rod 7-5 is rotatably connected in the rotating groove 7-3, the lower ends of the adjusting rods 7-4 are respectively slidably connected in the lifting chutes 6-2, and the fixed shaft rods 7-5 are fixedly connected to the mounting plate 1-7.

When the distance between the cross 6-1 and the mounting plate 1-7 is shortened, the adjusting rods 7-4 slide in the lifting chutes 6-2, the adjusting rods 7-4 drive the clamping jaws 7-1 to rotate, the clamping jaws 7-1 rotate around the corresponding fixed shaft rods 7-5, the clamping jaws 7-1 are gathered towards the middle to clamp the outside of the ceramic ware, when the ceramic ware is internally expanded and fixed, the distance between the cross 6-1 and the mounting plate 1-7 is lengthened, and the clamping jaws 7-1 are expanded towards the periphery to fix the inner wall of the ceramic ware.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1-8, and the middle shaft rod 5-2 is slidably connected in the internally threaded rotating cylinder 6-3, so that the middle shaft rod 5-2 is ensured not to incline, and the ceramic ware is ensured to be vertical.

The invention relates to a ceramic processing system, which has the use principle that: when the external bottom clamp of the ceramic ware is fixed, the ceramic ware is placed on the center shaft sucker 5-3, the cylinder rod of the center shaft cylinder 5-1 drives the middle shaft rod 5-2 to extend out, the center shaft rod 5-2 drives the center shaft sucker 5-3 to lift, the position of the ceramic ware is adjusted, the ceramic ware is clamped and fixed by matching with the plurality of clamping jaws 7-1, the bottom fixation of different types of ceramic ware is realized, the center shaft sucker 5-3 also prevents the ceramic ware from accidentally sliding down to cause the damage of the ceramic ware, the adjusting frame 6-4 is rotated, the adjusting frame 6-4 drives the internal thread rotary drum 6-3 to rotate, the coincidence degree of the internal thread rotary drum 6-3 and the threaded pipe 1-8 is reduced, the internal thread rotary drum 6-3 drives the cross 6-1 to descend, and the plurality of adjusting rods 7-4 slide in the plurality of lifting chutes 6-2, the plurality of adjusting rods 7-4 drive the plurality of clamping jaws 7-1 to rotate, the plurality of clamping jaws 7-1 rotate around the corresponding fixed shaft rods 7-5, the plurality of clamping jaws 7-1 gather towards the middle to realize the external clamping of the ceramic ware and the fixation of the external bottom end of the ceramic ware, when the ceramic ware is clamped and fastened internally, the adjusting frame 6-4 is rotated to shorten the distance between the cross 6-1 and the mounting plate 1-7, the plurality of clamping jaws 7-1 expand towards the periphery to fix the inner wall of the ceramic ware and expand and fix the inner wall of the ceramic ware, the center shaft cylinder 5-1 is started, the cylinder rod of the center shaft cylinder 5-1 drives the shaft rod 5-2 to extend out, the center shaft rod 5-2 drives the center shaft sucker 5-3 to be pressed against the inner wall at the bottom end of the ceramic ware, and the plurality of clamping jaws 7-1 are prevented from having the same diameter as the inner wall of the ceramic, the clamping jaws 7-1 slide on the inner wall of the ceramic ware, the ceramic ware is scratched, the product is poor, when the outer part of the ceramic ware is glazed or other processing is carried out, clamping dead angles cannot occur like clamping and fixing the outer part, the clamped part cannot be processed, or secondary clamping is required for processing, the processing efficiency is too low, the rotating motor 1-5 is started, the rotating motor 1-5 drives the rotating plate 1-6 to rotate, the rotating plate 1-6 is supported by the supporting rods 1-4, the rotating plate 1-6 is prevented from inclining, the rotating plate 1-6 drives the mounting plate 1-7 to rotate, the mounting plate 1-7 drives the clamping jaw assemblies 7 to rotate, the rotating plate 1-6 drives the central supporting assembly 5 to rotate, and the ceramic ware is rotated, the processing of workers on the excircle of the revolving body ceramic device is convenient, the processing is convenient, the efficiency is high, the lifting motor 2-4 is started, the lifting motor 2-4 drives the lifting screw thread 2-1 fixedly connected with the lifting screw thread to rotate so as to drive the synchronous gear 2-2 at the front end to rotate, the synchronous gear 2-2 at the front end drives the other synchronous gear 2-2 to rotate through the synchronous belt 2-3 so as to drive the lifting screw thread 2-1 at the rear end to rotate, the two lifting screw thread 2-1 drive the lifting plate 3-1 to lift through screw threads, the transverse moving motor 3-4 is started, the transverse moving motor 3-4 drives the transverse moving screw rod 3-3 to rotate, the transverse moving screw rod 3-3 drives the transverse moving slide block 3-5 to slide on the transverse guide rod 3-2, the transverse moving slide block 3-5 drives the combined rod, the up-and-down movement of the glazing component 4 is realized, the glazes can be carried out on the ceramic ware with different heights and widths, the communicating pipe 4-4 is connected on the glaze slurry feeding device, the probe wheel 4-2 is directly contacted on the ceramic ware, the rotation of the probe wheel 4-2 can not scratch the ceramic surface, the probe wheel 4-2 drives the combined rod 4-5 to slide, the combined rod 4-5 slides in the combined sliding hole 3-6, the length of the spring 4-6 can ensure that the probe wheel 4-2 is always contacted with the outer surface of the ceramic ware, when glazing is required, the glaze slurry enters the communicating pipe 4-4 and is coated on the outer surface of the ceramic ware from the glazing spray head 4-3, the probe wheel 4-2 is always changed along with the change of the appearance of the ceramic ware, and the glazing spray head 4-3 is also changed along with the change of the probe wheel 4-2, the distance between the glazing spray head 4-3 and the ceramic ware is fixed all the time, the glazing uniformity is ensured, and the effects of brightness, brightness and wear resistance after firing are achieved.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (9)

1. The utility model provides a ceramic machining system, includes rotation support assembly (1), lifting unit (2), sideslip subassembly (3), glazing subassembly (4), central support assembly (5), drive assembly (6) and clamping jaw subassembly (7), its characterized in that: lifting unit (2) fixed connection is on rotating support assembly (1), sideslip subassembly (3) pass through threaded connection on lifting unit (2), glazing subassembly (4) sliding connection is on sideslip subassembly (3), drive assembly (6) pass through threaded connection on rotating support assembly (1), center support assembly (5) fixed connection is on rotating support assembly (1), clamping jaw subassembly (7) are provided with four, the equipartition has four clamping jaw subassemblies (7) on rotating support assembly (1), four equal sliding connection of clamping jaw subassembly (7) are on drive assembly (6), center support assembly (5) sliding connection is on drive assembly (6).

2. A ceramic processing system as claimed in claim 1, wherein: the rotary supporting component (1) comprises a bottom plate (1-1), rib plates (1-2), a top plate (1-3), supporting rods (1-4), a rotary motor (1-5), rotary plates (1-6), mounting plates (1-7) and threaded pipes (1-8), the rib plates (1-2) are fixedly connected to the middle of the right side of the bottom plate (1-1), the top plate (1-3) is fixedly connected to the upper end of the right side of the bottom plate (1-1), the four supporting rods (1-4) are fixedly connected to the bottom plate (1-1), the rotary motor (1-5) is fixedly connected to the middle of the left side of the bottom plate (1-1), the rotary plates (1-6) are fixedly connected to output shafts of the rotary motor (1-5), the mounting plates (1-7) are fixedly connected to the rotary plates (1-6), the threaded pipes (1-8) are fixedly connected to the middle parts of the mounting plates (1-7).

3. A ceramic processing system as claimed in claim 2, wherein: the lifting component (2) comprises a lifting threaded screw rod (2-1) and a synchronous gear (2-2), the lifting device comprises synchronous belts (2-3) and lifting motors (2-4), the lower ends of two lifting threaded screws (2-1) are respectively rotatably connected to the front side and the rear side of a rib plate (1-2), the upper ends of the two lifting threaded screws (2-1) are respectively rotatably connected to the front side and the rear side of a top plate (1-3), synchronous gears (2-2) are respectively arranged on the two lifting threaded screws (2-1), the two synchronous gears (2-2) are driven by the synchronous belts (2-3), the lifting motors (2-4) are fixedly connected to the top plate (1-3), and output shafts of the lifting motors (2-4) are fixedly connected to one lifting threaded screw (2-1).

4. A ceramic processing system as claimed in claim 3, wherein: the transverse moving assembly (3) comprises a lifting plate (3-1), transverse guide rods (3-2), transverse moving screw rods (3-3), transverse moving motors (3-4), transverse moving sliding blocks (3-5) and combined sliding holes (3-6), the lifting plate (3-1) is connected to two lifting screw thread lead screws (2-1) through threads, the transverse guide rods (3-2) are fixedly connected to the lifting plate (3-1), the transverse moving screw rods (3-3) are rotatably connected to the lifting plate (3-1), the transverse moving motors (3-4) are fixedly connected to the front ends of the lifting plate (3-1), the transverse moving screw rods (3-3) are fixedly connected to output shafts of the transverse moving motors (3-4), the transverse moving sliding blocks (3-5) are slidably connected to the transverse guide rods (3-2), the transverse sliding block (3-5) and the transverse screw rod (3-3) are in threaded transmission, and the transverse sliding block (3-5) is provided with a combined sliding hole (3-6).

5. A ceramic processing system as claimed in claim 4, wherein: the glazing assembly (4) comprises a probe rack (4-1), a probe wheel (4-2), a glazing nozzle (4-3), a communicating pipe (4-4), a combined rod (4-5) and a spring (4-6), the combined rod (4-5) is connected in the combined sliding hole (3-6) in a sliding mode, the probe frame (4-1) is fixedly connected to the left end of the combined rod (4-5), the probe wheel (4-2) is connected to the probe frame (4-1) in a rotating mode, the glazing nozzle (4-3) is fixedly connected to the combined rod (4-5), the communicating pipe (4-4) is fixedly connected to the glazing nozzle (4-3), the left end of the spring (4-6) is fixedly connected to the probe frame (4-1), and the right end of the spring (4-6) is fixedly connected to the transverse moving sliding block (3-5).

6. A ceramic processing system as claimed in claim 5, wherein: the central support assembly (5) comprises a central shaft cylinder (5-1), a central shaft rod (5-2) and a central shaft sucker (5-3), the central shaft cylinder (5-1) is fixedly connected to the rotating plate (1-6), the central shaft rod (5-2) is fixedly connected to a cylinder rod of the central shaft cylinder (5-1), and the central shaft sucker (5-3) is fixedly connected to the central shaft rod (5-2).

7. A ceramic processing system as claimed in claim 6, wherein: the driving assembly (6) comprises a cross (6-1), lifting chutes (6-2), an internal thread rotating cylinder (6-3) and an adjusting frame (6-4), wherein the lifting chutes (6-2) are uniformly distributed on the cross (6-1), the internal thread rotating cylinder (6-3) is rotatably connected to the middle of the cross (6-1), the adjusting frame (6-4) is fixedly connected to the middle of the internal thread rotating cylinder (6-3), and the internal thread rotating cylinder (6-3) is in threaded connection with a threaded pipe (1-8).

8. A ceramic processing system as claimed in claim 7, wherein: the clamping jaw assembly (7) comprises clamping jaws (7-1), adjusting grooves (7-2), rotating grooves (7-3), adjusting rods (7-4) and fixed shaft rods (7-5), the adjusting grooves (7-2) and the rotating grooves (7-3) are formed in the clamping jaws (7-1), the upper ends of the adjusting rods (7-4) are rotatably connected into the adjusting grooves (7-2), the upper ends of the fixed shaft rods (7-5) are rotatably connected into the rotating grooves (7-3), the lower ends of the adjusting rods (7-4) are respectively connected into the lifting sliding grooves (6-2) in a sliding mode, and the fixed shaft rods (7-5) are fixedly connected onto the mounting plate (1-7).

9. A ceramic processing system as claimed in claim 8, wherein: the middle shaft rod (5-2) is connected in the internal thread rotary drum (6-3) in a sliding mode.

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