CN217414403U - Automatic ceramic production equipment - Google Patents

Abstract

An automatic ceramic production device comprises a feeding device, a stirring device, a mold conveying device drying device, a roll forming device I, a roll forming device II and a control system, wherein the mold conveying device comprises a support frame, an annular conveying chain I and an annular conveying chain II which are arranged on the support frame in parallel, a plurality of mold brackets I and mold brackets II used for placing molds are respectively arranged on the annular conveying chain I and the annular conveying chain II, and an exchange assembly for exchanging the molds on the mold brackets I and the molds on the mold brackets II is arranged on the support frame; wherein the drying device is arranged on the support frame; the roll forming device I and the roll forming device II are located at one end of the supporting frame and are respectively arranged corresponding to the annular conveying chain II and the annular conveying chain I, and the roll forming device I and the roll forming device II are two roll forming devices for rolling different types of pottery.

Description

Automatic ceramic production equipment

Technical Field

The utility model relates to a pottery automatic production technical field especially relates to a pottery automatic production equipment.

Background

The whole process from raw material feeding to finished product output in the production process of porcelain utensils by the existing porcelain utensil production enterprises depends on manual allocation operation, so that the manual operation is time-consuming and labor-consuming, the production efficiency is low, the labor cost is high, and the working procedures are complicated; and the whole pottery production line occupies too long ground, and a specific factory building needs to be built for placing the production line.

In addition, the existing ceramic production equipment can only produce the same kind of ceramics in the production process, and can not produce different types of ceramics simultaneously, therefore, when different types of ceramics need to be produced simultaneously, only one type of ceramics can be produced before another type of ceramics is produced, which is time-consuming and labor-consuming, and after one type of ceramics is produced, the equipment needs to be debugged to produce other types of ceramics.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that an automatic ceramic production device is provided.

In order to solve the technical problem, the utility model adopts the following technical scheme:

an automatic ceramic production device comprises a feeding device, a stirring device, a mold conveying device drying device, a roll forming device I, a roll forming device II and a control system, wherein the mold conveying device comprises a support frame, an annular conveying chain I and an annular conveying chain II which are arranged on the support frame in parallel, a plurality of mold brackets I and mold brackets II used for placing molds are respectively arranged on the annular conveying chain I and the annular conveying chain II, and an exchange assembly for exchanging the molds on the mold brackets I and the molds on the mold brackets II is arranged on the support frame; wherein the drying device is arranged on the support frame; the roll forming device I and the roll forming device II are located at one end of the supporting frame and are respectively arranged corresponding to the annular conveying chain II and the annular conveying chain I, and the roll forming device I and the roll forming device II are two roll forming devices for rolling different types of pottery.

In one embodiment, the number of the stirring devices is two, the two stirring devices are positioned on one side of the annular conveying chain I or one side of the annular conveying chain II, and discharge ports of the two stirring devices are provided with a cutting assembly and a taking and placing assembly; the number of the feeding devices is two, and the two feeding devices are respectively positioned on one side of the two stirring devices and used for conveying the ceramic columns for the two stirring devices.

In one embodiment, the interchange assembly comprises a bracket and a fixing plate fixedly arranged at the top of the bracket, wherein a through hole is formed in the middle of the fixing plate, a motor fixing plate is arranged above the through hole, a connecting plate is arranged below the through hole, and the motor fixing plate and the connecting plate are both fixedly connected with the fixing plate through a connecting column.

In one embodiment, a rotating motor is arranged on the motor fixing plate, and an output shaft of the rotating motor sequentially penetrates through the motor fixing plate, the through hole and the connecting plate to be fixedly connected with the grabbing piece.

In an embodiment, snatch the piece including snatching the fixed plate, snatch the fixed plate with the opposite one side of rotation motor output shaft is provided with two-way telescopic cylinder I, two-way telescopic cylinder II, two-way telescopic cylinder III, two-way telescopic cylinder IV, wherein, two-way telescopic cylinder I with II parallel arrangement of two-way telescopic cylinder, two-way telescopic cylinder III with IV parallel arrangement of two-way telescopic cylinder, just two-way telescopic cylinder I with II with two-way telescopic cylinder III with IV symmetrical arrangement of two-way telescopic cylinder.

In one embodiment, output shafts at two ends of the bidirectional telescopic cylinder I, the bidirectional telescopic cylinder II, the bidirectional telescopic cylinder III and the bidirectional telescopic cylinder IV are respectively and fixedly provided with a fixing block I and a fixing block II, and the bottom ends of the fixing block I and the fixing block II are fixedly connected with a symmetrical connecting block I and a symmetrical connecting block II.

In one embodiment, the bottom of connecting block I with connecting block II is connected with vertical connecting block I and vertical connecting block II respectively, vertical connecting block I with the symmetrical one side in II bottom of vertical connecting block all is fixed and is provided with C shape clamp splice.

In one embodiment, the interchange assembly further comprises a lifting mechanism arranged on the support frame and located below the support frame, wherein the lifting mechanism comprises a bidirectional screw rod, a bearing seat I and a bearing seat II which are rotatably connected with two ends of the bidirectional screw rod, a screw rod sliding block I and a screw rod sliding block II which are arranged on the bidirectional screw rod, and a motor driving the bidirectional screw rod to be rotatably connected.

In an embodiment, a connecting rod I and a connecting rod II are hinged to the screw rod sliding block I and the screw rod sliding block II respectively, one end of the screw rod sliding block I is far away from the connecting rod I, one end of the screw rod sliding block II is far away from the connecting rod II, a supporting plate is fixedly arranged at the top of the hinged position of the connecting rod I and the connecting rod II, a stand column is fixedly arranged at the four corners of the opposite side of the bidirectional screw rod, and a tray is fixedly arranged at the top end of the stand column.

The utility model has the advantages as follows:

1. the utility model discloses a ceramic manufacture equipment can only produce the same kind pottery among the prior art in process of production in loading attachment, agitating unit, mould conveyor drying device, roll forming device I, roll forming device II and control system's setting can be solved, can not produce the pottery of different grade type simultaneously, and manual operation is wasted time and energy, and production efficiency is low, and the human cost is high, the loaded down with trivial details technical problem of process.

2. The utility model discloses a be provided with parallel annular conveying chain I and annular conveying chain II on the support frame, and be provided with a plurality of mould bracket I and mould bracket II that are used for placing the mould on annular conveying chain I and annular conveying chain II respectively, solved current ceramic manufacture line overlength from this, occupation space is big, and need build the technical problem of specific factory building.

Drawings

Fig. 1 is a schematic view of the overall structure of embodiment 1 of the present invention.

Fig. 2 is a schematic structural view of the mold conveying apparatus shown in fig. 1 according to the present invention.

Fig. 3 is a front view of the mold conveying device shown in fig. 1 according to the present invention.

Fig. 4 is a schematic structural view of the lifting mechanism of fig. 1 according to the present invention.

Fig. 5 is a schematic front view of the lifting mechanism of fig. 1 according to the present invention.

Fig. 6 is a left side perspective view of the interchange assembly of fig. 1 according to the present invention.

Fig. 7 is a right side perspective view of the interchange assembly of fig. 1 according to the present invention.

Fig. 8 is a schematic structural view of the stirring device shown in fig. 1 according to the present invention.

In the figure: 100. a feeding device, 200, a stirring device, 300, a die conveying device, 310, a support frame, 311, an annular conveying chain I, 312, an annular conveying chain II, 313, a die bracket I, 314, a die bracket II, 340, a vertical connecting block II, 341, a C-shaped clamping block, 350, an interchange assembly, 351, a support, 352, a fixing plate, 354, a motor fixing plate, 355, a connecting plate, 356, a connecting column, 357, a rotating motor, 360, a grabbing fixing plate, 361, a bidirectional telescopic cylinder I, 362, a bidirectional telescopic cylinder II, 3623, a bidirectional telescopic cylinder III, 364, a bidirectional telescopic cylinder IV, 365, a fixing block I, 366, a fixing block II, 367, a connecting block I, 368, a connecting block II, 369, a vertical connecting block I, 370, a bidirectional screw rod, 371, a bearing block I, 372, a bearing block II, 373, a screw rod sliding block I, 374, a screw rod sliding block II, 375, a motor, 376. connecting rods I and 377, connecting rods II and 378, a supporting plate 379 and a stand column. 380. The tray, 400, drying device, 450, roll forming device I, 500, roll forming device II.

Detailed Description

The present invention will be further explained with reference to the drawings and examples.

As shown in fig. 1, the present embodiment includes a feeding device 100, a stirring device 200, a mold conveying device 300, a drying device 400, a roll forming device i 450, a roll forming device ii 500, and a control system, where the control system is electrically connected to the feeding device 100, the stirring device 200, the mold conveying device 300, the drying device 400, the roll forming device i 450, and the roll forming device ii 500, and is used to control the operations of the feeding device 100, the stirring device 200, the mold conveying device 300, the drying device 400, the roll forming device i 450, and the roll forming device ii 500, so that the whole production equipment can automatically operate, and each processing procedure is reasonably linked.

The structure and mechanism of action of the main components of the present invention are further described below.

Mold conveying device

As shown in fig. 2-3, the mold conveying device 300 includes a supporting frame 310, an annular conveying chain i 311 and an annular conveying chain ii 312 which are arranged in parallel on the supporting frame 310, wherein a plurality of mold brackets i 313 and mold brackets ii 314 for placing molds are respectively arranged on the annular conveying chain i 311 and the annular conveying chain ii 312, and specifically, the mold brackets i 313 and the mold brackets ii 314 are both annular brackets.

The supporting frame 310 is provided with an interchanging component 350 for interchanging the die on the die bracket I313 and the die on the die bracket II 314; the interchanging module 350 comprises a bracket 351, a fixing plate 352 fixedly arranged at the top of the bracket 351, and a lifting mechanism arranged on the supporting frame 310 and positioned below the bracket 351; specifically, the support 351 is located at one end of the annular conveying chain I311 and one end of the annular conveying chain II 312, and more specifically, the support 351 is located above the middle part of the annular conveying chain I311 to the middle part of the annular conveying chain II 312, so that the mold brackets I313 and the mold brackets II 314 on the annular conveying chain I311 and the annular conveying chain II 312 can pass below the supporting frame 310.

As shown in fig. 3, the lifting mechanism is disposed at the bottom of the supporting frame 310; as shown in fig. 4-5, the lifting mechanism includes a bidirectional screw 370, bearing seats i 371 and ii 372 rotatably connected to two ends of the bidirectional screw 370, screw sliders i 373 and ii 374 disposed on the bidirectional screw 370, and a motor 375 for driving the bidirectional screw to rotatably connect, further, connecting rods i 376 and ii 377 are respectively hinged to the screw sliders i 373 and ii 374, wherein one end of the connecting rod i 376 far away from the screw slider i 373 is hinged to one end of the connecting rod ii 377 far away from the screw slider ii 374, a support plate 378 is fixedly disposed on the top of the hinged portion of the connecting rod i 376 and ii 377, upright posts 379 are fixedly disposed at four corners of the support plate 378 opposite to the bidirectional screw 370, a tray 380 is fixedly disposed on the top of the upright posts 379, and four upright posts 379 at four corners of the support plate are respectively connected to two mold brackets i 313, ii 378 on the annular conveying chain i 311, Two mould brackets II 314 on annular conveying chain II 312 are corresponding, from this, through the operation of motor 375, can drive lead screw slider I373 and lead screw slider II 374 and fold each other for backup pad 378 rises, makes four trays 380 on four stands 379 mould in two mould brackets I313 on annular conveying chain I311 and two mould brackets II 314 on annular conveying chain II 312 in mould all jack-up and break away from two mould brackets I313 and two mould brackets II 314 simultaneously.

As shown in fig. 6-7, a through hole is formed in the middle of the fixing plate 352, a motor fixing plate 354 is disposed above the through hole, a connecting plate 355 is disposed below the through hole, the fixing plate 354 and the connecting plate 355 are both fixedly connected to the fixing plate 352 through a connecting post 356, further, a rotating motor 357 is disposed on the motor fixing plate 354, and an output shaft of the rotating motor 357 sequentially passes through the motor fixing plate 354, the through hole 353 and the connecting plate to be fixedly connected to a grasping member.

The grabbing part comprises a grabbing fixing plate 360, one surface of the grabbing fixing plate 360, which is opposite to the output shaft of the rotating motor 357, is provided with a bidirectional telescopic cylinder I361, a bidirectional telescopic cylinder II 362, a bidirectional telescopic cylinder III 363 and a bidirectional telescopic cylinder IV 364, wherein the bidirectional telescopic cylinder I361 and the bidirectional telescopic cylinder II 362 are arranged in parallel and located at the left end of the grabbing fixing plate 360; the bidirectional telescopic cylinder III 363 and the bidirectional telescopic cylinder IV 364 are arranged in parallel and are positioned at the right end of the grabbing fixing plate 360; and the bidirectional telescopic cylinder I361 and the bidirectional telescopic cylinder II 362 are symmetrically arranged with the bidirectional telescopic cylinder III 363 and the bidirectional telescopic cylinder IV 364.

Output shafts at two ends of the bidirectional telescopic cylinder I361, the bidirectional telescopic cylinder II 362, the bidirectional telescopic cylinder III 363 and the bidirectional telescopic cylinder IV 364 are respectively and fixedly provided with a fixed block I365 and a fixed block II 366, and the bottom ends of the fixed block I365 and the fixed block II 366 are fixedly connected with a symmetrical connecting block I367 and a symmetrical connecting block II 368; the bottoms of the connecting block I367 and the connecting block II 368 are respectively connected with a vertical connecting block I369 and a vertical connecting block II 340, C-shaped clamping blocks 341 are fixedly arranged on symmetrical surfaces of the bottom ends of the vertical connecting block I369 and the vertical connecting block II 340,

therefore, after the molds in the two mold brackets I313 on the annular conveying chain I311 and the molds in the two mold brackets II 314 on the annular conveying chain II 312 are jacked up by the lifting mechanism and separated from the two mold brackets I313 and the two mold brackets II 314, the two-way telescopic cylinder I361, the two-way telescopic cylinder II 362, the two-way telescopic cylinder III 363 and the two-way telescopic cylinder IV 364 operate, so that the fixing blocks I365 and II 366 at two ends of the two-way telescopic cylinder I361, the two-way telescopic cylinder II 362, the two-way telescopic cylinder III 363 and the two-way telescopic cylinder IV 364 are folded, meanwhile, the connecting blocks I367 and II 368 and the vertical connecting blocks I369 and II 340 are also synchronously folded, and further, the molds in the two mold brackets I313 on the annular conveying chain I311 and the molds in the two mold brackets II 314 on the annular conveying chain II 312 are further clamped by the C-shaped clamping blocks 341 with symmetrical bottom ends of the vertical connecting blocks I369 and II 340 Then, through the rotation of the rotating motor 357, the molds in the two mold brackets i 313 on the annular conveying chain i 311 are exchanged with the molds in the two mold brackets ii 314 on the annular conveying chain ii 312, namely the two molds in the two mold brackets i 313 are exchanged with the two molds in the two mold brackets ii 314.

Stirring device

As shown in fig. 5, there are two stirring devices 200, two stirring devices 200 are located at one side of the circular conveying chain i 311 or the circular conveying chain ii 312, in this embodiment, two stirring devices 200 are located at one side of the circular conveying chain i 311, and two stirring devices 200 are supported by a stirring support, so that discharge ports of two stirring devices 200 are located at one side of the circular conveying chain i 311; further, the discharge ports of the two stirring devices 200 are provided with a cutting assembly and a taking and placing assembly;

as shown in fig. 6, the cutting assembly comprises a fixed plate fixedly arranged below the discharge port, a telescopic cylinder is arranged on the fixed plate, a U-shaped part is fixedly arranged on an output shaft of the telescopic cylinder, and a cutting knife is connected to an opening of the U-shaped part, so that the cutting knife is driven to move up and down through the telescopic cylinder, and the ceramic column at the conveying position of the discharge port is cut.

As shown in fig. 7, the taking and placing assembly comprises a taking and placing support frame which is arranged at one end of the stirring support and is positioned below the discharge port, wherein the end of the taking and placing support frame, which is far away from the stirring support, is provided with a taking and placing support, a taking and placing bearing seat is arranged on the taking and placing support, a rotating shaft is arranged on the taking and placing bearing seat, an oil cylinder fixing plate is fixed at one end of the rotating shaft, an oil cylinder is arranged on the oil cylinder fixing plate, and an output shaft of the oil cylinder is provided with a vacuum chuck; and one end of the rotating shaft, which is far away from the oil cylinder fixing plate, and the taking and placing support frame are provided with telescopic oil cylinders which drive the rotating shaft to rotate. From this, can make vacuum chuck hold the pottery post after will cutting through the flexible of hydro-cylinder, then through the flexible of flexible hydro-cylinder for the pottery post on the vacuum chuck is rotatory 90, then will hold the pottery post through vacuum chuck and place on the mould in I313 of mould bracket on I311 shape conveyor chain.

Feeding device

The number of the feeding devices 100 is two, the two feeding devices 100 are respectively positioned at one side of the two stirring devices 200 and used for conveying the ceramic columns for the two stirring devices 200; i.e. for transporting the mud column from bottom to top into the two stirring devices 200.

Roll forming device

The roll forming device comprises a roll forming device I450 and a roll forming device II 500, the roll forming device I450 and the roll forming device II 500 are located at one end of the support frame 310 and are respectively arranged corresponding to the annular conveying chain II 312 and the annular conveying chain I311, the roll forming device I450 and the roll forming device II 500 are two roll forming devices for rolling different types of pottery, therefore, the annular conveying chain I311 and the annular conveying chain II 312 can enable the mould bracket I313 and the mould bracket II 314 to rotate to the lower side of the roll forming device I450 and the roll forming device II 500, and the roll forming device I450 and the roll forming device II 500 can roll form pottery blocks in moulds on the mould bracket I313 and the mould bracket II 314.

Drying apparatus

The drying device 400 is arranged on the support frame 310; the drying device is used for drying the rolling and molding blank; specifically, drying device includes drying chamber, combustor and fan, and the drying chamber setting is at support frame 310, and is provided with tuber pipe and temperature controller in the drying chamber, and combustor, temperature controller and fan all are connected with control system: the combustor generates hot air by absorbing external air and mixing and combusting natural gas or coal gas, and the fan blows the hot air into the drying chamber through the air pipe to dry the rolled and molded green body; the temperature controller feeds back the real-time temperature in the drying chamber to the control system, and the control system controls the combustion power of the burner according to the real-time temperature information, so that the temperature in the whole drying process is stable.

The production method of the utility model is as follows: s1; placing the mud columns on the two feeding devices 100 respectively, controlling the two feeding devices 100 to operate by the control system, and conveying the mud columns into the two stirring devices 200 from bottom to top;

s2; the control system controls the two stirring devices 200 to fully stir the conveyed mud columns, then the mud columns I and II which are uniformly stirred are respectively output from the discharge ports of the two stirring devices 200, then the mud columns I and II are cut into ceramic blocks I and ceramic blocks II through the cutting assemblies and the taking and placing assemblies at the discharge ports of the two stirring devices 200, and the ceramic blocks I and the ceramic blocks II are respectively placed in the dies on the two die brackets I313 on the annular conveying chain I311;

s3; the control system controls the operation of the annular conveying chain I311 to enable the two mould brackets I313 with the ceramic blocks I and the ceramic blocks II to rotate on the annular conveying chain I311, so that the mould brackets I313 with the ceramic blocks I or the ceramic blocks II are located at the position of a roll forming device I450, the ceramic blocks I or the ceramic blocks II are rolled to form a blank body I through the operation of the roll forming device I450, and then the blank body I and the mould brackets I313 with the ceramic blocks I or the ceramic blocks II are rotated to the next working procedure through the operation of the annular conveying chain I311;

s4; when the blank body I and the mould bracket I313 with the ceramic block I or the ceramic block II rotate to the position above the lifting mechanism, the control system controls the lifting mechanism to jack up a mould with the blank body I and a mould with the ceramic block I or the ceramic block II on the two mould brackets I313;

s5; after the mold with the green body I and the mold with the ceramic block I or the ceramic block II are jacked up, the control system controls the interchanging assembly 350 to clamp the mold with the green body I and the mold with the ceramic block I or the ceramic block II, and then the molds with the green body I and the molds with the ceramic block I or the ceramic block II are placed on the two mold brackets II 314 on the annular conveying chain II 312 by rotating 180 degrees;

s6; the control system controls the operation of the annular conveying chain II 312 to enable the molds with the ceramic blocks I or the ceramic blocks II in the two mold brackets II 314 to rotate to the roll forming device II 500, and the ceramic blocks I or the ceramic blocks II are rolled to form a blank body II through the operation of the roll forming device II 500;

s7; the blank I and the blank II are dried by the drying device 400 on the support frame (310) in the running process of the annular conveying chain II 312, the blank I and the blank II are grabbed by the mold provided with the blank I and the blank II on the annular conveying chain II 312 and exchanged with the mold provided with the blank I and the mold provided with the ceramic block I or the ceramic block II on the annular conveying chain I311 through the matching of the exchange assembly 350 and the lifting mechanism after the annular conveying chain II 312 runs for a circle, and finally the mold provided with the blank I and the blank II on the annular conveying chain I311 runs to the next procedure through the annular conveying chain I311, so that the automatic production is realized in a circulating mode.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the technical solutions of the present invention have been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that the technical solutions described in the foregoing embodiments can be modified or some technical features can be replaced equally; such modifications or substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (9)

1. The utility model provides a pottery automatic production equipment, includes loading attachment (100), agitating unit (200), mould conveyor (300), drying device (400), roll forming device I (450), roll forming device II (500) and control system, its characterized in that: the mould conveying device (300) comprises a support frame (310), and an annular conveying chain I (311) and an annular conveying chain II (312) which are arranged on the support frame (310) in parallel, wherein a plurality of mould brackets I (313) and mould brackets II (314) used for placing moulds are respectively arranged on the annular conveying chain I (311) and the annular conveying chain II (312); the supporting frame (310) is provided with an interchanging assembly (350) for interchanging the die on the die bracket I (313) with the die on the die bracket II (314); wherein the drying device (400) is arranged on the support frame (310); the first roll forming device (450) and the second roll forming device (500) are located at one end of the support frame (310) and are respectively arranged corresponding to the second annular conveying chain (312) and the first annular conveying chain (311), and the first roll forming device (450) and the second roll forming device (500) are two roll forming devices for rolling different types of pottery.

2. The automatic ceramic production apparatus according to claim 1, wherein: the number of the stirring devices (200) is two, the two stirring devices (200) are positioned on one side of the annular conveying chain I (311) or one side of the annular conveying chain II (312), and discharge ports of the two stirring devices (200) are provided with a cutting assembly and a taking and placing assembly; the number of the feeding devices (100) is two, and the two feeding devices (100) are respectively positioned on one side of the two stirring devices (200) and used for conveying ceramic columns for the two stirring devices (200).

3. The automatic ceramic production apparatus according to claim 2, wherein: exchange subassembly (350) including support (351), fixed setting fixed plate (352) at support (351) top, the through-hole has been seted up in fixed plate (352) middle part, the through-hole top is provided with motor fixed plate (354), the below is provided with connecting plate (355), motor fixed plate (354) and connecting plate (355) all through spliced pole (356) with fixed plate (352) fixed connection.

4. The automatic ceramic production apparatus according to claim 3, wherein: the motor fixing plate (354) is provided with a rotating motor (357), and an output shaft of the rotating motor (357) sequentially penetrates through the motor fixing plate (354), the through hole and the connecting plate (355) and is fixedly connected with a grabbing piece.

5. The automatic ceramic production apparatus according to claim 4, wherein: the grabbing piece comprises a grabbing fixing plate (360), wherein a bidirectional telescopic cylinder I (361), a bidirectional telescopic cylinder II (362), a bidirectional telescopic cylinder III (363) and a bidirectional telescopic cylinder IV (364) are arranged on one surface, opposite to an output shaft of a rotating motor (357), of the grabbing fixing plate (360), the bidirectional telescopic cylinder I (361) and the bidirectional telescopic cylinder II (362) are arranged in parallel, the bidirectional telescopic cylinder III (363) and the bidirectional telescopic cylinder IV (364) are arranged in parallel, and the bidirectional telescopic cylinder I (361) and the bidirectional telescopic cylinder II (362) and the bidirectional telescopic cylinder III (363) and the bidirectional telescopic cylinder IV (364) are symmetrically arranged.

6. The automatic ceramic production apparatus according to claim 5, wherein: output shafts at two ends of the bidirectional telescopic cylinder I (361), the bidirectional telescopic cylinder II (362), the bidirectional telescopic cylinder III (363) and the bidirectional telescopic cylinder IV (364) are respectively and fixedly provided with a fixed block I (365) and a fixed block II (366), and bottom ends of the fixed block I (365) and the fixed block II (366) are fixedly connected with a symmetrical connecting block I (367) and a symmetrical connecting block II (368).

7. The automatic ceramic production apparatus according to claim 6, wherein: the bottom of connecting block I (367) with connecting block II (368) is connected with vertical connecting block I (369) and vertical connecting block II (340) respectively, vertical connecting block I (369) with the symmetrical one side in vertical connecting block II (340) bottom all is fixed and is provided with C shape clamp splice (341).

8. The automatic ceramic production apparatus according to claim 7, wherein: the interchange assembly (350) further comprises a lifting mechanism which is arranged on the supporting frame (310) and located below the support frame (351), wherein the lifting mechanism comprises a bidirectional screw rod (370), a bearing seat I (371) and a bearing seat II (372) which are rotatably connected with two ends of the bidirectional screw rod (370), a screw rod sliding block I (373) and a screw rod sliding block II (374) which are arranged on the bidirectional screw rod (370), and a motor (375) which drives the bidirectional screw rod to be rotatably connected.

9. The automatic ceramic production apparatus according to claim 8, wherein: the screw rod sliding block I (373) and the screw rod sliding block II (374) are respectively hinged with a connecting rod I (376) and a connecting rod II (377), one end, far away from the screw rod sliding block I (373), of the connecting rod I (376) is hinged with one end, far away from the screw rod sliding block II (374), of the connecting rod II (377), a supporting plate (378) is fixedly arranged at the top of the hinged position of the connecting rod I (376) and the connecting rod II (377), stand columns (379) are fixedly arranged at four corners of the opposite face of the supporting plate (378) and the bidirectional screw rod (370), and a tray (380) is fixedly arranged at the top end of each stand column (379).

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