阅读说明：本技术 一种金属氧化物陶瓷流水线型干燥总成 (Metal oxide ceramic assembly line type drying assembly ) 是由 谢紫祥 于 2021-10-08 设计创作，主要内容包括：本发明公开了一种金属氧化物陶瓷流水线型干燥总成,定向导轨,其上方设置有活动安装的定位架,且定位架的外侧壁上固定有减少滑动摩擦力的移动轮,并且定向导轨的正上方设置有蒸汽腔；蒸汽腔,其底部等间距固定有输汽组件,且输汽组件的下端安装有移动滚轮；连接件,其上端连接于所述定位架的下方,且连接件的下端固定连接有Y型支脚座；伸缩杆,其端部转动连接于所述Y型支脚座的“Y”字型末端,并且Y型支脚座的中部贯穿式安装有上压架。该金属氧化物陶瓷流水线型干燥总成,能够实现陶瓷工件的快速夹持安装定位,实现工件的流水线型快速干燥加工,并且实现陶瓷工件干燥时的持续蒸汽供给,提高其成型质量。(The invention discloses a metal oxide ceramic assembly line type drying assembly, which comprises a directional guide rail, wherein a movably mounted positioning frame is arranged above the directional guide rail, a moving wheel for reducing sliding friction force is fixed on the outer side wall of the positioning frame, and a steam cavity is arranged right above the directional guide rail; the bottom of the steam cavity is fixed with steam conveying components at equal intervals, and the lower end of each steam conveying component is provided with a movable roller; the upper end of the connecting piece is connected below the positioning frame, and the lower end of the connecting piece is fixedly connected with a Y-shaped supporting foot seat; the end part of the telescopic rod is rotatably connected to the tail end of the Y shape of the Y-shaped supporting foot seat, and the middle part of the Y-shaped supporting foot seat is provided with an upper pressing frame in a penetrating mode. The assembly line type drying assembly for the metal oxide ceramics can realize quick clamping, mounting and positioning of the ceramic workpieces, realize the assembly line type quick drying processing of the workpieces, realize continuous steam supply during the drying of the ceramic workpieces and improve the forming quality of the ceramic workpieces.)

1. A metal oxide ceramic flow-line drying assembly, comprising:

the microwave drying device comprises a directional guide rail, a positioning frame movably mounted above the directional guide rail, moving wheels for reducing sliding friction force and a steam cavity arranged right above the directional guide rail, wherein the moving track of the steam cavity is the same as that of the directional guide rail, and the steam cavity and the directional guide rail are both positioned in a microwave drying chamber;

the bottom of the steam cavity is fixed with steam transmission components at equal intervals, the lower end of each steam transmission component is provided with a movable roller, and the steam cavity and the directional guide rail are both positioned in the microwave drying chamber;

the upper end of the connecting piece is connected below the positioning frames, the lower end of the connecting piece is fixedly connected with Y-shaped supporting foot seats, the connecting piece is positioned between the positioning frames which are symmetrically distributed, and the Y-shaped supporting foot seats are integrally positioned below the directional guide rails;

the end part of the telescopic rod is rotatably connected with the tail end of the Y-shaped support foot seat, the middle of the Y-shaped support foot seat is provided with an upper pressing frame in a penetrating mode, and the center of the bottom of the upper pressing frame and the rod end of the telescopic rod are vertically fixed with ceramic pad feet.

2. The metal oxide ceramic flow-line drying assembly of claim 1, wherein: the lateral section of the directional guide rail is of a transverse U-shaped structure, and the inner walls of the left side and the right side of the directional guide rail which are symmetrically distributed are respectively and fixedly provided with a guide sawtooth strip and a conductive slide rail.

3. The metal oxide ceramic flow-line drying assembly of claim 1, wherein: the locating rack middle part is provided with interior cavity, and the top of interior cavity is fixed with the waffle slab to the left and right sides of waffle slab is 45 slope settings, and interior cavity and waffle slab are located the steam transmission subassembly under moreover, and the inside of interior cavity link up the setting with the inside of connecting piece simultaneously.

4. The metal oxide ceramic flow-line drying assembly of claim 1, wherein: the steam transmission assembly consists of an inner hollow pipe and a hollow pipe which are composed of three parts of rubber sealing covers;

interior hollow tube, its top is fixed in the bottom in steam chamber, and the inside run-through movable mounting of interior hollow tube has the hollow tube to the flexible piece is installed to the run-through connection department of hollow tube and interior hollow tube, and the upper end of hollow tube is fixed with the sealed lid of rubber in addition, and the sealed lid of rubber is located the inside in steam chamber, and the fixed connection department of hollow tube and the sealed lid of rubber sets up to fretwork network structure simultaneously.

5. The metal oxide ceramic flow-line drying assembly of claim 1, wherein: the connecting piece is of a cross-shaped hollow structure, the left side and the right side of the middle of the connecting piece are respectively provided with a gear shaft and an electrifying rod, the gear shaft and the electrifying rod are respectively arranged in one-to-one correspondence with the guide sawtooth strips and the conductive slide rails in the directional guide rail, the gear shaft is meshed with the guide sawtooth strips, and the electrifying rod is in electrical connection with the conductive slide rails in a laminating sliding manner;

the inner center position of the connecting piece is also rotatably provided with a turbine cylinder, the outer wall of the turbine cylinder and the middle shaft end of the gear shaft are provided with mutually meshed bevel gears, the center of the bottom of the turbine cylinder is fixedly connected with a push rod, and the outer wall of the lower end of the push rod is of a rectangular structure.

6. The metal oxide ceramic flow-line drying assembly of claim 1, wherein: the top center and the edge of Y type leg seat imbed respectively and are fixed with first shell and second shell, and motor body and ring gear are installed respectively to the inboard bottom of first shell and middle part to the output shaft outside of motor body is provided with the transmission ring, and the inside of first shell and the bottom of transmission ring are provided with electro-magnet and permanent magnet respectively moreover, and electro-magnet and permanent magnet both set up to the annular form simultaneously.

7. The metal oxide ceramic flow-line drying assembly of claim 6, wherein: both cross sections of the output shaft outer side wall of the motor body and the middle inner side wall of the transmission ring are both arranged to be rectangular structures, and are movably connected with each other through vertical fitting and transverse clamping, transmission thin rods are arranged on the transmission ring in a penetrating mode at equal intervals, elastic pieces are fixed between the middle of each transmission thin rod and the inside of the transmission ring, the outer side wall of the transmission ring is connected with the inner wall of the connecting piece in a sliding mode, and the gear ring top is arranged right below the transmission ring and is provided with a clamping groove with the diameter larger than the diameter of each transmission thin rod.

8. The metal oxide ceramic flow-line drying assembly of claim 6, wherein: the second shells are distributed around the middle shaft of the first shell at equal angles at the top edge of the Y-shaped supporting foot seat, a first gear and a second gear are installed in the adjacent second shells in an interval type rotating mode, the first gear and the second gear are both meshed with the gear ring, and meanwhile, a take-up reel is fixed on the second gear;

be provided with the atress line on the take-up reel, and the line end of atress line runs through the second shell and is connected with the sawtooth pole to the sawtooth pole is provided with 3 stabilizer blade one-to-one with Y type support foot seat, and the outer wall of sawtooth pole and Y type support foot seat is the swing joint who runs through moreover, and sawtooth pole and gear body intermeshing simultaneously, rotation connection epaxial of gear body fixedly connected with telescopic link and Y type support foot seat.

9. The metal oxide ceramic flow-line drying assembly of claim 8, wherein: first gear and Y type leg base are the relative revolution mechanic of bearing installation, and the middle part of first gear and the shaft-like outer wall threaded connection of last pressure frame to go up and run through the distribution between pressure frame and the Y type leg base, go up the vertical coaxial distribution of pressure frame and Y type leg base moreover.

Technical Field

The invention relates to the technical field of special ceramic product processing, in particular to a metal oxide ceramic assembly line type drying assembly.

Background

The special ceramic covers various types such as metal oxide ceramics according to the difference of the components in the special ceramic, and when the metal oxide ceramics are produced and processed, in order to improve the shaping efficiency and the quality impression of shaping, the special ceramic needs to be dried, so that the whole form of the special ceramic is stable, and the problems of local defects and deformation after the special ceramic is shaped are avoided, and the influence on normal use is avoided.

However, the existing metal oxide ceramic drying assembly has the following problems in use:

1. the positioning operation of the workpiece is inconvenient, the shielding and local compression of the workpiece are easy to occur due to the reinforcing and positioning operation, the defect of surface shaping is formed, the processing efficiency is low, and the workpiece produced by the assembly line cannot be stably, efficiently and quickly processed, dried and shaped;

2. the drying processing of the ceramic workpiece is carried out, the equipment operation is complex, the cost is high, and the problem of quality influence such as drying chap of local positions of the ceramic workpiece during drying and shaping is easily caused due to the humidity problem of the environment.

In order to solve the problems, innovative design is urgently needed on the basis of the original metal oxide ceramic drying assembly.

Disclosure of Invention

The invention aims to provide a metal oxide ceramic assembly line type drying assembly, which solves the problems that the prior metal oxide ceramic drying assembly has inconvenient positioning operation on a workpiece, easily generates the defects of surface shaping due to the shielding and local compression of the workpiece because of the reinforcing and positioning operation, has low processing efficiency, can not stably and efficiently rapidly process, dry and shape the workpiece produced by the assembly line to dry and process the ceramic workpiece, has complex equipment operation and high cost, and easily generates drying chap and the like at local positions during the drying and shaping due to the humidity problem of the environment.

In order to achieve the purpose, the invention provides the following technical scheme: a metal oxide ceramic flow-line drying assembly comprising:

the microwave drying device comprises a directional guide rail, a positioning frame movably mounted above the directional guide rail, moving wheels for reducing sliding friction force and a steam cavity arranged right above the directional guide rail, wherein the moving track of the steam cavity is the same as that of the directional guide rail, and the steam cavity and the directional guide rail are both positioned in a microwave drying chamber;

the bottom of the steam cavity is fixed with steam conveying components at equal intervals, and the lower end of each steam conveying component is provided with a movable roller;

the upper end of the connecting piece is connected below the positioning frames, the lower end of the connecting piece is fixedly connected with Y-shaped supporting foot seats, the connecting piece is positioned between the positioning frames which are symmetrically distributed, and the Y-shaped supporting foot seats are integrally positioned below the directional guide rails;

the end part of the telescopic rod is rotatably connected with the tail end of the Y-shaped support foot seat, the middle of the Y-shaped support foot seat is provided with an upper pressing frame in a penetrating mode, and the center of the bottom of the upper pressing frame and the rod end of the telescopic rod are vertically fixed with ceramic pad feet.

By adopting the technical scheme, the ceramic workpiece can be conveniently installed and positioned, the production line type continuous drying of the workpiece is realized, the drying efficiency is improved, the steam supplement can be carried out on the ceramic workpiece which is correspondingly dried, and the shaping quality of the ceramic workpiece is improved.

Preferably, the lateral section of the directional guide rail is arranged to be a transverse U-shaped structure, and the inner walls of the left side and the right side of the directional guide rail which are symmetrically distributed are respectively and fixedly provided with a guide sawtooth strip and a conductive slide rail.

By adopting the technical scheme, when the directional guide rail guides and moves the clamping and positioning mechanism of the ceramic workpiece, the energy used by the equipment in the mechanism is continuously supplied.

Preferably, the locating rack middle part is provided with interior cavity, and the top of interior cavity is fixed with the waffle slab to the left and right sides of waffle slab is 45 slope settings, and interior cavity and waffle slab are located the steam transmission subassembly under moreover, and the inside of interior cavity link up the setting with the inside of connecting piece simultaneously.

By adopting the technical scheme, when the steam transmission assembly is contacted with the grid plate, steam can be continuously introduced into the inner cavity.

Preferably, the steam transmission assembly consists of an inner hollow pipe, a hollow pipe and a rubber sealing cover;

interior hollow tube, its top is fixed in the bottom in steam chamber, and the inside run-through movable mounting of interior hollow tube has the hollow tube to the flexible piece is installed to the run-through connection department of hollow tube and interior hollow tube, and the upper end of hollow tube is fixed with the sealed lid of rubber in addition, and the sealed lid of rubber is located the inside in steam chamber, and the fixed connection department of hollow tube and the sealed lid of rubber sets up to fretwork network structure simultaneously.

By adopting the technical scheme, the steam transmission assembly can stretch when contacting with the grid plate, the steam in the steam cavity is aligned and discharged, and the waste caused by the overflow of all the steam is avoided.

Preferably, the connecting piece is of a cross-shaped hollow structure, the left side and the right side of the middle of the connecting piece are respectively provided with a gear shaft and an electrifying rod, the gear shaft and the electrifying rod are respectively arranged in one-to-one correspondence with the guide sawtooth strips and the conductive slide rails inside the directional guide rail, the gear shaft is meshed with the guide sawtooth strips, and the electrifying rod is in electrical connection with the conductive slide rails in a fitting sliding manner;

the inner center position of the connecting piece is also rotatably provided with a turbine cylinder, the outer wall of the turbine cylinder and the middle shaft end of the gear shaft are provided with mutually meshed bevel gears, the center of the bottom of the turbine cylinder is fixedly connected with a push rod, and the outer wall of the lower end of the push rod is of a rectangular structure.

By adopting the technical scheme, the Y-shaped supporting foot seat and the bottom structure thereof are convenient to position by installing the connecting piece, meanwhile, the ceramic workpiece clamping and positioning mechanism can automatically walk by utilizing the gear shaft and the guide sawtooth strips, the production line type drying processing is realized, and the turbine cylinder can generate downward absorbed external force to steam when rotating, so that the steam can efficiently guide the position of the workpiece.

Preferably, the top center and the edge of Y type leg base are embedded respectively and are fixed with first shell and second shell, and motor body and ring gear are installed respectively to the inboard bottom of first shell and middle part to the output shaft outside of motor body is provided with the transmission ring, and the inside of first shell and the bottom of transmission ring are provided with electro-magnet and permanent magnet respectively moreover, and electro-magnet and permanent magnet both set up to the annular form simultaneously.

By adopting the technical scheme, the positioning and mounting height of the transmission ring is changed by utilizing the repulsion of like poles and the attraction of unlike poles of the magnetism between the electromagnet and the permanent magnet.

Preferably, both cross sections of the output shaft outer side wall of the motor body and the middle inner side wall of the transmission ring are set to be rectangular structures, the cross sections of the output shaft outer side wall of the motor body and the middle inner side wall of the transmission ring are vertically attached and movably connected through the transmission ring, the transmission ring is provided with the transmission thin rod at an equal interval, an elastic part is fixed between the middle of the transmission thin rod and the inside of the transmission ring, the outer side wall of the transmission ring is connected with the inner wall of the connecting part in a sliding mode, and the gear ring top is set to be a clamping groove with the diameter larger than the diameter of the transmission thin rod.

Adopt above-mentioned technical scheme for the transmission ring can enough the elevating movement also can rotate with the rotation synchronization of motor body, and the effect that utilizes the transmission pin drives catch bar or gear ring rotatory.

Preferably, the second shells are distributed around the middle shaft of the first shell at equal angles at the top edge of the Y-shaped supporting foot seat, the adjacent second shells are internally and rotatably provided with a first gear and a second gear at intervals, the first gear and the second gear are both meshed with the gear ring, and meanwhile, the second gear is fixedly provided with a take-up reel;

be provided with the atress line on the take-up reel, and the line end of atress line runs through the second shell and is connected with the sawtooth pole to the sawtooth pole is provided with 3 stabilizer blade one-to-one with Y type support foot seat, and the outer wall of sawtooth pole and Y type support foot seat is the swing joint who runs through moreover, and sawtooth pole and gear body intermeshing simultaneously, rotation connection epaxial of gear body fixedly connected with telescopic link and Y type support foot seat.

By adopting the technical scheme, the rotation of the gear ring can drive the first gear and the second gear to rotate, the rotation of the second gear rolls the stress line, the rotation angle of the telescopic rod is changed, and the workpiece is pushed and positioned from bottom to top.

Preferably, the first gear and the Y-shaped supporting foot seat are of a relative rotation structure installed by a bearing, the middle part of the first gear is in threaded connection with the rod-shaped outer wall of the upper pressing frame, the upper pressing frame and the Y-shaped supporting foot seat are distributed in a penetrating mode, and the upper pressing frame and the Y-shaped supporting foot seat are vertically and coaxially distributed.

By adopting the technical scheme, the first gear rotates, the mounting height of the upper pressing frame is changed, the workpiece is pushed and positioned from top to bottom, and the stable effect of workpiece positioning is improved.

Compared with the prior art, the invention has the beneficial effects that: the assembly line type drying assembly for the metal oxide ceramics can realize quick clamping, mounting and positioning of the ceramic workpieces, realize the assembly line type quick drying processing of the workpieces, realize continuous steam supply during the drying of the ceramic workpieces and improve the forming quality of the ceramic workpieces;

1. the driving ring and the driving thin rod telescopically mounted on the driving ring are changed in position only by changing the magnetism of the electromagnet, the gear ring or the push rod is caused to rotate when the motor body drives the driving ring to rotate by utilizing the axial sliding and radial clamping actions among the driving thin rod, the push rod and the gear ring, the sawtooth rod is caused to move in position and is meshed with the gear body by utilizing the rotation of the gear ring and the meshing connection relation between the gear ring and the first gear and the second gear, the rotation angle of the telescopic rod is adjusted, the upper pressing frame is in threaded connection with the first gear to lift, the upper pressing frame and the telescopic rod act together, and the ceramic workpiece is clamped and positioned conveniently;

2. at transmission pin rotary motion, it is self and turbine section of thick bamboo synchronous revolution, utilize the awl tooth meshing transmission between turbine section of thick bamboo and the gear shaft, reach the purpose of gear shaft rotary motion, through the rotation of gear shaft and its and the meshing between the direction sawtooth rack, realize the removal drive of connecting piece and upper structure, carry out the dry processing of portable flowing water type of ceramic work piece, and the extending structure setting of steam transmission subassembly and the combination of grid plate, when can making ceramic work piece carry out continuous movement, steam transmission subassembly can make the directional interior through inner cavity of steam chamber, the leading-in first shell of connecting piece and turbine section of thick bamboo, then utilize the leading-in ceramic work piece position department that corresponds of the mesh of first shell bottom, realize the high quality design of ceramic work piece and handle.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a side view of the external structure of the present invention;

FIG. 3 is a schematic side view of the cross-sectional structure of the present invention;

FIG. 4 is an enlarged view of the structure at A in FIG. 3 according to the present invention;

FIG. 5 is a schematic view of the distribution structure of the driving thin rods of the present invention;

FIG. 6 is a schematic view of the driving pin mounting structure of the present invention;

FIG. 7 is a schematic view of the arrangement of the first and second gears of the present invention;

FIG. 8 is a schematic view of the driving structure of the sawtooth rod and the gear body of the present invention;

FIG. 9 is a schematic view of a connection structure of a first gear and an upper pressing frame according to the present invention;

FIG. 10 is a schematic view of a steam delivery assembly distribution of the present invention;

FIG. 11 is a schematic view of a steam delivery assembly of the present invention.

In the figure: 1. a directional guide rail; 101. a guide sawtooth strip; 102. a conductive slide rail; 2. a positioning frame; 201. an inner cavity; 202. a grid plate; 3. a moving wheel; 4. a steam chamber; 5. a steam delivery assembly; 501. an inner hollow pipe; 502. a hollow tube; 503. a rubber sealing cover; 6. moving the roller; 7. a connecting member; 701. a gear shaft; 702. a power-on pole; 703. a turbine barrel; 704. conical teeth; 705. a push rod; 8. a Y-shaped supporting foot seat; 801. a first housing; 802. a second housing; 803. a motor body; 804. a gear ring; 805. a drive ring; 806. an electromagnet; 807. a permanent magnet; 808. a driving thin rod; 809. a first gear; 810. a second gear; 811. a take-up reel; 812. a stress line; 813. a serrated bar; 814. a gear body; 9. a telescopic rod; 10. an upper pressing frame; 11. ceramic foot pad.

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.

Referring to fig. 1-11, the present invention provides a technical solution: a metal oxide ceramic flow-line drying assembly comprising:

the microwave drying device comprises a directional guide rail 1, a movably mounted positioning frame 2 is arranged above the directional guide rail 1, a moving wheel 3 for reducing sliding friction force is fixed on the outer side wall of the positioning frame 2, a steam cavity 4 is arranged right above the directional guide rail 1, the moving track of the steam cavity 4 is the same as that of the directional guide rail 1, the steam cavity 4 and the directional guide rail 1 are both positioned in a microwave drying chamber, the directional guide rail 1 is used for limiting the movement convenience of a ceramic workpiece and a clamping mechanism thereof, the continuous drying of a streamline type in the microwave drying chamber is realized, and the processing efficiency is improved; the side cross-section of directional guide rail 1 sets up to horizontal "U" style of calligraphy structure, and on the directional guide rail 1 left and right sides inner wall of symmetric distribution respectively fixed mounting have guide sawtooth strip 101 and electrically conductive slide rail 102, the design of directional guide rail 1 is convenient for the installation location of connecting piece 7, locating rack 2 middle part is provided with interior cavity 201, and the top of interior cavity 201 is fixed with grid plate 202, and the left and right sides of grid plate 202 is 45 slope settings, and interior cavity 201 and grid plate 202 are located steam transmission subassembly 5 under, the inside of interior cavity 201 link up the setting with the inside of connecting piece 7 simultaneously, along with the walking motion of locating rack 2, grid plate 202 on the locating rack 2 can promote steam transmission subassembly 5, make it take place ascending promotion, lead to its structure form change that takes place to stretch out and draw back.

As shown in the technical scheme of fig. 1 and fig. 10-11, a steam cavity 4 is fixed with steam delivery components 5 at the bottom at equal intervals, the lower end of the steam delivery component 5 is provided with a movable roller 6, and the steam delivery component 5 consists of three parts, namely an inner hollow pipe 501 and a hollow pipe 502 which are provided with rubber sealing covers 503;

the top of the inner hollow tube 501 is fixed at the bottom of the steam cavity 4, and the hollow tube 502 is movably installed in the inner hollow tube 501 in a penetrating way, an elastic piece is arranged at the penetrating connection part of the hollow tube 502 and the hollow tube 501, a rubber sealing cover 503 is fixed at the upper end of the hollow tube 502, the rubber sealing cover 503 is positioned in the steam cavity 4, meanwhile, the fixed connection position of the hollow tube 502 and the rubber sealing cover 503 is set to be a hollow net structure, when the mesh plate 202 pushes the steam delivery module 5 as described above, the hollow tube 502 and the inner hollow tube 501 are relatively contracted, so that the rubber sealing cover 503 is not attached to the inside of the steam cavity 4 any more, the steam in the steam cavity 4 enters through the hollow mesh structure on the hollow tube 502, and is discharged from the lower end of the guide grid plate 202 into the inner cavity 201 below the guide grid plate, and steam at the alignment position is discharged and utilized, so that the steam is prevented from being discharged randomly to generate great waste.

As shown in fig. 1-3, in the technical solution, the upper end of the connecting member 7 is connected below the positioning frame 2, the lower end of the connecting member 7 is fixedly connected with the Y-shaped supporting base 8, the connecting member 7 is located between the positioning frames 2 which are symmetrically distributed, the Y-shaped supporting base 8 is integrally located below the directional guide rail 1, the Y-shaped supporting base 8 is used for clamping and positioning the ceramic workpiece, the connecting member 7 is arranged in a cross-shaped hollow structure, the left side and the right side of the middle part of the connecting member 7 are respectively provided with the gear shaft 701 and the power-on rod 702, the gear shaft 701 and the power-on rod 702 are respectively arranged corresponding to the guiding sawtooth strips 101 and the conductive slide rails 102 in the directional guide rail 1, the gear shaft 701 is meshed with the guiding sawtooth strips 101, the power-on rod 702 is in electrical connection with the conductive slide rails 102 in a laminating sliding manner, the cross-shaped hollow connecting member 7 is arranged, after being guided into the inner cavity 201, steam can enter the first shell 801 through the hollow connecting piece 7 and is directly discharged to the position of the ceramic workpiece through meshes at the bottom of the first shell 801, so that the drying and forming quality of the ceramic workpiece is improved, the gear shaft 701 is meshed with the guide sawtooth racks 101 during rotation, the connecting piece 7 and the upper connecting structure thereof can be driven to move and change on the directional guide rail 1, the streamline processing of the workpiece is realized, and the electrifying rod 702 is continuously attached to the conductive slide rail 102 along with the movement of the connecting piece 7 and the upper structure thereof, so that continuous electric energy can be provided for the use of the motor body 803;

the turbine cylinder 703 is rotatably mounted at the center of the inside of the connecting piece 7, the conical teeth 704 which are meshed with each other are mounted on the outer wall of the turbine cylinder 703 and the middle shaft end of the gear shaft 701, the push rod 705 is fixedly connected to the center of the bottom of the turbine cylinder 703, and the outer wall of the lower end of the push rod 705 is of a rectangular structure, so that when the push rod 705 rotates, the push rod 705 can drive the turbine cylinder 703 to rotate, steam of the turbine cylinder 703 is continuously conveyed from top to bottom, waste and dissipation are reduced, and the conical teeth 704 between the turbine cylinder 703 and the gear shaft 701 are driven to provide external power output for rotation of the gear shaft 701;

a first shell 801 and a second shell 802 are respectively embedded and fixed at the top center and the edge of the Y-shaped support foot seat 8, a motor body 803 and a gear ring 804 are respectively installed at the bottom and the middle of the inner side of the first shell 801, a transmission ring 805 is arranged at the outer side of an output shaft of the motor body 803, an electromagnet 806 and a permanent magnet 807 are respectively arranged at the inner side of the first shell 801 and the bottom of the transmission ring 805, the electromagnet 806 and the permanent magnet 807 are both arranged in a ring shape, magnetism with different poles is generated through the control of the electromagnet 806, when repulsion with the permanent magnet 807 is generated, the transmission ring 805 and the upper structure thereof can move to lean against the turbine barrel 703 and the push rod 705, the cross sections of the outer side wall of the output shaft of the motor body 803 and the inner side wall of the middle part of the transmission ring 805 are both arranged in a rectangular structure, and are movably connected in a vertical joint and a transverse joint manner, and transmission thin rods 808 are installed on the transmission ring 805 at equal intervals, and an elastic member is fixed between the middle part of the driving thin rod 808 and the inner part of the driving ring 805, meanwhile, the outer side wall of the transmission ring 805 is in close sliding connection with the inner wall of the connecting piece 7, the top of the gear ring 804 right below the transmission ring 805 is provided with a clamping groove with the diameter larger than that of the transmission slender rod 808, the driving ring 805 and the driving thin rod 808 thereon move towards the pushing rod 705 and are telescopic, so that the driving thin rod 808 wraps the pushing rod 705, the driving ring 805 is slid in the axial direction and engaged in the radial direction, and when the motor body 803 rotates, the driving ring rotates in synchronization with the turbine cylinder 703 and the pusher 705 to provide power for the rotation of the turbine cylinder 703, and in the same way, when the electromagnet 806 generates an attractive force with the permanent magnet 807, the driving ring 805 and the driving thin rod 808 move downwards, and the driving thin rod 808 is guided into the slot on the gear ring 804, so that the driving ring 805 and the gear ring 804 rotate synchronously when the motor body 803 rotates.

By adopting the technical scheme as shown in figures 1-2 and 7-9, the end part of the telescopic rod 9 is rotationally connected with the Y-shaped tail end of the Y-shaped supporting foot seat 8, an upper pressing frame 10 is installed in the middle of the Y-shaped supporting foot seat 8 in a penetrating mode, ceramic pad feet 11 are vertically fixed at the center of the bottom of the upper pressing frame 10 and the rod end of the telescopic rod 9, the Y-shaped supporting foot seat 8 is used for clamping and positioning ceramic workpieces, the second shell 802 is distributed around the center shaft of the first shell 801 at the edge of the top of the Y-shaped supporting foot seat 8 at equal angles, and a first gear 809 and a second gear 810 are installed inside the adjacent second outer shells 802 in a spaced-apart rotating manner, and the first gear 809 and the second gear 810 are both engaged with the gear ring 804, and the take-up reel 811 is fixed on the second gear 810, when the gear ring 804 rotates, the first gear 809 and the second gear 810 can synchronously rotate;

the take-up reel 811 is provided with a stress line 812, the line end of the stress line 812 penetrates through the second shell 802 and is connected with a sawtooth rod 813, the sawtooth rod 813 is provided with 3 support legs which are in one-to-one correspondence with the support legs of the Y-shaped support leg seat 8, the outer walls of the sawtooth rod 813 and the Y-shaped support leg seat 8 are in through movable connection, the sawtooth rod 813 is meshed with the gear body 814, the gear body 814 is fixedly connected with a telescopic rod 9 and a rotating connecting middle shaft of the Y-shaped support leg seat 8, the rotation of the second gear 810 winds up the stress line 812 through the take-up reel 811, so that the stress line 813 pulls the sawtooth rod to change the position movement, the rotating included angle of the telescopic rod 9 is changed by the meshing of the sawtooth rod 813 and the gear body 814, and the elastic member installed on the sawtooth rod 813 acts to clamp a workpiece by external force from bottom to top, and the telescopic length change of the telescopic rod 9 can facilitate the clamping of the ceramic workpiece, and first gear 809 and Y type leg base 8 are the relative revolution mechanic of bearing installation, and the middle part of first gear 809 and the shaft-like outer wall threaded connection of last pressure frame 10, and go up and run through the distribution between pressure frame 10 and the Y type leg base 8, and go up pressure frame 10 and the vertical coaxial distribution of Y type leg base 8, it can change the last pressure frame 10 location height of its middle part threaded installation to rotate at first gear 809, make it give ceramic work piece from top to bottom to press frame 10, cooperate with telescopic link 9, make things convenient for the centre gripping location of ceramic work piece on Y type leg base 8 to press the location height

The working principle is as follows: when the metal oxide ceramic assembly line type drying assembly is used, firstly, the transmission ring 805 and the transmission thin rod 808 move downwards through the magnetic change between the electromagnet 806 and the permanent magnet 807, the transmission thin rod 808 is guided into the clamping groove on the gear ring 804, the transmission ring 805 and the gear ring 804 synchronously rotate when the motor body 803 rotates, the gear ring 804 is meshed with the first gear 809 and the second gear 810 to drive the first gear 809 and the second gear to rotate, the stress line 812 is wound to change the position of the sawtooth rod 813, the rotation angle of the telescopic rod 9 is changed by the meshing of the sawtooth rod 813 and the gear body 814 and the elastic action of the elastic piece, the rotation of the first gear 809 enables the upper pressing frame 10 in threaded connection with the middle part to move downwards, the rapid positioning of the ceramic workpiece is realized through the upper pressing frame 10 and the telescopic rod 9, and when the magnetism between the electromagnet 806 and the permanent magnet 807 is changed to enable the transmission ring 805 and the transmission thin rod 808 to move upwards, the driving thin rod 808 comprises a driving ring 805 and the pushing rod 705 which rotate synchronously when the motor body 803 rotates, so that the pushing rod 705 and the turbine cylinder 703 generate steam suction from top to bottom, and simultaneously, the gear shaft 701 rotates and is meshed with the guide sawtooth racks 101 by utilizing the meshing of the bevel gears, so that the connecting piece 7 and the structure on the connecting piece drive the ceramic workpiece to move, thereby realizing the pipeline type drying in the microwave drying chamber, when the ceramic workpiece moves, the steam transmission component 5 contacts with the grid plate 202 and extends and retracts, so that the steam in the steam cavity 4 is guided to the workpiece through the inner cavity 201, the connecting piece 7 and the first shell 801, the humidity of the drying environment is changed, and the drying and forming quality is improved.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.