CN220839157U - Assembled machine tool assembly convenient to position and assemble and used for semiconductor processing - Google Patents

Abstract

The utility model discloses an assembled machine tool component for semiconductor processing, which is convenient to position and assemble, and relates to the technical field of machine tool components.

Description

Assembled machine tool assembly convenient to position and assemble and used for semiconductor processing

Technical Field

The utility model relates to the technical field of machine tool components, in particular to an assembled machine tool component convenient to position and assemble and used for semiconductor processing.

Background

The machine tool is a machine for manufacturing machines, plays a great role in modern construction of national economy, and in the technical field of machining, various types of machine tools are involved, such as common milling machines, lathes, planing machines, boring machines, machining centers and the like, the semiconductor refers to a material with conductivity between a conductor and an insulator at normal temperature, and most parts manufactured by the semiconductor material need to be machined by the machine tool.

On the basis, chinese patent publication No. CN207447355U discloses a machine tool, which comprises an operation table and is characterized in that: the automatic clamping device is characterized in that an axle clamp is arranged on the operation table, a disc clamp is further arranged on the operation table along the axial direction of the axle clamp, a tool rest is arranged on the edge of the operation table, the tool rest is located between the axle clamp and the disc clamp and used for carrying out axle machining and disc machining, the operation table further comprises a sliding groove or a sliding rail, and the disc clamp and the axle clamp can move along the sliding groove or the sliding rail. The beneficial effects achieved by the utility model are as follows: the machine tool in this embodiment includes both a disc clamp that can be used for machining disc parts and a shaft clamp that can be used for machining shaft parts, and the tool rest is located between the shaft clamp and the disc clamp, and can be used for machining disc parts in the disc clamp and shaft parts in the shaft clamp, so in this embodiment, machining of disc parts and shaft parts can be achieved simultaneously on one machine tool, the machining steps of parts are simplified, and production efficiency is improved.

However, there are disadvantages in this patent application: traditional assembled lathe subassembly for semiconductor processing generally adopts artifical manual material loading, but to the semiconductor spare part of batch, artifical manual material loading spends time longer, and work efficiency is lower, has reduced the practicality of device.

Disclosure of utility model

The utility model aims to provide an assembled machine tool component for semiconductor processing, which is convenient to position and assemble, and adopts the device to work, so that the problems that the traditional automatic positioning device for metal workpiece processing generally adopts manual feeding in the background, the manual feeding of batches of metal workpieces consumes longer time, the working efficiency is lower, certain deviation is caused in the part feeding process, the processing effect of the part is influenced, and the traditional automatic positioning device for metal workpiece processing cannot automatically position and fix the workpiece, and the workpiece is easy to shift in the processing process, so that the processing effect of the workpiece is influenced are solved.

In order to achieve the above purpose, the technical scheme provided by the utility model is as follows: the utility model provides a convenient assembled lathe subassembly for semiconductor processing of location equipment, includes lathe workstation subassembly and sets up the material loading subassembly in lathe workstation subassembly upper end, and lathe workstation subassembly top surface is provided with locating component, and lathe workstation subassembly upper end is provided with lathe processing subassembly, lathe workstation subassembly top surface is provided with the conveyer belt, and the conveyer belt top surface is provided with semiconductor spare part, and lathe workstation subassembly top surface one side is provided with the backup pad, and lathe workstation subassembly top surface opposite side is provided with the support part, fixedly connected with bracing piece between backup pad and the support part, and support part one side is provided with the pneumatic cylinder, and pneumatic cylinder one end is provided with the sliding block, and the sliding block is connected with the pneumatic cylinder output, and sliding block and bracing piece sliding connection, the sliding block bottom is provided with automatic telescopic link, and automatic telescopic link is provided with two sets of, two sets of automatic telescopic link lower extreme be provided with the fixed plate, and the fixed plate is connected with two sets of automatic telescopic link output, the fixed plate middle part is provided with the sliding chamber.

Preferably, the inner cavity of the sliding cavity is provided with a positive and negative tooth screw rod, one side of the fixed plate is provided with a first motor, and one end of the positive and negative tooth screw rod passes through the fixed plate to be connected with the output end of the first motor.

Preferably, the positive and negative tooth lead screw periphery threaded connection has the slip plate, and the slip plate is provided with two sets of, slip plate and slip cavity groove sliding connection, and slip plate bottom is provided with the grip block.

Preferably, the top of the machine tool workbench assembly is provided with a main cavity groove, two sides of the main cavity groove are provided with first cavity grooves, the first cavity grooves are communicated with the main cavity groove, the bottom of the main cavity groove is provided with a supporting bedplate, a second motor is arranged in an inner cavity in the middle of the supporting bedplate, the top surface of the supporting bedplate is provided with a gear, and the gear is connected with the output end of the second motor.

Preferably, the support platen top surface fixedly connected with stopper, and the stopper is provided with two sets of, and the gear both sides are provided with locating part, and locating part is including setting up the L type sliding plate at support platen top surface, and L type sliding plate sliding connection is inside first chamber groove and main chamber groove, and L type sliding plate bottom is provided with the second chamber groove, and second chamber groove and stopper sliding connection.

Preferably, a rack is arranged on one side of the bottom of the L-shaped sliding plate, the rack is meshed with the gear, a connecting cavity column is arranged at the top of the L-shaped sliding plate, and a clamping plate component is connected to one side of the connecting cavity column in a clamping mode.

Preferably, the upper end of the supporting platen is provided with a processing plate, two sides of the processing plate are fixedly connected with the inner walls of two sides of the main cavity groove, and the connecting cavity column and the clamping plate part are arranged on the top surface of the processing plate.

Compared with the prior art, the utility model has the following beneficial effects:

1. The utility model discloses an assembly type machine tool component for semiconductor processing, which is convenient to position and assemble, an operator places a semiconductor part to be processed on the top surface of a conveyor belt, a hydraulic cylinder is started, the hydraulic cylinder stretches and drives a sliding block and a fixed plate to move to the position right above the semiconductor part, an automatic telescopic rod and a first motor are started, the automatic telescopic rod drives the fixed plate to move downwards, the first motor rotates forwards or reversely to drive a positive and negative screw rod to rotate, the two groups of sliding blocks do opposite or opposite movement at the moment due to the limit fit action of a sliding cavity groove, the distance between the two groups of sliding blocks is adjusted according to the size of the semiconductor part, the two groups of clamping blocks clamp the semiconductor part, the automatic telescopic rod and the hydraulic cylinder are started again after clamping and fixing the semiconductor part, the automatic telescopic rod drives the fixed plate to ascend, the sliding block and the fixed plate are driven to move to the side close to the processing plate, the automatic telescopic rod is started after the fixed plate reaches the position above the processing plate, the semiconductor part contacts the top surface of the processing plate, the first motor rotates, the two groups of sliding blocks are driven to move downwards, the two groups of sliding blocks are enabled to move oppositely or move towards each other, the upper part of the semiconductor part is enabled to be clamped, the manual material is avoided, and the manual material feeding efficiency is prolonged after the two groups of sliding blocks are arranged on the conveyor belt, and the manual material feeding efficiency is improved.

2. The utility model discloses an assembled machine tool component for semiconductor processing, which is convenient to position and assemble, after a semiconductor part falls on the top surface of a processing plate, a second motor is started to drive a gear on the top surface of a mounting plate supporting platen to rotate, as the gear is meshed with a rack, the rack drives two groups of positioning parts to move close to each other, namely, the clamping plate parts are close to each other to clamp the semiconductor part on the top surface of the processing plate, wherein the cooperation of a limiting block and a second cavity groove plays a role in limiting the positioning parts, after the semiconductor part is fixed, the machine tool processing component in a machine tool is started to carry out subsequent processing, after the machine tool processing component finishes the processing of the semiconductor part, the second motor reversely rotates, the two groups of positioning parts are separated, the clamping plate parts are clamped and connected with a connecting cavity column, so that the mounting and the dismounting of the clamping plate parts are convenient, an operator can determine the size of the assembled clamping plate parts according to the size of the semiconductor part, the arrangement not only effectively avoids the displacement of the semiconductor part in the machine tool processing process, ensures the effect of the semiconductor part processing, but also improves the practicability of the device.

Drawings

FIG. 1 is an overall block diagram of the present utility model;

FIG. 2 is a perspective view of a loading assembly of the present utility model;

FIG. 3 is a perspective view of a positioning assembly of the present utility model;

fig. 4 is a cross-sectional view of a support platen of the present utility model.

In the figure: 1. a machine tool table assembly; 11. processing a plate; 12. a conveyor belt; 13. a semiconductor component; 14. a bracket member; 15. a support plate; 16. a main cavity groove; 17. a first cavity groove; 2. a feeding assembly; 21. a hydraulic cylinder; 22. a sliding block; 23. a support rod; 24. a fixing plate; 25. a first motor; 26. a sliding plate; 261. a clamping block; 27. a sliding cavity groove; 28. a positive and negative tooth screw rod; 29. an automatic telescopic rod; 3. a positioning assembly; 31. a support platen; 311. a second motor; 32. a gear; 33. a limiting block; 34. a positioning member; 341. a clamping plate member; 342. connecting the cavity column; 343. an L-shaped sliding plate; 344. a rack; 345. a second cavity groove; 4. and machining the assembly by a machine tool.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

For a further understanding of the present utility model, the present utility model will be described in detail with reference to the drawings.

Referring to fig. 1-2, an assembled machine tool assembly for semiconductor processing convenient for positioning and assembly comprises a machine tool workbench assembly 1 and a feeding assembly 2 arranged at the upper end of the machine tool workbench assembly 1, wherein the top surface of the machine tool workbench assembly 1 is provided with a positioning assembly 3, the upper end of the machine tool workbench assembly 1 is provided with a machine tool processing assembly 4, the top surface of the machine tool workbench assembly 1 is provided with a conveyor belt 12, the top surface of the conveyor belt 12 is provided with a semiconductor part 13, one side of the top surface of the machine tool workbench assembly 1 is provided with a supporting plate 15, the other side of the top surface of the machine tool workbench assembly 1 is provided with a support part 14, a supporting rod 23 is fixedly connected between the supporting plate 15 and the support part 14, one side of the support part 14 is provided with a hydraulic cylinder 21, one end of the hydraulic cylinder 21 is provided with a sliding block 22, the sliding block 22 is connected with the output end of the hydraulic cylinder 21, the sliding block 22 is in sliding connection with the supporting rod 23, the bottom of the sliding block 22 is provided with automatic telescopic rods 29, the automatic telescopic rods 29 are provided with two groups, the lower ends of the automatic telescopic rods 29 of the two groups are provided with a fixing plate 24, the fixing plate 24 is connected with the output ends of the automatic telescopic rods 29 of the two groups, and the sliding block 24 is provided with a sliding cavity 27.

The utility model is further described below with reference to examples.

Example 1

Referring to fig. 1-2, a front and back screw rod 28 is disposed in an inner cavity of the sliding cavity 27, a first motor 25 is disposed on one side of the fixed plate 24, one end of the front and back screw rod 28 passes through the fixed plate 24 and is connected with an output end of the first motor 25, sliding plates 26 are screwed on the periphery of the front and back screw rod 28, two groups of sliding plates 26 are disposed, the sliding plates 26 are slidably connected with the sliding cavity 27, and a clamping block 261 is disposed at the bottom of the sliding plates 26.

Example 2

Referring to fig. 1 and 3-4, a main cavity groove 16 is provided at the top of a machine tool table assembly 1, first cavity grooves 17 are provided at both sides of the main cavity groove 16, the first cavity grooves 17 are communicated with the main cavity groove 16, a supporting platen 31 is provided at the bottom of the main cavity groove 16, a second motor 311 is provided in an inner cavity in the middle of the supporting platen 31, a gear 32 is provided at the top of the supporting platen 31, the gear 32 is connected with an output end of the second motor 311, a limiting block 33 is fixedly connected to the top of the supporting platen 31, the limiting block 33 is provided with two groups, positioning members 34 are provided at both sides of the gear 32, the positioning members 34 comprise L-shaped sliding plates 343 provided at the top of the supporting platen 31, the L-shaped sliding plates 343 are slidably connected in the first cavity grooves 17 and the inside of the main cavity groove 16, a rack 344 is provided at the bottom of the L-shaped sliding plates 343, the rack 344 is engaged with the gear 32, a connecting cavity post 342 is provided at the top of the L-shaped sliding plates 343, a clamping plate member 341 is provided at one side of the connecting cavity post 342, the upper end of the supporting platen 31 is provided with two inner walls 11 and the two side of the processing plate 11 are fixedly connected to the two side of the top of the main cavity groove 11.

To sum up: the utility model discloses an assembled machine tool component for semiconductor processing, which is convenient for positioning and assembling, an operator places a semiconductor part 13 to be processed on the top surface of a conveyor belt 12, a hydraulic cylinder 21 is started, the hydraulic cylinder 21 stretches and stretches to drive a sliding block 22 and a fixed plate 24 to move right above the semiconductor part 13, an automatic telescopic rod 29 and a first motor 25 are started, the automatic telescopic rod 29 drives the fixed plate 24 to move downwards, the first motor 25 rotates forward or backward to drive a positive and negative screw rod 28 to rotate, the two groups of sliding plates 26 move relatively or oppositely at the moment due to the limit fit effect of the sliding plates 26 and a sliding cavity 27, the distance between the sliding plates 26 is adjusted according to the size of the semiconductor part 13, so that two groups of clamping blocks 261 clamp the semiconductor part 13, the automatic telescopic rod 29 and the hydraulic cylinder 21 are started again after the semiconductor part 13 is clamped and fixed, the automatic telescopic rod 29 drives the fixed plate 24 to rise, the 19 pushes the sliding block 22 and the fixed plate 24 to move towards the side close to the processing plate 11, when the fixed plate 24 reaches the upper part of the processing plate 11, the automatic telescopic rod 29 is started, the fixed plate 24 is driven to move downwards by the automatic telescopic rod 29, so that the semiconductor parts 13 are contacted with the top surface of the processing plate 11, the first motor 25 is started, namely the first motor 25 rotates, the two groups of sliding plates 26 are far away from each other, the two groups of clamping blocks 261 release the semiconductor parts 13, the feeding assembly 2 carries out feeding work on the semiconductor parts 13 on the next group of conveyor belts 12, the whole operation of the feeding assembly 2 is automatic and simple, the feeding efficiency is improved, the time consumed by manual feeding is avoided to be longer, after the semiconductor parts 13 fall on the top surface of the processing plate 11, the gear 32 on the top surface of the mounting plate support platen 31 is driven by starting the second motor 311, because the gear 32 is meshed with the rack 344, the rack 344 drives the two groups of positioning components 34 to move close to each other, namely, the clamping plate components 341 are close to each other to clamp the semiconductor component 13 on the top surface of the processing plate 11, wherein the cooperation of the limiting block 33 and the second cavity 345 plays a role in limiting the positioning components 34, after the semiconductor component 13 is fixed, the machine tool processing assembly 4 in the machine tool is started to carry out subsequent processing, after the machine tool processing assembly 4 finishes processing the semiconductor component 13, the second motor 311 reversely rotates, the two groups of positioning components 34 are separated, the clamping plate components 341 are conveniently assembled and disassembled by being clamped and connected with the connecting cavity column 342, an operator can determine the size of the assembled clamping plate components 341 according to the size of the semiconductor component 13, the arrangement not only effectively avoids the displacement of the semiconductor component 13 in the machine tool processing process, ensures the processing effect of the semiconductor component 13, but also improves the practicability of the device.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an assembled lathe subassembly is used in semiconductor processing of convenient location equipment, includes lathe work bench subassembly (1) and sets up material loading subassembly (2) in lathe work bench subassembly (1) upper end, and lathe work bench subassembly (1) top surface is provided with locating component (3), and lathe work bench subassembly (1) upper end is provided with lathe processing subassembly (4), its characterized in that: the utility model provides a lathe workstation subassembly (1) top surface is provided with conveyer belt (12), conveyer belt (12) top surface is provided with semiconductor spare part (13), lathe workstation subassembly (1) top surface one side is provided with backup pad (15), lathe workstation subassembly (1) top surface opposite side is provided with support component (14), fixedly connected with bracing piece (23) between backup pad (15) and support component (14), support component (14) one side is provided with pneumatic cylinder (21), pneumatic cylinder (21) one end is provided with slider (22), slider (22) are connected with pneumatic cylinder (21) output, and slider (22) and bracing piece (23) sliding connection, slider (22) bottom is provided with automatic telescopic link (29), automatic telescopic link (29) are provided with two sets of, two sets of automatic telescopic link (29) lower extreme be provided with fixed plate (24), and fixed plate (24) are connected with two sets of automatic telescopic link (29) output, fixed plate (24) middle part is provided with sliding chamber groove (27).

2. The fabricated machine tool assembly for semiconductor processing that facilitates positioning and assembly as set forth in claim 1, wherein: the inner cavity of the sliding cavity groove (27) is provided with a positive and negative tooth screw rod (28), one side of the fixed plate (24) is provided with a first motor (25), and one end of the positive and negative tooth screw rod (28) penetrates through the fixed plate (24) to be connected with the output end of the first motor (25).

3. The fabricated machine tool assembly for semiconductor processing that facilitates positioning and assembly as set forth in claim 2, wherein: the positive and negative tooth lead screw (28) periphery threaded connection has slip plate (26), and slip plate (26) are provided with two sets of, slip plate (26) and slip cavity groove (27) sliding connection, and slip plate (26) bottom is provided with grip block (261).

4. A fabricated machine tool assembly for semiconductor processing that facilitates positioning and assembly as set forth in claim 3, wherein: the machine tool workbench comprises a machine tool workbench assembly (1), and is characterized in that a main cavity groove (16) is formed in the top of the machine tool workbench assembly (1), first cavity grooves (17) are formed in two sides of the main cavity groove (16), the first cavity grooves (17) are communicated with the main cavity groove (16), a supporting table plate (31) is arranged at the bottom of the main cavity groove (16), a second motor (311) is arranged in an inner cavity in the middle of the supporting table plate (31), a gear (32) is arranged on the top surface of the supporting table plate (31), and the gear (32) is connected with the output end of the second motor (311).

5. The assembled machine tool assembly for semiconductor processing convenient for positioning and assembling as defined in claim 4, wherein: the utility model discloses a support platen, including support platen (31), support platen (31) top surface fixedly connected with stopper (33), and stopper (33) are provided with two sets of, and gear (32) both sides are provided with locating part (34), and locating part (34) are including setting up L type sliding plate (343) at support platen (31) top surface, and L type sliding plate (343) sliding connection is inside first chamber groove (17) and main chamber groove (16), and L type sliding plate (343) bottom is provided with second chamber groove (345), and second chamber groove (345) and stopper (33) sliding connection.

6. The assembled machine tool assembly for semiconductor processing of claim 5, wherein: a rack (344) is arranged on one side of the bottom of the L-shaped sliding plate (343), the rack (344) is connected with the gear (32) in a meshed mode, a connecting cavity column (342) is arranged at the top of the L-shaped sliding plate (343), and a clamping plate component (341) is connected to one side of the connecting cavity column (342) in a clamping mode.

7. The assembled machine tool assembly for semiconductor processing of claim 6, wherein: the upper end of the supporting platen (31) is provided with a processing plate (11), two sides of the processing plate (11) are fixedly connected with inner walls of two sides of the main cavity groove (16), and the connecting cavity column (342) and the clamping plate component (341) are arranged on the top surface of the processing plate (11).