阅读说明：本技术 一种用于超精密半导体陶瓷部件调压紧固加工装置 (Pressure regulating and fastening processing device for ultra-precise semiconductor ceramic component ) 是由 王超杰 于 2021-05-19 设计创作，主要内容包括：本发明涉及一种无机非金属领域,尤其涉及一种用于超精密半导体陶瓷部件调压紧固加工装置。本发明的技术问题为：提供一种用于超精密半导体陶瓷部件调压紧固加工装置。技术方案：一种用于超精密半导体陶瓷部件调压紧固加工装置,包括有底板组件和支座等；底板组件与支座相连接。本发明实现了将所用粘接剂以及涂抹后沉底的粘接剂均匀的涂抹在陶瓷件内表面,接着,再将上层陶瓷件挤压进陶瓷件内部制成所需陶瓷部件,接着,再对陶瓷部件进行挤压使陶瓷件粘接牢固,且可调节控制挤压时的压力,从而使得在不伤害陶瓷部件的情况下,使得陶瓷件粘接牢固,提高了产品质量,避免了安全隐患。(The invention relates to the field of inorganic nonmetal, in particular to a pressure regulating and fastening processing device for an ultra-precise semiconductor ceramic component. The technical problem of the invention is as follows: provided is a pressure regulating and fastening processing device for an ultra-precise semiconductor ceramic component. The technical scheme is as follows: a pressure regulating and fastening processing device for an ultra-precise semiconductor ceramic component comprises a bottom plate assembly, a support and the like; the bottom plate assembly is connected with the support. The invention realizes that the adhesive and the adhesive which is coated and sinks to the bottom are uniformly coated on the inner surface of the ceramic part, then the upper layer ceramic part is extruded into the ceramic part to be made into the required ceramic part, then the ceramic part is extruded to ensure that the ceramic part is firmly bonded, and the pressure during extrusion can be regulated and controlled, thereby ensuring that the ceramic part is firmly bonded under the condition of not damaging the ceramic part, improving the product quality and avoiding the potential safety hazard.)

1. The utility model provides a be used for ultra-precise semiconductor ceramic part pressure regulating fastening processingequipment, includes bottom plate subassembly (1), control panel (5), support (6), support (7), support column (8), slipmat (9), collecting box (10) and handle (11), characterized by: the device also comprises a smearing unit (2), a bonding unit (3) and a pressure regulating and fastening unit (4); the bottom plate component (1) is connected with the smearing unit (2); the bottom plate assembly (1) is connected with the bonding unit (3); the bottom plate component (1) is connected with the pressure regulating fastening unit (4); the bottom plate component (1) is connected with the support (6); the bottom plate component (1) is connected with the bracket (7); the bottom plate component (1) is connected with five groups of supporting columns (8); the bottom plate component (1) is connected with the collecting box (10); the smearing unit (2) is connected with the bonding unit (3); the smearing unit (2) is connected with the pressure regulating fastening unit (4); the pressure regulating fastening unit (4) is connected with the bracket (7); the control screen (5) is connected with the support (6); the five groups of supporting columns (8) are connected with the five groups of anti-skid pads (9); the collecting box (10) is connected with a handle (11).

2. The pressure regulating and fastening processing device for the ultra-precise semiconductor ceramic part according to claim 1, wherein the coating unit (2) comprises a first transmission wheel (201), a second transmission wheel (202), a first transmission shaft (203), a third transmission wheel (204), a fourth transmission wheel (205), a second transmission shaft (206), a first bevel gear (207), a second bevel gear (208), a third transmission shaft (209), a material tray (210), a first straight gear (211), a second straight gear (212), a third straight gear (213), an arc-shaped frame (214), a first electric push rod (215) and an arc-shaped block (216); the first transmission wheel (201) is connected with the pressure regulating fastening unit (4); the first transmission wheel (201) is in transmission connection with the second transmission wheel (202) through a belt; the second transmission wheel (202) is fixedly connected with the first transmission shaft (203); the first transmission shaft (203) is rotatably connected with the bottom plate component (1); the first transmission shaft (203) is fixedly connected with the third transmission wheel (204); the third driving wheel (204) is in driving connection with the fourth driving wheel (205) through a belt; the fourth transmission wheel (205) is fixedly connected with the second transmission shaft (206); the second transmission shaft (206) is rotatably connected with the bottom plate component (1); the second transmission shaft (206) is fixedly connected with the first bevel gear (207); the first bevel gear (207) is meshed with the second bevel gear (208); the second bevel gear (208) is fixedly connected with a third transmission shaft (209); the third transmission shaft (209) is fixedly connected with the material tray (210); the material tray (210) is connected with the bonding unit (3); the first transmission shaft (203) is fixedly connected with the first straight gear (211); the first straight gear (211) is meshed with the second straight gear (212); the second straight gear (212) is rotationally connected with the bottom plate component (1) through a rotating shaft; the first straight gear (211) is meshed with the third straight gear (213); the third straight gear (213) is rotationally connected with the bottom plate component (1) through a rotating shaft; the second straight gear (212) is rotationally connected with the arc-shaped frame (214) through a rotating shaft; the third straight gear (213) is rotationally connected with the arc-shaped frame (214) through a rotating shaft; the arc-shaped frame (214) is fixedly connected with a first electric push rod (215); the first electric push rod (215) is fixedly connected with the arc-shaped block (216).

3. The pressure regulating and fastening processing device for the ultra-precise semiconductor ceramic component according to claim 2, wherein the bonding unit (3) comprises a first electric rotating disc (301), a first screw rod (302), a first sliding block (303), a first mechanical claw (304), a first fixing plate (305), a bearing plate (306), a second mechanical claw (307), a second sliding block (308), a second fixing plate (309), a first electric sliding rail (310), a first fixing frame (311), a second electric sliding rail (312), a second electric rotating disc (313), a fourth transmission shaft (314), a first connecting rod (315), a sliding plate (316), a first transmission plate (317), a disc (318), a bump (319), a third fixing plate (320) and a spring rod (321); the stator of the first electric turntable (301) is fixedly connected with the bottom plate component (1); a rotor of the first electric turntable (301) is fixedly connected with a first screw rod (302); the first screw rod (302) is rotatably connected with the bottom plate assembly (1); the first screw rod (302) is in screwed connection with the first sliding block (303); the first sliding block (303) is fixedly connected with the first mechanical claw (304); the first sliding block (303) is in sliding connection with the first fixing plate (305); the first fixing plate (305) is fixedly connected with the bottom plate component (1); the first mechanical claw (304) is fixedly connected with the bearing plate (306); the bearing plate (306) is rotatably connected with the material tray (210); the bearing plate (306) is fixedly connected with the second mechanical claw (307); the second mechanical claw (307) is fixedly connected with the second sliding block (308); the second sliding block (308) is connected with the second fixing plate (309) in a sliding manner; the second fixing plate (309) is fixedly connected with the bottom plate component (1); a first electric slide rail (310) is arranged on the upper side part of the second fixing plate (309); the first electric slide rail (310) is fixedly connected with the bottom plate component (1); the first electric sliding rail (310) is in sliding connection with the first fixing frame (311); the first fixing frame (311) is in sliding connection with the second electric sliding rail (312); the second electric slide rail (312) is fixedly connected with the bottom plate component (1); the first fixed frame (311) is fixedly connected with a stator of the second electric turntable (313); the rotor of the second electric turntable (313) is fixedly connected with the fourth transmission shaft (314); the fourth transmission shaft (314) is rotationally connected with the first fixed frame (311); the fourth transmission shaft (314) is fixedly connected with the first connecting rod (315); the first connecting rod (315) is connected with the sliding plate (316) in a sliding way; the sliding plate (316) is fixedly connected with the first transmission plate (317); the first transmission plate (317) is connected with the first fixed frame (311) in a sliding way; the first driving plate (317) is fixedly connected with the disc (318); the disc (318) is fixedly connected with a plurality of groups of lugs (319); the first fixed frame (311) is in sliding connection with a plurality of groups of spring rods (321); the multiple groups of spring rods (321) are fixedly connected with the multiple groups of third fixing plates (320).

4. The voltage-regulating fastening processing device for the ultra-precise semiconductor ceramic component as claimed in claim 3, wherein the voltage-regulating fastening unit (4) comprises a motor (401), a fifth transmission shaft (402), a sixth transmission shaft (403), a third bevel gear (404), a fourth fixing plate (405), a second electric push rod (406), a fourth bevel gear (407), a seventh transmission shaft (408), a fifth transmission wheel (409), a sixth transmission wheel (410), an expansion link (411), a fourth spur gear (412), a fifth fixing plate (413), a third electric push rod (414), an eighth transmission shaft (415), a second fixing frame (416), a fifth bevel gear (417), a sixth bevel gear (418), a ninth transmission shaft (419), a second lead screw (420), a first fixing block (421), a connecting shaft (422), an arc-shaped plate (423), a second connecting rod (424), a fifth bevel gear (417), a sixth bevel gear (418), a ninth transmission shaft (419), a first lead screw (420), a first fixing block (421), a connecting shaft (422), an arc-shaped plate (423), a second connecting rod (424), a third connecting rod (414), a fourth connecting rod (410), a fourth connecting rod (a fifth connecting rod (410), a sixth connecting rod (410), a sixth bevel gear (410), a sixth connecting rod (410), a sixth bevel gear (a sixth connecting rod (a sixth bevel gear (410), a sixth connecting rod (410), a sixth connecting rod (410), a sixth connecting rod (, A seventh transmission wheel (425), an eighth transmission wheel (426), a tenth transmission shaft (427), a cam bracket (428), a third connecting rod (429), a connecting frame (430), a second transmission plate (431), a second fixed block (432), a pressurizing rod (433) and a sliding barrel (434); the motor (401) is fixedly connected with the bracket (7); the motor (401) is fixedly connected with the fifth transmission shaft (402); the fifth transmission shaft (402) is rotatably connected with the bottom plate assembly (1); the fifth transmission shaft (402) is fixedly connected with the first transmission wheel (201); the fifth transmission shaft (402) is connected with the sixth transmission shaft (403); the sixth transmission shaft (403) is fixedly connected with the third bevel gear (404); the sixth transmission shaft (403) is rotatably connected with the fourth fixing plate (405); the fourth fixing plate (405) is fixedly connected with a second electric push rod (406); the second electric push rod (406) is fixedly connected with the bottom plate component (1); a fourth bevel gear (407) is arranged on the side of the third bevel gear (404); the fourth bevel gear (407) is fixedly connected with the seventh transmission shaft (408); the seventh transmission shaft (408) is rotatably connected with the bottom plate assembly (1); the seventh transmission shaft (408) is fixedly connected with a fifth transmission wheel (409); the fifth driving wheel (409) is in driving connection with the sixth driving wheel (410) through a belt; the sixth driving wheel (410) is fixedly connected with an expansion link (411); the telescopic rod (411) is rotatably connected with the bottom plate component (1); the telescopic rod (411) is fixedly connected with the fourth straight gear (412); the telescopic rod (411) is rotatably connected with the fifth fixing plate (413); the fifth fixing plate (413) is fixedly connected with a third electric push rod (414); the third electric push rod (414) is fixedly connected with the bottom plate component (1); an eighth transmission shaft (415) is arranged on the side part of the fourth straight gear (412); the eighth transmission shaft (415) is rotatably connected with the bottom plate assembly (1); the eighth transmission shaft (415) is fixedly connected with the second fixing frame (416); the second fixed frame (416) is rotationally connected with a ninth transmission shaft (419); the eighth transmission shaft (415) is fixedly connected with a fifth bevel gear (417); the fifth bevel gear (417) is meshed with the sixth bevel gear (418); a sixth bevel gear (418) is fixedly connected with a ninth transmission shaft (419); the ninth transmission shaft (419) is fixedly connected with the second screw rod (420); the second screw rod (420) is rotatably connected with the first fixed block (421); the first fixed block (421) is fixedly connected with the connecting shaft (422); the connecting shaft (422) is connected with the arc-shaped plate (423) in a sliding way; the arc-shaped plate (423) is fixedly connected with the bottom plate component (1); the first fixed block (421) is rotatably connected with the second connecting rod (424) through a rotating shaft; the second connecting rod (424) is rotatably connected with the connecting frame (430); the telescopic rod (411) is fixedly connected with the seventh driving wheel (425); the seventh driving wheel (425) is in transmission connection with the eighth driving wheel (426) through a belt; the eighth driving wheel (426) is fixedly connected with the tenth transmission shaft (427); the tenth transmission shaft (427) is rotatably connected with the bottom plate component (1); the tenth transmission shaft (427) is fixedly connected with the cam rack (428); the cam rack (428) is fixedly connected with the third connecting rod (429); the third connecting rod (429) is rotatably connected with the bottom plate component (1); the cam frame (428) is rotationally connected with the connecting frame (430); the connecting frame (430) is rotatably connected with the second transmission plate (431); the second transmission plate (431) is rotatably connected with the second fixed block (432); the second fixed block (432) is fixedly connected with the pressurizing rod (433); the pressurizing rod (433) is connected with the sliding cylinder (434) in a sliding manner; the sliding cylinder (434) is fixedly connected with the bottom plate component (1).

5. The pressure-regulating fastening processing device for the ultra-precise semiconductor ceramic component as claimed in claim 2, wherein the slide plate (316) is provided with a slide groove matching with the first link (315).

6. The pressure-regulating fastening processing device for the ultra-precise semi-conductor ceramic component as claimed in claim 3, wherein a convex strip is arranged at the joint of the sixth transmission shaft (403) and the fifth transmission shaft (402), and a groove is arranged in the fifth transmission shaft (402).

7. The pressure-regulating fastening processing device for the ultra-precise semi-conductor ceramic component as claimed in claim 3, wherein the eighth transmission shaft (415) is provided with a tooth hole matched with the fourth spur gear (412).

8. The pressure-regulating fastening processing device for the ultra-precise semiconductor ceramic component as claimed in claim 3, wherein the arc-shaped plate (423) is provided with a chute matching with the connecting shaft (422).

Technical Field

The invention relates to the field of inorganic nonmetal, in particular to a pressure regulating and fastening processing device for an ultra-precise semiconductor ceramic component.

Background

Ceramics are general names of pottery and porcelain, and are also an industrial art in China, in the age of new stone, ancient and plain painted pottery and black pottery have been found in China, and ceramic materials are inorganic nonmetallic materials prepared from natural or synthetic compounds through forming and high-temperature sintering, have the advantages of high melting point, high hardness, high wear resistance, oxidation resistance and the like, can be used as structural materials, cutter materials and mould materials, and can be widely applied to various markets as ceramics also have non-conductive performance and can be used as functional materials.

At present, among the prior art, for full user demand, many parts in conductor equipment and the semiconductor product production process can be made by multiple advanced ceramic material, at this in-process, need paint used combined material adhesive at the ceramic part internal surface, will need the part of combination to dock afterwards again, because the inside easy vacuole formation of adhesive, and need great pressure when leading to the extrusion, just can dock, and then lead to very easily damaging ceramic part, and then make the unable bonding of ceramic part firm, thereby lead to influencing later stage product quality, leave the potential safety hazard.

In summary, there is a need to develop a pressure-regulating fastening processing device for ultra-precise semiconductor ceramic components to overcome the above problems.

Disclosure of Invention

In order to overcome the defects that in the prior art, in order to meet the use requirements, many parts in the production process of conductor equipment and semiconductor products can be made of various advanced ceramic materials, in the process, a composite material adhesive needs to be coated on the inner surface of a ceramic part, then the parts needing to be combined are butted, and because a cavity is easily formed in the adhesive, the parts can be butted under high pressure during extrusion, so that the ceramic parts are extremely easy to damage, the ceramic parts cannot be firmly bonded, the quality of the products at the later stage is influenced, and potential safety hazards are left, the invention has the technical problems that: provided is a pressure regulating and fastening processing device for an ultra-precise semiconductor ceramic component.

The technical scheme is as follows: a pressure regulating and fastening processing device for an ultra-precise semiconductor ceramic component comprises a bottom plate assembly, a smearing unit, a bonding unit, a pressure regulating and fastening unit, a control screen, a support column, an anti-skid pad, a collecting box and a handle; the bottom plate component is connected with the smearing unit; the bottom plate assembly is connected with the bonding unit; the bottom plate assembly is connected with the pressure regulating fastening unit; the bottom plate assembly is connected with the support; the bottom plate assembly is connected with the bracket; the bottom plate assembly is connected with the five groups of supporting columns; the bottom plate component is connected with the collecting box; the smearing unit is connected with the bonding unit; the smearing unit is connected with the pressure regulating fastening unit; the pressure regulating fastening unit is connected with the bracket; the control screen is connected with the support; the five groups of supporting columns are connected with the five groups of anti-skid mats; the collecting box is connected with the handle.

In a preferred embodiment of the invention, the smearing unit comprises a first driving wheel, a second driving wheel, a first transmission shaft, a third driving wheel, a fourth driving wheel, a second transmission shaft, a first bevel gear, a second bevel gear, a third transmission shaft, a material tray, a first straight gear, a second straight gear, a third straight gear, an arc-shaped frame, a first electric push rod and an arc-shaped block; the first driving wheel is connected with the pressure regulating fastening unit; the first driving wheel is in transmission connection with the second driving wheel through a belt; the second driving wheel is fixedly connected with the first driving shaft; the first transmission shaft is rotatably connected with the bottom plate assembly; the first transmission shaft is fixedly connected with the third transmission wheel; the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the fourth driving wheel is fixedly connected with the second transmission shaft; the second transmission shaft is rotatably connected with the bottom plate assembly; the second transmission shaft is fixedly connected with the first bevel gear; the first bevel gear is meshed with the second bevel gear; the second bevel gear is fixedly connected with the third transmission shaft; the third transmission shaft is fixedly connected with the material tray; the material tray is connected with the bonding unit; the first transmission shaft is fixedly connected with the first straight gear; the first straight gear is meshed with the second straight gear; the second straight gear is rotationally connected with the bottom plate component through a rotating shaft; the first straight gear is meshed with the third straight gear; the third straight gear is rotationally connected with the bottom plate component through a rotating shaft; the second straight gear is rotationally connected with the arc-shaped frame through a rotating shaft; the third straight gear is rotationally connected with the arc-shaped frame through a rotating shaft; the arc-shaped frame is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the arc-shaped block.

In a preferred embodiment of the present invention, the bonding unit includes a first electric rotary table, a first screw, a first slide block, a first gripper, a first fixing plate, a bearing plate, a second gripper, a second slide block, a second fixing plate, a first electric slide rail, a first fixing frame, a second electric slide rail, a second electric rotary table, a fourth transmission shaft, a first connecting rod, a sliding plate, a first transmission plate, a disc, a bump, a third fixing plate, and a spring rod; the stator of the first electric turntable is fixedly connected with the bottom plate assembly; a rotor of the first electric turntable is fixedly connected with the first screw rod; the first screw rod is rotatably connected with the bottom plate assembly; the first screw rod is in screwed connection with the first sliding block; the first sliding block is fixedly connected with the first mechanical claw; the first sliding block is in sliding connection with the first fixing plate; the first fixing plate is fixedly connected with the bottom plate assembly; the first mechanical claw is fixedly connected with the bearing plate; the bearing plate is rotatably connected with the material tray; the bearing plate is fixedly connected with the second mechanical claw; the second mechanical claw is fixedly connected with the second sliding block; the second sliding block is in sliding connection with the second fixing plate; the second fixing plate is fixedly connected with the bottom plate assembly; a first electric slide rail is arranged on the upper side part of the second fixing plate; the first electric slide rail is fixedly connected with the bottom plate component; the first electric sliding rail is in sliding connection with the first fixing frame; the first fixing frame is in sliding connection with the second electric sliding rail; the second electric slide rail is fixedly connected with the bottom plate component; the first fixing frame is fixedly connected with a stator of the second electric turntable; the rotor of the second electric turntable is fixedly connected with the fourth transmission shaft; the fourth transmission shaft is rotatably connected with the first fixing frame; the fourth transmission shaft is fixedly connected with the first connecting rod; the first connecting rod is in sliding connection with the sliding plate; the sliding plate is fixedly connected with the first driving plate; the first transmission plate is connected with the first fixing frame in a sliding manner; the first driving plate is fixedly connected with the disc; the disc is fixedly connected with the plurality of groups of bumps; the first fixing frame is connected with the multiple groups of spring rods in a sliding manner; the multiple groups of spring rods are fixedly connected with the multiple groups of third fixing plates.

In a preferred embodiment of the present invention, the pressure-regulating fastening unit includes a motor, a fifth transmission shaft, a sixth transmission shaft, a third bevel gear, a fourth fixing plate, a second electric push rod, a fourth bevel gear, a seventh transmission shaft, a fifth transmission wheel, a sixth transmission wheel, a telescopic rod, a fourth spur gear, a fifth fixing plate, a third electric push rod, an eighth transmission shaft, a second fixing frame, a fifth bevel gear, a sixth bevel gear, a ninth transmission shaft, a second screw rod, a first fixing block, a connecting shaft, an arc-shaped plate, a second connecting rod, a seventh transmission wheel, an eighth transmission wheel, a tenth transmission shaft, a cam frame, a third connecting rod, a connecting frame, a second transmission plate, a second fixing block, a pressure rod, and a sliding cylinder; the motor is fixedly connected with the bracket; the motor is fixedly connected with the fifth transmission shaft; the fifth transmission shaft is rotatably connected with the bottom plate assembly; the fifth transmission shaft is fixedly connected with the first transmission wheel; the fifth transmission shaft is connected with the sixth transmission shaft; the sixth transmission shaft is fixedly connected with the third bevel gear; the sixth transmission shaft is rotatably connected with the fourth fixing plate; the fourth fixing plate is fixedly connected with the second electric push rod; the second electric push rod is fixedly connected with the bottom plate component; a fourth bevel gear is arranged on the side part of the third bevel gear; the fourth bevel gear is fixedly connected with the seventh transmission shaft; the seventh transmission shaft is rotatably connected with the bottom plate assembly; the seventh transmission shaft is fixedly connected with the fifth transmission wheel; the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the sixth driving wheel is fixedly connected with the telescopic rod; the telescopic rod is rotatably connected with the bottom plate component; the telescopic rod is fixedly connected with the fourth straight gear; the telescopic rod is rotatably connected with the fifth fixing plate; the fifth fixing plate is fixedly connected with the third electric push rod; the third electric push rod is fixedly connected with the bottom plate component; an eighth transmission shaft is arranged on the side part of the fourth straight gear; the eighth transmission shaft is rotatably connected with the bottom plate assembly; the eighth transmission shaft is fixedly connected with the second fixing frame; the second fixing frame is rotationally connected with the ninth transmission shaft; the eighth transmission shaft is fixedly connected with the fifth bevel gear; the fifth bevel gear is meshed with the sixth bevel gear; the sixth bevel gear is fixedly connected with the ninth transmission shaft; the ninth transmission shaft is fixedly connected with the second screw rod; the second screw rod is connected with the first fixed block in a rotating mode; the first fixed block is fixedly connected with the connecting shaft; the connecting shaft is connected with the arc-shaped plate in a sliding manner; the arc-shaped plate is fixedly connected with the bottom plate component; the first fixed block is rotationally connected with the second connecting rod through a rotating shaft; the second connecting rod is rotatably connected with the connecting frame; the telescopic rod is fixedly connected with the seventh driving wheel; the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the eighth driving wheel is fixedly connected with the tenth transmission shaft; the tenth transmission shaft is rotatably connected with the bottom plate assembly; the tenth transmission shaft is fixedly connected with the cam rack; the cam rack is fixedly connected with the third connecting rod; the third connecting rod is rotatably connected with the bottom plate component; the cam frame is rotationally connected with the connecting frame; the connecting frame is rotationally connected with the second transmission plate; the second transmission plate is rotatably connected with the second fixed block; the second fixed block is fixedly connected with the pressurizing rod; the pressurizing rod is connected with the sliding cylinder in a sliding manner; the sliding cylinder is fixedly connected with the bottom plate component.

In a preferred embodiment of the invention, the slide plate is provided with a sliding groove matched with the first connecting rod.

In a preferred embodiment of the present invention, a protruding strip is disposed at a connection position of the sixth transmission shaft and the fifth transmission shaft, and a groove is disposed in the fifth transmission shaft.

In a preferred embodiment of the present invention, the eighth transmission shaft is provided with a tooth hole matched with the fourth spur gear.

In a preferred embodiment of the invention, the arc-shaped plate is provided with a sliding groove matched with the connecting shaft.

Compared with the prior art, the invention has the beneficial effects that:

one, for solving at present, among the prior art, for full user demand, many parts in conductor equipment and the semiconductor product production process can be made by multiple advanced ceramic material, at this in-process, need paint used composite material adhesive at ceramic member internal surface, the part that will need the combination afterwards docks again, because the inside cavity that easily forms of adhesive, and need great pressure when leading to the extrusion, just can dock, and then lead to very easily damaging ceramic part, and then make ceramic part can't bond firmly, thereby lead to influencing later stage product quality, leave the problem of potential safety hazard.

Secondly, by arranging the smearing unit, the bonding unit and the pressure regulating and fastening unit, when the device is used, the pressure regulating and fastening device for the ultra-precise semiconductor ceramic part is placed at a position to be used, so that the support, the support column and the non-slip mat are kept horizontal, and then the device is externally connected with a power supply and is controlled to start through a control screen on the support; firstly, a worker places a hollow hemispheroid ceramic piece on a smearing unit fixed on a bottom plate assembly, then the smearing unit is used for smearing the composite material adhesive on the inner surface of the ceramic piece uniformly, then, after the hollow hemispheroid ceramic piece is smeared, the adhesive is easy to sink, then, the smearing unit is used for smearing the adhesive on the inner surface of the ceramic piece, then, the bonding unit conveys the ceramic piece smeared with the adhesive to a specified position, meanwhile, the worker places the upper layer hemispheroid ceramic piece in the bonding unit in advance, then, the bonding unit is used for extruding the upper layer ceramic piece into the hollow hemispheroid ceramic piece to prepare the required ceramic piece, then, the bonding unit conveys the prepared ceramic piece to a pressure regulating fastening unit, and then, the pressure regulating fastening unit is used for extruding the ceramic piece, and the pressure during extrusion can be controlled by the pressure regulating fastening unit, so that the hollow hemispheroid ceramic part and the upper layer hemispheroid ceramic part are firmly bonded under the condition of not damaging the ceramic part, and finally, the hollow hemispheroid ceramic part is taken out by a worker and collected in a collecting box, and the collecting box is taken out through a handle and then collected.

Thirdly, the adhesive and the adhesive which is coated and sinks to the bottom are uniformly coated on the inner surface of the ceramic part, then the upper layer ceramic part is extruded into the ceramic part to be manufactured into the required ceramic part, then the ceramic part is extruded to ensure that the ceramic part is firmly bonded, and the pressure during extrusion can be adjusted and controlled, so that the ceramic part is firmly bonded under the condition of not damaging the ceramic part, the product quality is improved, and the potential safety hazard is avoided.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a second perspective view of the present invention;

FIG. 3 is a schematic perspective view of the applying unit according to the present invention;

FIG. 4 is a schematic perspective view of a portion of the applying unit of the present invention;

FIG. 5 is a schematic perspective view of a bonding unit according to the present invention;

FIG. 6 is a schematic perspective view of a first portion of the bonding unit of the present invention;

FIG. 7 is a perspective view of a second portion of the bonding unit of the present invention;

FIG. 8 is a schematic perspective view of the pressure-regulating fastening unit of the present invention;

FIG. 9 is a schematic perspective view of a first portion of the pressure regulating fastening unit of the present invention;

FIG. 10 is a perspective view of a second portion of the pressure regulating fastening unit of the present invention;

fig. 11 is an enlarged view of region B of the present invention.

Wherein the figures include the following reference numerals: 1. a base plate component, 2, an applying unit, 3, a bonding unit, 4, a pressure regulating fastening unit, 5, a control screen, 6, a support, 7, a support, 8, a support column, 9, a non-slip mat, 10, a collecting box, 11, a handle, 201, a first transmission wheel, 202, a second transmission wheel, 203, a first transmission shaft, 204, a third transmission wheel, 205, a fourth transmission wheel, 206, a second transmission shaft, 207, a first bevel gear, 208, a second bevel gear, 209, a third transmission shaft, 210, a material disc, 211, a first straight gear, 212, a second straight gear, 213, a third straight gear, 214, an arc frame, 215, a first electric push rod, 216, an arc block, 301, a first electric rotating disc, 302, a first screw rod, 303, a first sliding block, 304, a first mechanical claw, 305, a first fixing plate, 306, a bearing plate, 307, a second mechanical claw, 308, a second sliding block, 309 and a second fixing plate, 310. 311, a first fixed frame, 312, a second electric sliding rail, 313, a second electric rotating disc, 314, a fourth transmission shaft, 315, a first connecting rod, 316, a sliding plate, 317, a first transmission plate, 318, a disc, 319, a bump, 320, a third fixed plate, 321, a spring rod, 401, a motor, 402, a fifth transmission shaft, 403, a sixth transmission shaft, 404, a third bevel gear, 405, a fourth fixed plate, 406, a second electric pushing rod, 407, a fourth bevel gear, 408, a seventh transmission shaft, 409, a fifth transmission wheel, 410, a sixth transmission wheel, 411, a telescopic rod, 412, a fourth spur gear, 413, a fifth fixed plate, 414, a third electric pushing rod, 415, an eighth transmission shaft, 416, a second fixed frame, 417, a fifth bevel gear, 418, a sixth bevel gear, 419, a ninth transmission shaft, 420, a second screw rod, 421, a first fixed block, 422, a connecting shaft, 423, a second fixed block, a spring rod, The device comprises an arc-shaped plate 424, a second connecting rod 425, a seventh transmission wheel 426, an eighth transmission wheel 427, a tenth transmission shaft 428, a cam rack 429, a third connecting rod 430, a connecting rack 431, a second transmission plate 432, a second fixing block 433, a pressurizing rod 434 and a sliding barrel.

Detailed Description

Although the present invention may be described with respect to particular applications or industries, those skilled in the art will recognize the broader applicability of the invention. Those of ordinary skill in the art will recognize other factors such as: terms such as above, below, upward, downward, and the like are used to describe the accompanying drawings and are not meant to limit the scope of the invention, which is defined by the appended claims. Such as: any numerical designation of first or second, and the like, is merely exemplary and is not intended to limit the scope of the invention in any way.

Example 1

A pressure regulating and fastening processing device for ultra-precise semiconductor ceramic parts is shown in figures 1-11 and comprises a bottom plate component 1, a smearing unit 2, a bonding unit 3, a pressure regulating and fastening unit 4, a control screen 5, a support 6, a support 7, a support column 8, an anti-skid pad 9, a collecting box 10 and a handle 11; the bottom plate component 1 is connected with the smearing unit 2; the bottom plate assembly 1 is connected with the bonding unit 3; the bottom plate component 1 is connected with the pressure regulating fastening unit 4; the bottom plate component 1 is connected with the support 6; the bottom plate component 1 is connected with the bracket 7; the bottom plate component 1 is connected with five groups of supporting columns 8; the bottom plate component 1 is connected with the collecting box 10; the smearing unit 2 is connected with the bonding unit 3; the smearing unit 2 is connected with the pressure regulating fastening unit 4; the pressure regulating fastening unit 4 is connected with the bracket 7; the control screen 5 is connected with the support 6; the five groups of supporting columns 8 are connected with the five groups of anti-skid pads 9; the collecting chamber 10 is connected with a handle 11.

The working steps are as follows: when in use, the voltage-regulating fastening processing device for the ultra-precise semiconductor ceramic part is placed at a position to be used, so that the bracket 7, the supporting column 8 and the anti-skid pad 9 are kept horizontal, and then the device is externally connected with a power supply and is controlled to start through the control screen 5 on the support 6; firstly, a worker places a hollow hemispheroid ceramic piece on a smearing unit 2 fixed on a bottom plate assembly 1, then the smearing unit 2 is used for smearing the composite material adhesive on the inner surface of the ceramic piece uniformly, then, after the hollow hemispheroid ceramic piece is smeared, the adhesive is easy to sink, then, the smearing unit 2 is used for smearing the adhesive on the inner surface of the ceramic piece, then, the adhering unit 3 is used for conveying the ceramic piece smeared with the adhesive to a specified position, meanwhile, the worker places the upper layer hemispheroid ceramic piece in the adhering unit 3 in advance, then, the adhering unit 3 is used for extruding the upper layer ceramic piece into the hollow hemispheroid ceramic piece to prepare a required ceramic piece, and then, the adhering unit 3 is used for conveying the prepared ceramic piece to a pressure regulating and fastening unit 4, then the pressure regulating fastening unit 4 is used for extruding the ceramic component, the pressure regulating fastening unit 4 can be used for controlling the pressure during extrusion, further, under the condition of not damaging the ceramic parts, the ceramic parts in the hollow hemispheroids are firmly bonded with the hemispheroids on the upper layer, and finally taken out by workers and collected in the collecting box 10, then the collecting box 10 is taken out through the handle 11 and then collected, the invention realizes that the used adhesive and the adhesive which is coated and deposited are uniformly coated on the inner surface of the ceramic piece, then, the upper layer ceramic piece is extruded into the ceramic piece to manufacture the required ceramic part, then, the ceramic part is extruded to ensure that the ceramic piece is firmly bonded, the pressure during extrusion can be adjusted and controlled, therefore, under the condition of not damaging the ceramic part, the ceramic part is firmly bonded, the product quality is improved, and the potential safety hazard is avoided.

The smearing unit 2 comprises a first driving wheel 201, a second driving wheel 202, a first driving shaft 203, a third driving wheel 204, a fourth driving wheel 205, a second driving shaft 206, a first bevel gear 207, a second bevel gear 208, a third driving shaft 209, a material tray 210, a first straight gear 211, a second straight gear 212, a third straight gear 213, an arc-shaped frame 214, a first electric push rod 215 and an arc-shaped block 216; the first driving wheel 201 is connected with the pressure regulating fastening unit 4; the first transmission wheel 201 is in transmission connection with a second transmission wheel 202 through a belt; the second driving wheel 202 is fixedly connected with the first driving shaft 203; the first transmission shaft 203 is rotatably connected with the bottom plate component 1; the first transmission shaft 203 is fixedly connected with a third transmission wheel 204; the third driving wheel 204 is in driving connection with a fourth driving wheel 205 through a belt; the fourth transmission wheel 205 is fixedly connected with the second transmission shaft 206; the second transmission shaft 206 is rotatably connected with the bottom plate component 1; the second transmission shaft 206 is fixedly connected with the first bevel gear 207; the first bevel gear 207 is meshed with the second bevel gear 208; the second bevel gear 208 is fixedly connected with a third transmission shaft 209; the third transmission shaft 209 is fixedly connected with the material tray 210; the material tray 210 is connected with the bonding unit 3; the first transmission shaft 203 is fixedly connected with the first straight gear 211; the first spur gear 211 is meshed with the second spur gear 212; the second spur gear 212 is rotatably connected with the base plate assembly 1 through a rotating shaft; the first spur gear 211 is meshed with the third spur gear 213; the third spur gear 213 is rotatably connected with the bottom plate assembly 1 through a rotating shaft; the second spur gear 212 is rotatably connected with the arc-shaped frame 214 through a rotating shaft; the third spur gear 213 is rotatably connected with the arc-shaped frame 214 through a rotating shaft; the arc frame 214 is fixedly connected with a first electric push rod 215; the first electric push rod 215 is fixedly connected with the arc-shaped block 216.

Firstly, a worker places a hollow hemispheroid ceramic piece in a material tray 210, then coats the composite material adhesive on an arc-shaped block 216, then coats the composite material adhesive on the inner surface of the ceramic piece uniformly by using the arc-shaped block 216, a pressure regulating fastening unit 4 operates to drive a first transmission wheel 201 to rotate, the first transmission wheel 201 rotates to drive a second transmission wheel 202 to rotate through a belt, the second transmission wheel 202 rotates to drive a first straight gear 211 to rotate through a first transmission shaft 203, the first straight gear 211 rotates to drive a second straight gear 212 and a third straight gear 213 to rotate simultaneously, all parts on an arc-shaped frame 214 are driven to move, a first electric push rod 215 and the arc-shaped block 216 are driven to move, the composite material adhesive is further coated on the inner surface of the ceramic piece uniformly, and then after the hollow hemispheroid ceramic piece is coated, the adhesive is easy to generate a bottom sinking phenomenon, meanwhile, the bottom sinking adhesive is coated on the inner surface of the ceramic piece, the first transmission shaft 203 rotates to drive the third transmission wheel 204 to rotate, the third transmission wheel 204 rotates to drive the fourth transmission wheel 205 to rotate through a belt, the fourth transmission wheel 205 rotates to drive the first bevel gear 207 to rotate through the second transmission shaft 206, the first bevel gear 207 rotates to drive the second bevel gear 208 to rotate, the second bevel gear 208 rotates to drive the material tray 210 to rotate through the third transmission shaft 209, so that the material tray 210 rotates to drive the hollow hemispheroid ceramic piece to rotate, further the ceramic piece and the arc block 216 rotate simultaneously, the bottom sinking adhesive is coated on the inner surface of the ceramic piece, the coating unit 2 uniformly coats the composite material adhesive on the inner surface of the ceramic piece, and then the hollow hemispheroid ceramic piece is coated, the adhesive is easy to generate bottom sinking phenomenon, and meanwhile, the bottom sinking adhesive is coated on the inner surface of the ceramic piece.

The bonding unit 3 includes a first electric rotary table 301, a first screw 302, a first slider 303, a first gripper 304, a first fixed plate 305, a bearing plate 306, a second gripper 307, a second slider 308, a second fixed plate 309, a first electric slide rail 310, a first fixed frame 311, a second electric slide rail 312, a second electric rotary table 313, a fourth transmission shaft 314, a first link 315, a sliding plate 316, a first transmission plate 317, a disc 318, a bump 319, a third fixed plate 320, and a spring rod 321; the stator of the first electric turntable 301 is fixedly connected with the bottom plate assembly 1; the rotor of the first electric turntable 301 is fixedly connected with a first screw rod 302; the first screw rod 302 is rotatably connected with the bottom plate component 1; the first screw rod 302 is screwed with the first slide block 303; the first sliding block 303 is fixedly connected with the first mechanical claw 304; the first slider 303 is slidably connected to the first fixing plate 305; the first fixing plate 305 is fixedly connected with the base plate assembly 1; the first gripper 304 is fixedly connected with the bearing plate 306; the bearing plate 306 is rotatably connected with the material tray 210; the bearing plate 306 is fixedly connected with the second gripper 307; the second gripper 307 is fixedly connected with the second slide block 308; the second slider 308 is slidably connected to the second fixing plate 309; the second fixing plate 309 is fixedly connected with the bottom plate assembly 1; a first electric slide rail 310 is arranged on the upper side of the second fixing plate 309; the first electric slide rail 310 is fixedly connected with the bottom plate component 1; the first electric slide rail 310 is connected with the first fixing frame 311 in a sliding manner; the first fixing frame 311 is connected with the second electric slide rail 312 in a sliding manner; the second electric slide rail 312 is fixedly connected with the bottom plate component 1; the first fixed frame 311 is fixedly connected with a stator of the second electric turntable 313; the rotor of the second electric turntable 313 is fixedly connected with the fourth transmission shaft 314; the fourth transmission shaft 314 is rotatably connected with the first fixing frame 311; the fourth transmission shaft 314 is fixedly connected with the first connecting rod 315; the first link 315 is slidably connected to the slide plate 316; the slide plate 316 is fixedly connected to the first driving plate 317; the first driving plate 317 is slidably connected to the first fixing frame 311; the first driving plate 317 is fixedly connected with the disc 318; the disc 318 is fixedly connected with a plurality of groups of bumps 319; the first fixing frame 311 is connected with the plurality of groups of spring rods 321 in a sliding manner; the plurality of sets of spring rods 321 are fixedly connected with the plurality of sets of third fixing plates 320.

After the coating unit 2 uniformly coats the composite material adhesive on the inner surface of the ceramic piece, then the worker puts the upper layer of the hemispherical ceramic piece in the first fixing frame 311 in advance, then the bearing plate 306 transfers the ceramic piece coated with the adhesive to the position right under the disc 318, the first electric turntable 301 is started to drive the first screw rod 302 to rotate, the first screw rod 302 rotates to drive the first slide block 303 to move along the first fixing plate 305, the first slide block 303 moves to drive the bearing plate 306 to move to the position right under the disc 318 through the first gripper 304, meanwhile, the bearing plate 306 moves to drive the second gripper 307 to move, the second gripper 307 moves to drive the second slide block 308 to move along the second fixing plate 309, and then the ceramic piece coated with the adhesive is transferred to the position right under the disc 318, at this time, the first electric turntable 301 stops operating, and then, then, a plurality of sets of bumps 319 are used to extrude the hemispherical ceramic piece placed on the upper layer in the first fixing frame 311 into the hollow hemispherical ceramic piece, so as to manufacture the required ceramic component, the first electric slide rail 310 and the second electric slide rail 312 are started to drive the first fixing frame 311 to move, so that the hemispherical ceramic piece in the first fixing frame 311 is placed vertically to the hollow hemispherical ceramic piece, then, the second electric rotary table 313 is started to drive the first connecting rod 315 to rotate through the fourth transmission shaft 314, the first connecting rod 315 rotates to drive the sliding plate 316 to move downwards, the sliding plate 316 moves to drive the first transmission plate 317 to move downwards, so as to drive the disc 318 to move downwards, the disc 318 moves to drive the plurality of sets of bumps 319 to move downwards, so as to extrude the third fixing plate 320, thereby compressing the spring rod 321, and further extrude the hemispherical ceramic piece on the upper layer into the hollow hemispherical ceramic piece, and then the semi-sphere ceramic piece and the hollow semi-sphere ceramic piece are bonded to form a required ceramic part, the bonded ceramic part is conveyed to the pressure regulating and fastening unit 4 by the bearing plate 306 according to the same working principle, the bonding unit 3 conveys the upper semi-sphere ceramic piece to a specified position, the upper ceramic piece is extruded into the hollow semi-sphere ceramic piece, and the required ceramic part is formed, and then the bonded ceramic part is conveyed to the pressure regulating and fastening unit 4.

The pressure regulating fastening unit 4 comprises a motor 401, a fifth transmission shaft 402, a sixth transmission shaft 403, a third bevel gear 404, a fourth fixed plate 405, a second electric push rod 406, a fourth bevel gear 407, a seventh transmission shaft 408, a fifth transmission wheel 409, a sixth transmission wheel 410, an expansion rod 411, a fourth spur gear 412, a fifth fixed plate 413, a third electric push rod 414, an eighth transmission shaft 415, a second fixed frame 416, a fifth bevel gear 417, a sixth bevel gear 418, a ninth transmission shaft 419, a second screw rod 420, a first fixed block 421, a connecting shaft 422, an arc plate 423, a second connecting rod 424, a seventh transmission wheel 425, an eighth transmission wheel 426, a tenth transmission shaft 427, a cam frame 428, a third connecting rod 429, a connecting frame 430, a second transmission plate 431, a second fixed block 432, a pressure rod 433 and a sliding barrel 434; the motor 401 is fixedly connected with the bracket 7; the motor 401 is fixedly connected with the fifth transmission shaft 402; the fifth transmission shaft 402 is rotatably connected with the bottom plate component 1; the fifth transmission shaft 402 is fixedly connected with the first transmission wheel 201; the fifth transmission shaft 402 is connected with the sixth transmission shaft 403; the sixth transmission shaft 403 is fixedly connected with a third bevel gear 404; the sixth transmission shaft 403 is rotatably connected with the fourth fixing plate 405; the fourth fixing plate 405 is fixedly connected with the second electric push rod 406; the second electric push rod 406 is fixedly connected with the bottom plate component 1; a fourth bevel gear 407 is provided at a side of the third bevel gear 404; the fourth bevel gear 407 is fixedly connected with the seventh transmission shaft 408; the seventh transmission shaft 408 is rotatably connected with the bottom plate assembly 1; the seventh transmission shaft 408 is fixedly connected with a fifth transmission wheel 409; the fifth driving wheel 409 is in driving connection with the sixth driving wheel 410 through a belt; the sixth driving wheel 410 is fixedly connected with the telescopic rod 411; the telescopic rod 411 is rotatably connected with the bottom plate component 1; the telescopic rod 411 is fixedly connected with the fourth straight gear 412; the telescopic rod 411 is rotatably connected with the fifth fixing plate 413; the fifth fixing plate 413 is fixedly connected with the third electric push rod 414; the third electric push rod 414 is fixedly connected with the bottom plate component 1; an eighth transmission shaft 415 is provided at a side portion of the fourth spur gear 412; the eighth transmission shaft 415 is rotatably connected with the bottom plate assembly 1; the eighth transmission shaft 415 is fixedly connected with the second fixing frame 416; the second fixed frame 416 is rotatably connected with a ninth transmission shaft 419; the eighth transmission shaft 415 is fixedly connected with a fifth bevel gear 417; fifth bevel gear 417 meshes with sixth bevel gear 418; the sixth bevel gear 418 is fixedly connected with a ninth transmission shaft 419; the ninth transmission shaft 419 is fixedly connected with the second screw rod 420; the second screw rod 420 is rotatably connected with the first fixed block 421; the first fixing block 421 is fixedly connected with the connecting shaft 422; the connecting shaft 422 is connected with the arc plate 423 in a sliding way; the arc-shaped plate 423 is fixedly connected with the bottom plate component 1; the first fixing block 421 is rotatably connected to the second connecting rod 424 through a rotating shaft; the second connecting rod 424 is rotatably connected with the connecting frame 430; the telescopic rod 411 is fixedly connected with the seventh driving wheel 425; the seventh driving wheel 425 is in driving connection with the eighth driving wheel 426 through a belt; the eighth driving wheel 426 is fixedly connected with a tenth transmission shaft 427; the tenth transmission shaft 427 is rotatably connected with the soleplate assembly 1; the tenth transmission shaft 427 is fixedly connected with the cam rack 428; the cam frame 428 is fixedly connected with the third connecting rod 429; the third connecting rod 429 is rotatably connected with the bottom plate component 1; the cam frame 428 is rotatably connected with the connecting frame 430; the connecting frame 430 is rotatably connected with the second transmission plate 431; the second transmission plate 431 is rotatably connected with the second fixed block 432; the second fixed block 432 is fixedly connected with a pressurizing rod 433; the pressurizing rod 433 is connected with the sliding cylinder 434 in a sliding manner; the shuttle 434 is fixedly connected to the base plate assembly 1.

Then, the bonded ceramic parts are conveyed to the position right below the pressure rod 433 by the bonding unit 3, and then the ceramic parts are extruded by the pressure rod 433, so that the ceramic parts in the shape of a hollow hemisphere are firmly bonded with the ceramic parts in the upper layer, the motor 401 is started to drive the fifth transmission shaft 402 to rotate, the fifth transmission shaft 402 rotates to drive the first transmission wheel 201 to rotate, and further the transmission painting unit 2 operates, meanwhile, the fifth transmission shaft 402 rotates to drive the sixth transmission shaft 403 to rotate, the sixth transmission shaft 403 rotates to drive the third bevel gear 404 to rotate, then, the second electric push rod 406 is started to control the sixth transmission shaft 403 to slide through the fourth fixing plate 405, and further the meshing between the third bevel gear 404 and the fourth bevel gear 407 is controlled, when the third bevel gear 404 is meshed with the fourth bevel gear 407, the third bevel gear 404 rotates to drive the fourth bevel gear 407 to rotate, and the fourth bevel gear 407 rotates to drive the fifth transmission wheel 409 to rotate through the seventh transmission shaft 408, the fifth driving wheel 409 rotates to drive the sixth driving wheel 410 to rotate through a belt, the sixth driving wheel 410 rotates to drive the telescopic rod 411 to rotate, the telescopic rod 411 rotates to drive the seventh driving wheel 425 to rotate, the seventh driving wheel 425 rotates to drive the eighth driving wheel 426 to rotate through a belt, the eighth driving wheel 426 rotates to drive the cam frame 428 to rotate through the tenth transmission shaft 427, the cam frame 428 rotates to drive the third connecting rod 429 to rotate, the cam frame 428 rotates to drive the connecting frame 430 to move downwards, the connecting frame 430 moves to drive the second connecting rod 424 to rotate, the connecting frame 430 moves to drive the second driving plate 431 to move downwards, the second driving plate 431 moves to drive the pressurizing rod 433 to slide in the sliding barrel 434 through the second fixing block 432, so as to extrude the ceramic part, so that the hollow hemispherical ceramic part is firmly bonded with the upper hemispherical ceramic part, and the sliding stroke of the pressurizing rod 433 can be controlled by the movement of the first fixing block 421, further controlling the pressure of the pressure rod 433 during extrusion, further making the hollow hemispherical ceramic member firmly adhere to the upper hemispherical ceramic member without damaging the ceramic member, the telescopic rod 411 rotates to drive the fourth spur gear 412 to rotate, then the third electric push rod 414 is started to control the telescopic rod 411 to extend and retract through the fifth fixing plate 413, further controlling the engagement of the fourth spur gear 412 and the toothed hole formed in the eighth transmission shaft 415, when the fourth spur gear 412 is engaged with the toothed hole formed in the eighth transmission shaft 415, the fourth spur gear 412 rotates to drive the eighth transmission shaft 415 to rotate, the eighth transmission shaft 415 rotates to drive the second fixing frame 416 to rotate, the second fixing frame 416 rotates to drive the second lead screw 420 to rotate through the ninth transmission shaft 419, the second lead screw 420 rotates to drive the first fixing block 421 to rotate, further making the first fixing block 421 deflect, and at the same time, the eighth transmission shaft 415 rotates to drive the fifth bevel gear 417 to rotate, the fifth bevel gear 417 rotates to drive the sixth bevel gear 418 to rotate, the sixth bevel gear 418 rotates to drive the second lead screw 420 to rotate through the ninth transmission shaft 419, the second lead screw 420 rotates to drive the first fixing block 421 to move, the first fixing block 421 moves to drive the connecting shaft 422 to slide along the arc plate 423, the first fixing block 421 moves to drive the second connecting rod 424 to rotate through the rotating shaft, so as to adjust and control the sliding stroke of the pressure rod 433, and further control the pressure when the pressure rod 433 extrudes, so that the hollow hemispherical ceramic part and the upper hemispherical ceramic part are firmly bonded without damaging the ceramic part, the pressure-adjusting fastening unit 4 realizes the extrusion of the ceramic part, so that the hollow hemispherical ceramic part and the upper hemispherical ceramic part are firmly bonded, the pressure during extrusion can be adjusted and controlled, so that the hollow hemispherical ceramic piece and the upper hemispherical ceramic piece are firmly bonded under the condition of not damaging the ceramic parts.

Wherein, the sliding plate 316 is provided with a sliding groove matched with the first connecting rod 315.

The first connecting rod 315 can slide in the sliding plate 316, and the sliding plate 316 can be moved.

A convex strip is arranged at the joint of the sixth transmission shaft 403 and the fifth transmission shaft 402, and a groove is arranged in the fifth transmission shaft 402.

The sixth drive shaft 403 can be made to slide in the fifth drive shaft 402 and remain rotating.

Wherein, a tooth hole matched with the fourth spur gear 412 is arranged in the eighth transmission shaft 415.

The eighth transmission shaft 415 and the fourth spur gear 412 can be connected and driven, and can be controlled by the third electric push rod 414 to be switched on and off.

Wherein, the arc plate 423 is provided with a sliding groove matched with the connecting shaft 422.

The coupling shaft 422 can be made to slide in the arc plate 423.

The technical principle of the embodiment of the present invention is described above in conjunction with the specific embodiments. The description is only intended to explain the principles of embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive step, and these embodiments will fall within the scope of the present invention.