CN111645183A

CN111645183A - Ceramic grouting production line

Info

Publication number: CN111645183A
Application number: CN202010495994.4A
Authority: CN
Inventors: 许光权; 许文豪
Original assignee: Fujian Dehua Haopeng Machinery Co ltd
Current assignee: Fujian Dehua Haopeng Machinery Co ltd
Priority date: 2020-06-03
Filing date: 2020-06-03
Publication date: 2020-09-11

Abstract

The invention discloses a ceramic grouting production line, and particularly relates to the technical field of ceramic grouting. According to the invention, the traditional chain transmission is replaced by the contact transmission, so that the transmission process is more stable, the influence of generated vibration on the ceramic mould is smaller, the slurry pouring and turning processes of the ceramic mould are realized by the arranged first slurry turning windmill and the second slurry turning windmill, the ceramic mould is finally transferred from the first production line to the second production line, the contact transmission is carried out on the second production line again, and then the ceramic mould flows into the first production line again to realize the circular work.

Description

Ceramic grouting production line

Technical Field

The invention relates to the technical field of ceramic grouting, in particular to a ceramic grouting production line.

Background

The slip casting is a method for casting the mud into the plaster mould to make it into the product, the products with complicated shapes such as vase, pot, teapot, sugar pot, milk level, and love are formed by multi-purpose slip casting, the slip casting method is simple, i.e. the mud made from blank is poured into the plaster mould, because the plaster chess has water absorption, the water content of the mud near the inner wall of the mould is sucked by the porous gypsum to form a mud layer with the same shape as the inner wall of the mould, the mud layer is thickened along with the increase of time, after a while, the surplus mud is poured, the mud layer near the inner wall of the mould is left in the mould, and after a while, the mud layer shrinks naturally and separates from the mould, and the formed rough blank can be taken out.

Through retrieval, the Chinese invention with the publication number of CN208557869U discloses a ceramic grouting production line, which comprises a frame and a conveying belt; the frame is provided with a bearing platform in an inverted acute angle triangle shape; the bearing table comprises an upper platform, a left inclined table and a right inclined table; the conveyer belt is arranged on the bearing table and is in transmission connection through a transmission shaft with a gear; one of the transmission shafts with the gears is in transmission connection with the motor; a grouting opening is arranged above the conveying belt; a plurality of uniformly distributed circular trays are arranged on the conveying belt; the center of the circular tray is rotatably connected with the conveying belt through a circular shaft; gear teeth are arranged on the outer edge of the circular tray; a first gear which can be in meshing transmission with the gear teeth is arranged beside the grouting port of the upper platform; the first gear is in transmission connection with the second motor; a plurality of gears II which are meshed and driven along the length direction of the right sloping table are arranged beside the right sloping table; the gear II positioned at the uppermost edge is in transmission connection with the motor III; the second gear can be in meshing transmission with the gear teeth; the technology can effectively eliminate bubbles, the surface of the prepared product is smooth, and the production efficiency and the product quality are effectively improved.

However, in the actual use of the ceramic die, the chain type transmission is adopted, the vibration generated in the transmission process is large, the ceramic die is easily affected, and the continuous circular processing cannot be realized.

Disclosure of Invention

In order to overcome the above defects in the prior art, embodiments of the present invention provide a ceramic grouting production line, in which a conventional chain transmission is replaced by a contact transmission, the transmission process is more stable, the influence of generated vibration on a ceramic mold is less, and the ceramic mold is circulated to solve the above problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: a ceramic grouting production line comprises a first production line, wherein a first vertical concave guide rail is arranged at the top of the first production line, a plurality of movable frames are connected above the first vertical concave guide rail, a ceramic mold is installed above the movable frames, the top end of each movable frame is positioned on the outer side of the ceramic mold and is connected with a buckle pressing piece, a grouting section is installed on the outer side of the starting end of the first production line, a lifting plate is arranged on the outer side of the end part of the first production line, the bottom end of the lifting plate is connected with a lifting cylinder, a first telescopic cylinder is installed on one horizontal side of the first production line, a first slurry-turning windmill is installed on one side, far away from the first telescopic cylinder, of the outer side of one end of the first production line, a second slurry-turning windmill is installed on the inner side of the bottom of the first slurry-turning windmill, and a third telescopic cylinder is installed on the outer side of the bottom, a second telescopic cylinder is arranged on the outer side of the middle part of the first slurry turning windmill, close to the outer side of the top of the second slurry turning windmill, a second assembly line is arranged at the position, right below the first assembly line, of one side of the second slurry turning windmill, a second longitudinal concave guide rail is arranged at the top of the second assembly line, and an operation box is arranged on the outer side of the first assembly line;

the first slurry turning windmill is of a cross structure consisting of four first slurry turning frames, the end part of each first slurry turning frame is provided with a third longitudinal concave guide rail, the second slurry turning windmill is of a cross structure consisting of four second slurry turning frames, and the end part of each second slurry turning frame is provided with a fourth longitudinal concave guide rail;

the movable frame comprises a placing plate connected to the bottom of the ceramic die, the bottom of the placing plate is connected with a fixing frame, the bottom end of the buckle pressing piece is fixedly connected to the edge of the top end of the fixing frame, the bottom end of the fixing frame is connected with a fixing column, two sides of the bottom of the fixing column are both provided with idler wheels, two outer side walls of the fixing column are both fixedly connected with hollow columns, the inner sides of the hollow columns are connected with telescopic rods, and one end of each telescopic rod is connected with a baffle;

the buckle compresses tightly a fixed column including connecting on the mount top, the external connection of fixed column has first movable block, the outer wall of first movable block is located the top of mount and rotates and is connected with the clamp plate, the outside of fixed column is located the top position department of first movable block and is connected with the second movable block, the outer wall of second movable block is located the top of clamp plate and is connected with the dead lever, the end connection of dead lever has cylinder spring, through fixed axle swing joint between cylinder spring's the top and the outer wall of dead lever, the bottom position department that the top of clamp plate corresponds cylinder spring is provided with movable clamping groove on the horizontal direction.

In a preferred embodiment, the outer walls of the middle parts of the first and second paddle-turning windmills are respectively provided with a servo motor, and the servo motors are supported and fixed by an outer frame body.

In a preferred embodiment, the lifting cylinder, the first telescopic cylinder, the second telescopic cylinder and the third telescopic cylinder are connected with mounting frames outside, and the mounting frames are fixedly mounted on the placing surface.

In a preferred embodiment, the vertical cross-sectional structures of the first, second, third and fourth longitudinal concave rails are the same size.

In a preferred embodiment, a fifth longitudinal concave guide rail is arranged at the top of the movable plate corresponding to one side position of the first longitudinal concave guide rail and the second longitudinal concave guide rail, and the output end of the lifting cylinder is fixedly connected to the bottom of the lifting plate.

In a preferred embodiment, the outer wall of the end part of the hollow column, which is close to the outer side of the telescopic rod, is connected with a fastening bolt, the baffle and the telescopic rod are connected in a welding manner, and the outer surface of the telescopic rod is provided with scale marks.

In a preferred embodiment, the inside of the first movable block and the second movable block is provided with a through hole corresponding to the outside of the fixed column, the inner diameter of the cross section of the through hole is larger than the outer diameter of the cross section of the fixed column, the outer walls of the first movable block and the second movable block are connected with adjusting bolts, and the inside of the first movable block and the inside of the second movable block are communicated with the through hole corresponding to screw holes where the adjusting bolts are located.

In a preferred embodiment, the length of the first flow line is greater than the length of the second flow line, and the second flow line is installed inside a support frame body of the first flow line.

The invention has the technical effects and advantages that: compared with the prior art, the technology adopts the buckle pressing pieces of two implementation modes to realize the fixing treatment of the ceramic mould, simultaneously, the work of the whole production line adopts an air cylinder pushing type, the outer walls of the bottoms of any two movable frames are provided with telescopic rods, the distance between the two ceramic moulds can be conveniently adjusted according to the ceramic moulds of different specifications, the fixed columns at the bottoms of the movable frames are inserted into the guide rails, and the rollers roll in the guide rails, the movable frames for mounting the ceramic moulds replace the traditional chain type transmission through the contact type transmission, the transmission process is more stable, the influence of the generated vibration on the ceramic moulds is smaller, the ceramic moulds continue to adopt the contact type transmission after the grouting section finishes the grouting, the grout pouring and the grout turning process of the ceramic moulds are realized through the arranged first grout turning windmill and the second grout turning windmill, and finally the ceramic moulds are transferred from the first production line to the second production line, and the second assembly line is subjected to the abutting transmission again, and then the second assembly line flows into the first assembly line again to realize the circular work.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of a first pinwheel of the present invention.

Fig. 3 is a schematic structural view of a second pinwheel of the present invention.

Fig. 4 is a schematic view showing the structure of a clip presser in embodiment 1 of the present invention.

Fig. 5 is a schematic view showing the structure of a clip presser in embodiment 2 of the present invention.

Fig. 6 is a schematic structural view of the movable frame of the present invention.

Fig. 7 is a schematic structural view of the lifting plate of the present invention.

The reference signs are: 1 a first production line, 2 a first longitudinal concave guide rail, 3 a movable frame, 4 ceramic molds, 5 buckle pressing pieces, 6 grouting sections, 7 lifting plates, 8 lifting cylinders, 9 first telescopic cylinders, 10 first grout turning windmills, 11 second grout turning windmills, 12 operation boxes, 13 second telescopic cylinders, 131 third telescopic cylinders, 14 second production lines, 15 second longitudinal concave guide rails, 101 first grout turning frames, 102 third longitudinal concave guide rails, 111 second grout turning frames and 112 fourth longitudinal concave guide rails, 301 placing plate, 302 fixing frame, 303 fixing column, 304 idler wheel, 305 hollow column, 306 telescopic rod, 307 baffle, 51 fixing column, 52 first movable block, 53 pressing plate, 54 second movable block, 55 fixing rod, 56 cylinder spring, 57 fixing shaft, 58 movable clamping groove, 501 first fixing barrel, 502 first telescopic inner barrel, 503 turning frame, 504 second fixing barrel and 505 second telescopic inner barrel.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1:

the ceramic grouting production line shown in the attached figures 1-4 and 6-7 comprises a first production line 1, wherein a first longitudinal concave guide rail 2 is arranged at the top of the first production line 1, a plurality of movable frames 3 are connected above the first longitudinal concave guide rail 2, a ceramic mold 4 is installed above the movable frames 3, the top end of each movable frame 3 is positioned at the outer side of the ceramic mold 4 and is connected with a buckle pressing piece 5, a grouting section 6 is installed at the outer side of the starting end of the first production line 1, a lifting plate 7 is arranged at the outer side of the end part of the first production line 1, the bottom end of the lifting plate 7 is connected with a lifting cylinder 8, a first telescopic cylinder 9 is installed at one side of the horizontal side of the first production line 1, a first grout turning windmill 10 is installed at one side of the first telescopic cylinder 9 far away from the outer side of one end of the first production line 1, a second slurry turning windmill 11 is arranged on the inner side of the bottom of the first slurry turning windmill 10, a third telescopic cylinder 131 is arranged on the outer side of the bottom of the first slurry turning windmill 10, a second telescopic cylinder 13 is arranged on the outer side of the middle of the first slurry turning windmill 10, which is close to the outer side of the top of the second slurry turning windmill 11, a second assembly line 14 is arranged at a position right below the first assembly line 1 on one side of the second slurry turning windmill 11, a second longitudinal concave guide rail 15 is arranged on the top of the second assembly line 14, and an operation box 12 is arranged on the outer side of the first assembly line 1;

the first slurry turning windmill 10 is of a cross structure integrally formed by four first slurry turning frames 101, a third longitudinal concave guide rail 102 is arranged at the end part of each first slurry turning frame 101, the second slurry turning windmill 11 is of a cross structure integrally formed by four second slurry turning frames 111, and a fourth longitudinal concave guide rail 112 is arranged at the end part of each second slurry turning frame 111;

the movable frame 3 comprises a placing plate 301 connected to the bottom of the ceramic mold 4, the bottom of the placing plate 301 is connected with a fixed frame 302, the bottom end of the buckle pressing piece 5 is fixedly connected to the edge of the top end of the fixed frame 302, the bottom end of the fixed frame 302 is connected with a fixed column 303, two sides of the bottom of the fixed column 303 are both provided with rollers 304, two outer side walls of the fixed column 303 are both fixedly connected with hollow columns 305, the inner sides of the hollow columns 305 are connected with telescopic rods 306, and one ends of the telescopic rods 306 are connected with baffle plates 307;

the buckle pressing piece 5 comprises a fixed column 51 connected to the top end of the fixed frame 302, a first movable block 52 is connected to the outside of the fixed column 51, a pressing plate 53 is rotatably connected to the outer wall of the first movable block 52 above the fixed frame 302, a second movable block 54 is connected to the outside of the fixed column 51 above the first movable block 52, a fixed rod 55 is connected to the outer wall of the second movable block 54 above the pressing plate 53, an air cylinder spring 56 is connected to the end of the fixed rod 55, the top of the air cylinder spring 56 is movably connected with the outer wall of the fixed rod 55 through a fixed shaft 57, and a movable clamping groove 58 is horizontally arranged at the position, corresponding to the bottom end of the air cylinder spring 56, of the top of the pressing plate 53.

Furthermore, servo motors are arranged on the outer walls of the middle parts of the first and second paddle-turning

windmills

10 and 11, and are supported and fixed by an external frame body, so that the first and second paddle-turning

windmills

10 and 11 can stably rotate;

further, mounting frames are connected to the outsides of the lifting cylinder 8, the first telescopic cylinder 9, the second telescopic cylinder 13 and the third telescopic cylinder 131, and the mounting frames are fixedly mounted on a placing surface, so that the lifting cylinder 8, the first telescopic cylinder 9, the second telescopic cylinder 13 and the third telescopic cylinder 131 can be conveniently mounted and fixed;

furthermore, the vertical cross-sectional structures of the first longitudinal concave guide rail 2, the second longitudinal concave guide rail 15, the third longitudinal concave guide rail 102 and the fourth longitudinal concave guide rail 112 are the same in size, so that the movable frame 3 can drive the ceramic mold 4 to move on the first production line 1 and the second production line 14 in the use process;

furthermore, a fifth longitudinal concave guide rail 71 is arranged at a position, corresponding to one side of the first longitudinal concave guide rail 2 and the second longitudinal concave guide rail 15, on the top of the movable plate 7, and an output end of the lifting cylinder 8 is fixedly connected to the bottom of the lifting plate 7, so that in the using process, after the movable frame 3 is moved above the lifting plate 7, the movable plate 7 is driven to be lifted to one side of the first assembly line 1 through the lifting cylinder 8, and then the movable frame 3 on the lifting plate 17 is pushed onto the first longitudinal concave guide rail 2 at the top of the first assembly line 1 through the first telescopic cylinder 9;

furthermore, the outer wall of the end portion of the hollow column 305, which is close to the outer side of the telescopic rod 306, is connected with a fastening bolt, the baffle 307 and the telescopic rod 306 are connected in a welding manner, and the outer surface of the telescopic rod 306 is provided with scale marks, so that the telescopic rod 306 can stably extend and retract inside the hollow column 305, and the extension length of the telescopic rod 306 can be conveniently controlled;

furthermore, through holes are formed in the first movable block 52 and the second movable block 54 corresponding to the outer portions of the fixed columns 51, the inner diameter of the cross section of each through hole is larger than the outer diameter of the cross section of each fixed column 51, adjusting bolts are connected to the outer walls of the first movable block 52 and the second movable block 54, and screw holes in the first movable block 52 and the second movable block 54 corresponding to the screw rods of the adjusting bolts are communicated with the through holes, so that the fixing positions of the first movable block 52 and the second movable block 54 can be adjusted conveniently;

further, the length of the first production line 1 is greater than that of the second production line 14, and the second production line 14 is installed inside a support frame body of the first production line 1;

furthermore, the telescopic cylinder structure related in the invention can be replaced by a hydraulic cylinder, an electric telescopic transmission mechanism or other structural schemes with telescopic properties when in specific use.

Example 2:

as shown in fig. 1-2 and fig. 5-7, compared with embodiment 1, the fastening pressing member 5 adopted in this embodiment is composed of a first fixed cylinder 501, a first telescopic inner cylinder 502, a roll-over stand 503, a second fixed cylinder 504 and a second telescopic inner cylinder 505, the bottom end of the first fixed cylinder 501 is fixedly connected to the top end of the fixed frame 302, the inner side of the top of the first fixed cylinder 501 is connected to the first telescopic inner cylinder 502 through an adjusting bolt, the outer wall of the top of the first telescopic inner cylinder 502 is movably connected to the roll-over stand 503 above the fixed frame 302, one side of the lower end of the roll-over stand 503, which is far away from the first fixed cylinder 501, is connected to the second fixed cylinder 504, and the inner side of the bottom of the second fixed cylinder 504 is connected to the second telescopic inner cylinder 505 through an adjusting bolt.

The working principle of the invention is as follows:

referring to fig. 1-7 of the specification, in the present technology, two embodiments of the fastening pressing piece 5 are used to fix the ceramic mold 4 on the movable frame 3, in example 1, after the fixing positions of the first movable block 52 and the second movable block 54 are adjusted, the pressing plate 53 is attached to the ceramic mold 4, and the pressing effect is realized at the position of the movable clamping groove 58 through the bottom of the cylinder spring 56, when the cylinder spring 56 is vertically placed, the pressing effect is realized, and when the cylinder spring 56 is in an inclined state, the cylinder spring is also in a loose state; in embodiment 2, the extension length of the first telescopic inner cylinder 502 is adjusted according to the size of the ceramic mold 4 until the roll-over stand 503 can be attached to the top of the ceramic mold 4, and then the second telescopic inner cylinder 505 at the other end is pulled out downwards to contact the top of the fixed frame 302 and then screwed and fixed, so that the ceramic mold 4 can be fixed; furthermore, the whole production line works in an air cylinder pushing mode, the outer walls of the bottoms of any two movable frames 3 are provided with telescopic rods 306, the distance between the two ceramic molds 4 can be conveniently adjusted according to the ceramic molds 4 with different specifications, the fixed columns 303 at the bottoms of the movable frames 3 are inserted into the guide rails, and the rollers 304 roll in the guide rails, in the using process, the first telescopic air cylinders 9 are started to push the movable frames 3 to move at the tops of the first longitudinal concave guide rails 2, the movable frames 3 on the first longitudinal concave guide rails 2 are in contact transmission, namely the ceramic molds 4 are driven to carry out transmission, compared with the traditional chain transmission, the ceramic molds are more stable, the influence of the generated vibration on the ceramic molds 4 is smaller, the ceramic molds 4 continue to adopt contact transmission after the grouting section 6 finishes grouting, and the movable frame 3 at the forefront moves to the third longitudinal concave guide rail 102 at the top of the first grouting windmill 10, after the first mortar-turning windmill 10 finishes pouring and overturning mortar through 180-degree rotation of the servo motor, the third longitudinal concave guide rail 102 provided with the movable frame 3 and the fourth longitudinal concave guide rail 112 at the bottom of the second mortar-turning windmill 11 are in the same opening direction at the same height, at the same time, the movable frame 3 is pushed to the fourth longitudinal concave guide rail 112 from the third longitudinal concave guide rail 102 through the third telescopic cylinder 131 to realize the transfer of the ceramic mold 4 on the movable frame 3, wherein when the first mortar-turning windmill 10 rotates by 90 degrees, the ceramic movable frame 3 on the upper first production line 1 is pushed to the third longitudinal concave guide rail 102 at the top again, so that the working efficiency is improved in the use process, and then the servo motor controls the second mortar-turning windmill 11 to rotate by 180 degrees (similarly, when rotating by 90 degrees, the first mortar-turning windmill 10 is butted again to ensure that the movable frame 3 is transferred to improve the efficiency), so that the fourth longitudinal concave guide rail 112 provided with the movable frame 3 and the second longitudinal concave guide rail 15 on the second production line 14 In the same opening direction on same height, start second telescopic cylinder 13 at this moment and push away adjustable shelf 3 to the second on the second assembly line 14 on the vertical concave guide rail 15 of second, realize that ceramic mould 4 shifts from first assembly line 1 to on the second assembly line 14, and carry out the contact type transmission again on the second assembly line 14, after transmission to the fifth vertical concave guide rail on fly leaf 7 on, start lift cylinder 8 with lifter plate 7 rise to with the same height of the first on the first assembly line 1 on the first vertical concave guide rail 2, start first telescopic cylinder 9 at this moment and push away adjustable shelf 3 to on the first vertical concave guide rail 2 at first assembly line 1 top, realize circulation work, after adjustable shelf 3 moved to first assembly line 1, lift cylinder 8 drives lifter plate 7 to descend and carry out next circulation.

And finally: the above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that are within the spirit and principle of the present invention are intended to be included in the scope of the present invention.

Claims

1. The utility model provides a pottery slip casting production line, includes first assembly line (1), its characterized in that: the top of the first assembly line (1) is provided with a first longitudinal concave guide rail (2), a plurality of movable frames (3) are connected above the first longitudinal concave guide rail (2), a ceramic mold (4) is installed above the movable frames (3), the top end of each movable frame (3) is located on the outer side of the ceramic mold (4) and is connected with a buckle pressing piece (5), a grouting section (6) is installed on the outer side of the starting end of the first assembly line (1), a lifting plate (7) is arranged on the outer side of the end part of the first assembly line (1), the bottom end of the lifting plate (7) is connected with a lifting cylinder (8), a first telescopic cylinder (9) is installed on one side, located on the lifting plate (7), of the horizontal side of the first assembly line (1), and a first slurry turning windmill (10) is installed on one side, located on the side, far away from the first telescopic cylinder (9), of the outer side of one end of, a second slurry turning windmill (11) is arranged on the inner side of the bottom of the first slurry turning windmill (10), a third telescopic cylinder (131) is arranged on the outer side of the bottom of the first slurry turning windmill (10), a second telescopic cylinder (13) is arranged on the outer side of the middle of the first slurry turning windmill (10) close to the outer side of the top of the second slurry turning windmill (11), a second assembly line (14) is arranged on one side of the second slurry turning windmill (11) and is positioned right below the first assembly line (1), a second longitudinal concave guide rail (15) is arranged on the top of the second assembly line (14), and an operation box (12) is arranged on the outer side of the first assembly line (1);

the first slurry turning windmill (10) is of a cross structure integrally formed by four first slurry turning frames (101), a third longitudinal concave guide rail (102) is arranged at the end part of each first slurry turning frame (101), the second slurry turning windmill (11) is of a cross structure integrally formed by four second slurry turning frames (111), and a fourth longitudinal concave guide rail (112) is arranged at the end part of each second slurry turning frame (111);

the movable frame (3) comprises a placing plate (301) connected to the bottom of the ceramic mold (4), the bottom of the placing plate (301) is connected with a fixed frame (302), the bottom end of the buckle pressing piece (5) is fixedly connected to the edge of the top end of the fixed frame (302), the bottom end of the fixed frame (302) is connected with a fixed column (303), rollers (304) are mounted on two sides of the bottom of the fixed column (303), two outer side walls of the fixed column (303) are fixedly connected with hollow columns (305), the inner sides of the hollow columns (305) are connected with telescopic rods (306), and one end of each telescopic rod (306) is connected with a baffle (307);

the buckle pressing piece (5) comprises a fixing column (51) connected to the top end of the fixing frame (302), a first movable block (52) is connected outside the fixed column (51), the outer wall of the first movable block (52) is positioned above the fixed frame (302) and is rotatably connected with a pressure plate (53), a second movable block (54) is connected to the position, above the first movable block (52), outside the fixed column (51), the outer wall of the second movable block (54) is positioned above the pressure plate (53) and is connected with a fixed rod (55), the end part of the fixed rod (55) is connected with an air cylinder spring (56), the top of the air cylinder spring (56) is movably connected with the outer wall of the fixed rod (55) through a fixed shaft (57), the top of the pressure plate (53) is provided with a movable clamping groove (58) along the horizontal direction corresponding to the bottom end position of the cylinder spring (56).

2. The ceramic slip casting production line of claim 1, characterized in that: and servo motors are arranged on the outer walls of the middle parts of the first slurry turning windmill (10) and the second slurry turning windmill (11) and are supported and fixed by an external frame body.

3. The ceramic slip casting production line of claim 1, characterized in that: the outside of lift cylinder (8), first telescopic cylinder (9), second telescopic cylinder (13) and third telescopic cylinder (131) all is connected with the mounting bracket, and mounting bracket fixed mounting is on placing the face.

4. The ceramic slip casting production line of claim 1, characterized in that: the vertical cross-section structures of the first longitudinal concave guide rail (2), the second longitudinal concave guide rail (15), the third longitudinal concave guide rail (102) and the fourth longitudinal concave guide rail (112) are the same in size.

5. The ceramic slip casting production line of claim 1, characterized in that: a fifth longitudinal concave guide rail (71) is arranged at one side position of the top of the movable plate (7) corresponding to the first longitudinal concave guide rail (2) and the second longitudinal concave guide rail (15), and the output end of the lifting cylinder (8) is fixedly connected to the bottom of the lifting plate (7).

6. The ceramic slip casting production line of claim 1, characterized in that: the outer side of the outer wall of the end part of the hollow column (305), which is close to the telescopic rod (306), is connected with a fastening bolt, the baffle (307) and the telescopic rod (306) are connected in a welding mode, and the outer surface of the telescopic rod (306) is provided with scale marks.

7. The ceramic slip casting production line of claim 1, characterized in that: the inside of first movable block (52) and second movable block (54) corresponds the outside of fixed column (51) and all is provided with the through-hole, and the cross section internal diameter of through-hole is greater than the cross section external diameter of fixed column (51), the outer wall of first movable block (52) and second movable block (54) all is connected with adjusting bolt, and the inside screw and the through-hole intercommunication that correspond adjusting bolt's screw rod place of first movable block (52) and second movable block (54).

8. The ceramic slip casting production line of claim 1, characterized in that: the length of first assembly line (1) is greater than the length of second assembly line (14), second assembly line (14) are installed at the support body inboard of first assembly line (1).