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CN-224230955-U - Dimension measuring equipment for silicon material

CN224230955UCN 224230955 UCN224230955 UCN 224230955UCN-224230955-U

Abstract

The utility model relates to the technical field of silicon material measurement and discloses size measurement equipment for silicon materials, which comprises a base, wherein transmission seats are arranged at the middle two sides of the top of the base, transmission grooves are formed in the middle of the top of each transmission seat, and positive and negative threaded rods are connected in a rotary mode at the middle of the inner side walls of the transmission grooves. According to the utility model, the width ranging sensor, the movable ranging block and the fixed ranging sensor are arranged, each sensor accurately measures and feeds data back to the controller in real time, and the controller performs accurate analysis and processing. In addition, the altitude marks on two sides of the movable ranging block are matched with the ranging rod on the transmission seat, so that the accuracy of altitude measurement is further ensured, the driving motor can be started by one key through the controller, the driving motor drives the driving gear, the driven gear is driven by the driving belt, the positive and negative threaded rods are driven, the automatic movement of the sliding seat is realized, and the position adjustment of the width measuring mechanism is completed.

Inventors

  • WU HUAKAI

Assignees

  • 研索仪器科技(上海)有限公司

Dates

Publication Date
20260512
Application Date
20250319

Claims (7)

  1. 1. The size measurement equipment for the silicon material comprises a base (1), wherein a transmission seat (4) is arranged at the middle positions of the top of the base (1), the size measurement equipment is characterized in that transmission grooves are formed in the middle positions of the top of the transmission seat (4), a front threaded rod (5) is rotatably connected to the middle positions of the inner side walls of the transmission grooves, sliding seats (6) are in threaded connection with the front side and the rear side of the outer side wall of the front threaded rod (5), the sliding seats (6) are distributed in a rectangular array, a placement table (2) is arranged at the middle position of the top of the base (1), a driving block (13) is arranged at the middle position of the rear side wall of the placement table (2), the input end of the front threaded rod (5) penetrates through the inner side wall of the driving block (13) respectively, a driven gear (21) is arranged at the middle positions of the inner side walls of the front threaded rod (5) and the driving block (13), a driving motor (14) is arranged at the middle positions of the inner side walls of the driving block (13), an output end of the driving motor (14) penetrates through the inner side walls of the driving block (13) and is connected with a driving gear (20), the driven gear (21) is arranged in parallel to the driving gear (20) and the driving gear (20), the width ranging mechanisms are arranged at the middle positions of the tops of the sliding seats (6).
  2. 2. The dimension measuring equipment for silicon materials of claim 1, wherein the width measuring mechanisms are distributed in a rectangular array, the width measuring mechanisms comprise electric telescopic seats (7), the electric telescopic seats (7) are arranged at the middle positions of the tops of the corresponding sliding seats (6), adjusting seats (8) are arranged at the middle positions of the tops of the electric telescopic seats (7), mounting blocks (19) are respectively arranged at the middle positions of the front side wall and the rear side wall of each adjusting seat (8), and width measuring sensors (16) are respectively arranged at the two side walls of each mounting block (19).
  3. 3. The dimension measuring device for silicon materials according to claim 2, wherein the adjusting seats (8) are provided with adjusting grooves (9) at the middle positions of the tops, sliding blocks (10) are connected to the inner side walls of the adjusting grooves (9) in a sliding mode, and top plates (11) are arranged on the tops of the sliding blocks (10).
  4. 4. A dimension measuring device for silicon materials according to claim 3 is characterized in that a cylinder (12) is arranged at the middle position of the top plate (11), the output end of the cylinder (12) penetrates through the middle position of the bottom of the top plate (11), and a movable distance measuring block (15) is connected to the output end of the cylinder (12).
  5. 5. A dimension measuring device for silicon materials according to claim 4 wherein a fixed distance measuring sensor (3) is installed at the middle rear side of the top of the placing table (2), and the fixed distance measuring sensor (3) is electrically connected with a movable distance measuring block (15).
  6. 6. The dimension measuring equipment for silicon materials according to claim 5, wherein the height marks (18) are arranged at the middle positions of the bottoms of the two side walls of the movable distance measuring block (15), the distance measuring rule (17) is respectively arranged at the middle two sides of the top of the transmission seat (4), movable grooves are respectively formed in the two side walls of the distance measuring rule (17), and the other ends of the height marks (18) penetrate through and are movably connected to the inner side walls of the corresponding movable grooves.
  7. 7. The dimension measuring equipment for silicon materials according to claim 5, wherein a controller (23) is arranged near the front side in the middle of one side wall of the base (1), and the controller (23) is electrically connected with the air cylinder (12), the driving motor (14), the electric telescopic seat (7), the width ranging sensor (16), the movable ranging block (15) and the fixed ranging sensor (3) respectively.

Description

Dimension measuring equipment for silicon material Technical Field The utility model relates to the technical field of silicon material measurement, in particular to size measurement equipment for a silicon material. Background In the current silicon material production and processing industry, accurate measurement of the size of the silicon material plays a vital role in ensuring the quality of products and improving the production efficiency. However, the existing silicon material size measurement technology has a plurality of problems, and the development of the industry is severely restricted. First, the existing equipment has low degree of automation. Most existing devices rely on manual operation, and in the measurement process, an operator needs to manually adjust the position of a measuring tool, and record measurement data. The method is time-consuming and labor-consuming, has low working efficiency, and is easy to cause deviation of measurement results due to the influence of human factors such as fatigue of operators, technical proficiency difference and the like, so that the stability of product quality is affected. Furthermore, the application range is narrow. The traditional measuring device is relatively fixed in structure, and the position and size adjustment range of the measuring component is limited. This makes them only capable of measuring silicon materials of a specific size range, and if it is desired to measure width and height simultaneously, no effective measurement can be made. Accordingly, a size measuring apparatus for silicon materials is provided by those skilled in the art to solve the problems described above. Disclosure of utility model The utility model aims to solve the defects in the prior art, and provides a dimension measuring device for a silicon material, which provides the following technical scheme for realizing the purposes: the automatic distance measuring device comprises a base, the transmission seat is all installed to the top intermediate position of base, the transmission groove has all been seted up to the top intermediate position of transmission seat, and the inside wall intermediate position of transmission groove all rotates and is connected with positive and negative threaded rod, the lateral wall front side and the equal threaded connection of rear side position of positive and negative threaded rod have the slide, the slide becomes rectangular array and distributes, place the platform is installed to the top intermediate position of base, place the back lateral wall intermediate position of platform and install the drive block, positive and negative threaded rod's input runs through respectively and the inside wall of drive block, positive and negative threaded rod's input just is located the inside wall both sides position of drive block and all installs driven gear, driving motor's rear side wall intermediate position is installed to driving motor's output runs through the inside wall of drive block and is connected with the driving gear, driven gear and driving gear are parallel distribution, driven gear and driving gear's lateral wall cover are equipped with the drive belt, width range finding mechanism is all installed to the top intermediate position of slide, and width range finding mechanism includes electric telescopic seat, regulating seat, installation piece and width range finding sensor. The electric telescopic seat can be adjusted in height according to the height of the silicon material, and the adjusting seat is adjusted to a proper height position. The width ranging sensors arranged on the two side walls of the mounting block start to measure the width of the silicon material and feed back measurement data to the controller. Preferably, the electric telescopic seat can be adjusted in height according to the height of the silicon material, and the adjusting seat is adjusted to a proper height position. The width ranging sensors arranged on the two side walls of the mounting block start to measure the width of the silicon material and feed back measurement data to the controller. Preferably, the adjusting seat moves under the action of the sliding seat, the sliding block moves in the corresponding adjusting groove, the top of the sliding block is respectively connected to the four corners of the bottom of the top plate in a sliding manner, so that the position of the top plate is not affected in the moving process, and the clamping piece and the like can not be affected. Preferably, the controller controls the cylinder to act, and the output end of the cylinder pushes the movable ranging block to move downwards. Preferably, when the movable ranging block contacts the top of the silicon material, data between the movable ranging block and the fixed ranging sensor is changed, the height of the silicon material is calculated through the change of the distance between the movable ranging block and the fixed ranging sensor, and the measured