CN211306982U - Automatic stick sticking system for single polycrystalline silicon rod - Google Patents

Abstract

The utility model belongs to the technical field of the silicon rod processing, in particular to automatic stick system that glues of single polycrystalline silicon rod, including viscose platform unit and six robot units. One side of the viscose platform unit is provided with a plate conveying unit and a crystal bar conveying unit; a crystal support conveying unit and a tool conveying unit are arranged on one side, away from the plate conveying unit, of the viscose platform unit; a semi-finished product pressurizing and curing unit is arranged on one side, away from the crystal support conveying unit, of the tool conveying unit; and a finished product tool separation unit and a finished product pressurizing and curing unit are arranged on one side of the plate conveying unit. The utility model discloses promote silicon chip mill automation level, solve and glue excellent automation, comb on-the-spot stream of people, commodity circulation, improve production efficiency, reduce the loss that the human factor caused, reduce the manufacturing cost of enterprise.

Description

Automatic stick sticking system for single polycrystalline silicon rod

Technical Field

The utility model belongs to the technical field of silicon rod processing, specifically speaking relates to an automatic stick system that glues of single polycrystalline silicon stick.

Background

The rod sticking process of the silicon wafer factory is manually completed, the labor intensity and the labor cost are high, the working efficiency is low, unified material management and information tracking are not convenient, and the current situation facing most of the enterprises at present is achieved. In addition, in the process of manually sticking the rod at present, the adhesive tapes are needed to be pasted on the resin plate and the chamfer edge of the crystal rod, so that the problems of waste of glue consumption, different people and poor consistency of the stuck finished rod exist.

SUMMERY OF THE UTILITY MODEL

Aiming at various defects in the prior art, the inventor researches and designs a single-polycrystalline silicon rod automatic sticking system in long-term practice, improves the automation level of a silicon wafer factory, solves the problem of sticking rod automation, combs on-site people flow and logistics, improves the production efficiency, reduces the loss caused by human factors, and reduces the production cost of enterprises.

In order to achieve the above object, the utility model provides a following technical scheme:

an automatic stick sticking system for a single polycrystalline silicon rod comprises a sticking platform unit and a six-axis robot unit. One side of the viscose platform unit is provided with a plate conveying unit and a crystal bar conveying unit; a crystal support conveying unit and a tool conveying unit are arranged on one side, away from the plate conveying unit, of the viscose platform unit; a semi-finished product pressurizing and curing unit is arranged on one side, away from the crystal support conveying unit, of the tool conveying unit; and a finished product tool separation unit and a finished product pressurizing and curing unit are arranged on one side of the plate conveying unit.

Furthermore, the viscose platform unit comprises 2 viscose platforms which are symmetrically arranged at two sides of the viscose rod conveying line; the six-axis robot unit includes 2 six-axis robots; the semi-finished product pressurizing and curing unit comprises two semi-finished product pressurizing and curing devices which are respectively arranged on two sides of the stick rod conveying line.

Further, the finished product tooling separation unit and the finished product pressurizing and curing unit are arranged on two sides of the stick conveying line; and the stick rod conveying line is positioned at one end of the finished product tool separation unit and is provided with a finished product conveying and hoisting unit.

Further, the plate conveying unit comprises a plate transferring device, a plate cache library and a plate conveying line; the plate transferring device is arranged on one side of the plate cache library; and the plate conveying line is provided with a plate conveying and positioning line body and a plate cleaning unit.

Further, the crystal bar conveying unit comprises a crystal bar conveying line, and a crystal bar cleaning unit, a crystal bar transferring unit and a crystal bar positioning unit are arranged on the crystal bar conveying line.

Further, the crystal support conveying unit comprises a crystal support conveying line, and two crystal support grabbing stations are arranged on the crystal support conveying line; and the crystal support grabbing station is provided with a crystal support positioning unit and a crystal support blocking stopping non-return unit.

Further, the tool conveying unit comprises a double-layer speed-multiplying chain conveying unit and a tool conveying and lifting unit; a first tool grabbing station and a second tool grabbing station are arranged on the double-layer speed-multiplying chain conveying unit; and the first tool grabbing station and the second tool grabbing station are respectively provided with a blocking and stopping secondary positioning unit on one side.

Further, the viscose platform comprises a platform frame, and a tool lifting unit, a centering unit and a detection unit are arranged on the platform frame; the tool lifting unit comprises a vertical lifting assembly, a horizontal conveying assembly and a fixing plate; the centering units are fixedly arranged on two sides of the tool lifting unit; the detection unit is located one end of the tool lifting unit and comprises a lifting cylinder and a sensor.

Further, the six-axis robot comprises a robot base assembly arranged at the bottom, a robot body arranged at the top of the robot base assembly, and a robot jig unit arranged on the robot body.

Further, stick excellent system still includes the unit of gluing machine, and the rifle of gluing machine unit is installed on the six-axis robot tool unit.

Further, the semi-finished product pressurizing and curing unit comprises a semi-finished product rack, a semi-finished product shield sleeved outside the semi-finished product rack and a semi-finished product conveying line arranged on the semi-finished product rack; and a semi-finished product pressurizing unit is arranged on the semi-finished product conveying line.

Further, the finished product tooling separation unit comprises a finished product conveying line, a separation platform unit and a truss manipulator unit; the finished product pressurizing and curing unit comprises a finished product rack, a finished product protective cover sleeved outside the finished product rack and a finished product curing conveying line arranged on the finished product rack; and a finished product pressurizing unit is arranged on the finished product curing conveying line.

The utility model has the advantages that:

1) through many conveying units and robot cooperation, the robot snatchs the required stick that glues frock, brilliant support, resin board and crystal bar of stick from each conveying unit, puts again and carries out the viscose on the viscose platform, can realize automatic stick that glues, has improved stick efficiency.

2) Physical information of each crystal bar is input into the control system before being put in storage, so that the state of each crystal bar can be monitored in real time, informatization is realized, the materials can be conveniently traced, read and inquired in the production process, the bar sticking process is automatically controlled, the problem of poor consistency of finished bars caused by human factors can be solved, the precision of the crystal bars is improved, and the production cost of enterprises is reduced.

Drawings

FIG. 1 is a schematic structural view of the stick sticking system of the present invention;

fig. 2 is a schematic structural diagram of the plate conveying unit of the present invention;

FIG. 3 is a schematic structural view of a crystal bar conveying unit according to the present invention;

FIG. 4 is a schematic structural view of the crystal support conveying unit of the present invention;

FIG. 5 is a partial enlarged view of the conveying unit A of the crystal support of the present invention;

fig. 6 is a schematic structural view of the tool conveying unit of the present invention;

fig. 7 is a schematic structural view of the adhesive platform of the present invention;

FIG. 8 is a schematic structural view of the viscose platform viscose rod removing tool of the present invention;

fig. 9 is a schematic structural view of the stick platform tool lifting unit of the present invention;

fig. 10 is a schematic structural view of the six-axis robot of the present invention;

FIG. 11 is a schematic structural view of a semi-finished press curing unit according to the present invention;

FIG. 12 is a schematic structural view of a finished press curing unit of the present invention;

fig. 13 is a schematic structural diagram of the finished product tooling separation unit of the present invention.

In the drawings:

1-a plate conveying unit, 101-a plate conveying positioning line, 102-a plate cleaning unit, 103-a plate cache library and 104-a plate transplanting device;

2-a crystal bar conveying unit, 201-a crystal bar conveying line, 202-a crystal bar cleaning unit, 203-a crystal bar transplanting unit and 204-a crystal bar positioning unit;

3-crystal support conveying unit, 301-crystal support conveying line, 302-first crystal support grabbing station, 303-second crystal support grabbing station, 304-crystal support positioning unit and 305-crystal support blocking stopping check unit;

4-a tool conveying unit, 401-a stopping secondary positioning unit, 402-a first tool grabbing station, 403-a double-layer speed-multiplying chain conveying unit, 404-a second tool grabbing station and 405-a tool conveying and lifting unit;

5-gluing platform, 501-detection unit, 502-gluing rod tool, 503-lifting cylinder, 504-sensor, 505-anti-overflow gluing unit, 506-silicon rod clamping plate, 507-glue blocking plate, 508-tool lifting unit, 5081-horizontal conveying component, 5082-fixing plate, 5083-belt conveyor, 5084-stretching and swinging cylinder component, 5085-belt conveyor fixing seat, 5086-locating pin, 5087-guide column, 5088-stopper, 5089-lifting electric cylinder, 509-vertical lifting component, 510-centering unit and 511-clamping cylinder;

6-six-axis robot, 601-robot jig unit, 602-robot body, 603-robot base assembly;

7-a finished product tool separation unit, 701-a first finished product conveying line, 702-a second finished product conveying line, 703-a finished product silicon rod, 704-a truss manipulator unit and 705-a separation platform unit;

8-a semi-finished product pressurizing and curing unit, 801-a second semi-finished product conveying line, 802-a first semi-finished product conveying line, 803-a semi-finished product pressurizing unit, 804-a semi-finished product protective cover and 805-a semi-finished product rack;

9-a finished product pressurizing and curing unit, 901-a finished product protective cover, 902-a first finished product curing conveying line, 903-a second finished product curing conveying line, 904-a third finished product curing conveying line, 905-a fourth finished product curing conveying line, 906-a finished product rack and 907-a finished product pressurizing unit;

10-a gluing machine unit, 11-a finished product conveying and lifting machine unit and 12-a stick sticking conveying line.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the following description is given with reference to the accompanying drawings of the present invention for clear and complete description of the technical solution of the present invention. Based on the embodiments in the present application, other similar embodiments obtained by persons of ordinary skill in the art without any creative effort shall fall within the protection scope of the present application. In addition, directional terms such as "upper", "lower", "left", "right", etc. in the following embodiments are directions with reference to the drawings only, and thus, the directional terms are used for the purpose of illustrating the present invention and not for the purpose of limiting the same.

The present invention will be further described with reference to the accompanying drawings and preferred embodiments.

Referring to fig. 1, the utility model discloses an automatic stick system that glues of single polycrystalline silicon rod, including viscose platform unit and six robot units. The viscose platform unit includes 2 viscose platforms 5, and the symmetry sets up in gluing excellent transfer chain 12 both sides. Six axis robot cell includes 2 six axis robot 6, sets up respectively on one of them viscose platform 5 one side, conveniently snatchs required component for viscose platform 5. The utility model discloses 6 symmetries of two six robots set up and are gluing excellent transfer chain 12 both sides.

Be equipped with panel conveying unit 1 and crystal bar conveying unit 2 on one side of viscose platform unit, for viscose platform unit provides panel and crystal bar, wait that six robots 6 snatch. Keep away from panel conveying unit 1 one side at viscose platform unit and be equipped with brilliant support conveying unit 3 and frock conveying unit 4, for viscose platform unit provides brilliant support and stick with excellent frock 502, wait that six axis robot 6 snatchs.

Keep away from brilliant support conveying unit 3 one side at frock conveying unit 4 and be equipped with semi-manufactured goods pressurization curing unit 8, semi-manufactured goods pressurization curing unit includes two semi-manufactured goods pressurization curing device, sets up in gluing stick transfer chain 12 both sides.

And a finished product tool separation unit 7 and a finished product pressurizing and curing unit 9 are also arranged on one side of the plate conveying unit 1. The finished product tooling separation unit 7 and the finished product pressure curing unit 9 are arranged at two sides of the stick rod conveying line 12, and a finished product conveying elevator unit 11 is arranged at one end of the stick rod conveying line 12, which is positioned at the finished product tooling separation unit 7, and is used for transferring finished products finished by the finished product pressure curing unit 9 to the finished product tooling separation unit 7.

Example 1

Referring to fig. 2, the plate material conveying unit 1 includes a plate material transfer device 104, a plate material buffer storage 103, and a plate material conveying line. The plate transferring device 104 is arranged beside the plate buffer storage 103, and the conveying line is communicated with an outlet of the plate buffer storage 103. The resin boards are loaded by the board transfer device 104, the resin boards are stored in the board buffer storage 103 in a stack form, and when the resin boards are required to be loaded, the resin boards are output to the conveying line in a pop-up form by the board transfer device 104.

The conveying line is provided with a plate conveying and positioning line body 101 and a plate cleaning unit 102. The plate conveying and positioning line body 101 of the embodiment is provided with two. The needed resin plate firstly passes through the plate cleaning unit 102 on a conveying line, and the two sides of the resin plate to be glued are cleaned through the steps of alcohol solvent spraying, non-woven fabric wheel cleaning, self-cleaning wheel adhesion and static electricity removal and air drying by an ion fan. The static electricity removing function is to prevent the cleaned resin plate from adsorbing dust in a workshop. The resin plate passing through the plate cleaning unit 102 is conveyed to the plate conveying and positioning line 101 to wait for the six-axis robot 6 to grab, and two plate conveying and positioning lines 101 are provided for two sets of six-axis robot units 6 to use independently.

Example 2

Referring to fig. 3, the ingot conveying unit 2 includes an ingot conveying line 201, and an ingot cleaning unit 202, an ingot transferring unit 203, and an ingot positioning unit 204 are provided on the ingot conveying line 201. The crystal bar is firstly clamped by a special jig of the crystal bar transfer unit 203, and then is cleaned by the crystal bar cleaning unit 202, and the steps of spraying an alcohol solvent on a surface to be glued, cleaning a non-woven fabric wheel, adhering a self-cleaning wheel and removing static electricity by an ion fan are included, wherein the static electricity removing function is used for preventing the cleaned crystal bar from adsorbing dust in a workshop. After the crystal bar is cleaned up, the crystal bar is transferred to the crystal bar positioning unit 204 through the crystal bar transferring unit 203, and is secondarily and accurately positioned through the crystal bar positioning unit 204 until the six-axis robot 6 is clamped. Two groups of crystal bar transfer units 203 and two groups of crystal bar positioning units 204 are arranged on the crystal bar conveying line 201 and correspond to the two groups of six-axis robot 6 grabbing stations.

Example 3

Referring to fig. 4 and 5, the crystal support conveying unit 3 includes a crystal support conveying line 301, two crystal support grabbing stations are arranged on the crystal support conveying line 301, and the crystal support grabbing station of the embodiment includes a first crystal support grabbing station 302 and a second crystal support grabbing station 303. Each crystal support grabbing station is provided with a crystal support positioning unit 304 and a crystal support stop returning unit 305 for accurately positioning the crystal support and avoiding sliding in the opposite direction of conveying.

After the crystal support is processed by the water boiling tank, the residual glue is cleaned, the truss manipulator feeds the crystal support conveying line 301, the crystal support conveying line conveys the crystal support to the crystal support grabbing station for positioning, and the six-axis robot 6 is clamped.

Example 4

Referring to fig. 6, the tool conveying unit 4 includes a double-layer speed-multiplying chain conveying unit 403 and a tool conveying lifting unit 405, and the tool conveying lifting unit 405 is disposed at a turn of the two-layer conveying line of the double-layer speed-multiplying chain conveying unit 403 and is used for assisting in lifting the tool on the lower conveying line to the upper conveying line.

The double-layer speed chain conveying unit 403 is provided with a first tool grabbing station 402 and a second tool grabbing station 404, one side of each of the first tool grabbing station 402 and the second tool grabbing station 404 is provided with a blocking and stopping secondary positioning unit 401, and the blocking and stopping secondary positioning unit 401 is composed of a blocking and stopping mechanism and a secondary positioning mechanism and is used for accurately positioning the stick sticking tool and avoiding sliding in the opposite conveying direction.

The tool conveying unit 4 is mainly used for caching, conveying and accurately positioning the stick sticking tool, and the jig of the six-axis robot 6 is clamped to the sticking platform 5. After the stick-sticking tool is cleaned regularly, the truss manipulator feeds the stick-sticking tool to the bottom layer of the double-layer speed chain conveying unit 403, the stick-sticking tool is conveyed to the upper layer by the conveying and lifting unit 405, and the stick-sticking tool moves to the designated first tool grabbing station 402 and the designated second tool grabbing station 404 to wait for being grabbed.

Example 5

Referring to fig. 7, 8 and 9, the adhesive platform 5 includes a platform frame, and the platform frame is provided with a tool lifting unit 508, a centering unit 510 and a detection unit 501. Stick frock 502 can be placed on frock lift unit 508, and frock lift unit 508 is used for bearing stick frock 502 and carries stick frock 502 in horizontal direction and vertical direction.

The centering units 510 are fixedly arranged at two sides of the tool lifting unit 508 and used for centering the crystal support in the stick sticking tool 502. The detection unit 501 is fixedly arranged at one end of the tool lifting unit 508 and is used for positioning the stick sticking tool 502.

Stick excellent frock 502 including base fixed unit and anti-overflow unit 505 of gluing, the brilliant support is placed on base fixed unit to it is fixed as an organic whole with base fixed unit with brilliant support through locking Assembly. The glue overflow preventing units 505 are symmetrically disposed on two sides of the wafer support, and are fixedly connected to the base fixing unit.

The glue overflow preventing unit 505 comprises a silicon rod clamping plate 506 and a glue blocking plate 507. The silicon rod clamping plate 506 and the glue blocking plate 507 are arranged along the length direction of the crystal support, and the silicon rod clamping plate 506 is positioned above the glue blocking plate 507.

Frock lift unit 508 includes vertical lifting unit 509, horizontal transport component 5081 and fixed plate 5082, and fixed plate 5082 sets firmly in platform frame's below, and fixed plate 5082 and platform frame parallel arrangement.

Meanwhile, a mounting opening for the tool lifting unit 508 to penetrate through is formed in the platform frame, and the fixing plate 5082 is fixedly arranged right below the mounting opening. The horizontal transfer module 5081 and the vertical lifting module 509 are respectively fixed above and below the fixing plate 5082, and the horizontal transfer module 5081 is arranged along the length direction of the crystal support.

Specifically, the horizontal conveying assembly 5081 comprises a belt conveyor 5083, a swing cylinder assembly 5084, a belt conveyor holder 5085, a locating pin 5086, a guide column 5087 and a stopper 5088. The belt conveyor fixing base 5085 is fixedly connected with the fixing plate 5082 through the guide column 5087 and is arranged in parallel with the fixing plate 5082. The belt conveyor 5083 and the stopper 5088 are fixedly arranged on the upper surface of the belt conveyor fixing seat 5085, and the belt conveyor 5083 is arranged along the length direction of the crystalline silicon.

In this embodiment, the belt conveyor 5083 includes two parallel timing belts, and the two parallel timing belts are arranged along the length direction of the wafer holder. The stopper 5088 is arranged at one end of the belt conveyor 5083 and used for limiting the stick sticking tool 502. The stretching and swinging cylinder component 5084 comprises a stretching and swinging cylinder and a sleeve, wherein the cylinder body end of the stretching and swinging cylinder is fixedly connected with a fixing plate 5082, and the sleeve is matched with the stretching and swinging cylinder to realize the purpose of locking the crystal support and the base fixing unit.

The locating pin 5086 is vertically and fixedly connected with the fixing plate 5082 through a locating pin cylinder, and the other end of the locating pin 5086 penetrates through the belt conveyor fixing seat 5085 and is used for guiding the belt conveyor fixing seat 5085.

The vertical lifting assembly 509 comprises a lifting electric cylinder 5089, the cylinder end of the lifting electric cylinder 5089 is fixedly connected with a fixing plate 5082, and the piston end of the lifting electric cylinder 5089 penetrates through the fixing plate 5082 and then is fixedly connected with a belt conveyor fixing seat 5085, so as to drive the belt conveyor fixing seat 5085 to ascend and descend, namely, the position of the tool lifting unit 508 is adjusted in the vertical direction.

The detection unit 501 is located at one end of the tool lifting unit 508, and comprises a lifting cylinder 503 and a sensor 504, the lifting cylinder 503 is vertically and fixedly connected with the platform frame, a cylinder body end of the detection cylinder 503 is fixedly connected with the platform frame, and the sensor 504 is fixedly arranged at a piston end of the detection cylinder 503 and used for detecting whether the stick tool 502 is conveyed in place.

In order to prevent the tooling from displacing in the gluing process, a clamping cylinder 511 is arranged on the platform frame and used for clamping the stick-sticking tooling 502, specifically, the clamping cylinder 511 is located on different sides of the tooling lifting unit 508 and is fixedly connected with the platform frame, the cylinder body of the clamping cylinder 511 is arranged along the direction perpendicular to the length direction of the tooling, and the piston end of the clamping cylinder 511 is arranged towards one side close to the tooling lifting unit 508. The piston end of the clamping cylinder 511 positioned at different sides of the tool lifting unit 508 is arranged towards one side of the crystal support and used for clamping the stick sticking tool 502, and after the tool is clamped and positioned, the crystal support and the crystal silicon can be further prevented from displacing in the gluing process.

When the stick sticking platform is used, the method comprises the following two steps:

1) a resin bonding plate:

fixed stick frock 502: the vertical lifting component 509 is started, the tool lifting unit 508 rises, the six-axis robot 6 grabs the stick sticking tool 502 and places the stick sticking tool on the belt conveyor 5083, the belt conveyor 5083 drives the stick sticking tool 502 to move in the horizontal direction, when the stick sticking tool 502 hits the stopper 5088, the detection unit 501 detects that the stick sticking tool 502 is in place, the belt conveyor 5083 stops running immediately, then the tool lifting unit 508 descends, the positioning pin 5086 ascends, and the positioning pin 5086 guides the stick sticking tool 502 and the upper surface of the platform frame to be accurately positioned, the clamping cylinder 511 clamps the stick sticking tool 502 from two sides of the bottom of the stick sticking tool 502, and the tool is ensured not to deviate in the subsequent gluing process.

The air source connected with the stick sticking tool 502 is connected, the driving component of the glue overflow preventing unit 505 is started, the silicon rod clamping plate 506 and the glue blocking plate 507 are opened, the crystal support is placed on the base fixing unit by the six-axis robot 6, the centering unit 510 is started, whether the crystal support is centered or not is detected, the stretching and swinging air cylinder component 5084 operates, the crystal support is locked with the stick sticking tool 502, then glue beating is started, after the glue beating is finished, the resin plate is placed, and the resin plate is bonded with the upper surface of the crystal support. At the moment, the air source connected with the stick sticking tool 502 is disconnected, the glue blocking plate 507 is closed, the resin plate is clamped, at the moment, the clamping cylinder 511 is opened, the stick sticking tool 502 is released, the tool lifting unit 508 rises, the belt conveyor 5083 runs in the reverse direction, the stick sticking tool 502 is sent out of the stick sticking platform, and the work flow of the stick resin plate is completed.

2) Silicon rod sticking:

the operation of fixing the stick sticking tool 502 is repeated, and the stick sticking tool 502 to which the resin plate is stuck is fixed to the platform frame. The air source connected with the stick sticking tool 502 is connected, the driving component of the glue overflow preventing unit 505 is started, the silicon rod clamping plate 506 and the glue blocking plate 507 are opened, glue is applied to the upper surface of the resin plate, after glue application is finished, the crystal rod is placed on the upper surface of the resin plate by the six-axis robot 6, then the air source connected with the stick sticking tool 502 is disconnected, the glue blocking plate 507 and the silicon rod clamping plate 506 are closed, the glue blocking plate 507 clamps the resin plate, the silicon rod clamping plate 506 clamps the square rod, at the moment, the clamping cylinder 511 is opened, the stick sticking tool 502, the tool lifting unit 508 is lifted, the belt conveyor 5083 runs in the reverse direction, the stick sticking tool 502 is sent out of the stick sticking platform to the finished product pressurizing and curing unit, and the work flow of sticking silicon rods is completed.

Example 6

Referring to fig. 10, the six-axis robot unit is mainly used for stick sticking, crystal support, resin plate, crystal bar material grabbing, and gluing track control. The six-axis robot 6 includes a robot base assembly 603 disposed at the bottom, a robot body 602 disposed at the top of the robot base assembly 603, and a robot jig unit 601 disposed on the robot body 602.

Stick system is glued to this embodiment still includes the unit of gluing machine 10, and the rifle of gluing machine unit 10 is installed on six axis robot jig unit 601, and unit of gluing machine 10 is mainly responsible for supplying for the system and glues and accurate measurement, and the gluey rifle of gluing of beating out goes out to glue, and the robot moves according to predetermineeing the orbit when beating the operation of gluing, drives and glues the rifle motion, beats out the gluey of predetermineeing the orbit.

When a six-axis robot is used, the following steps are mainly carried out:

1) grabbing the stick sticking tool to a sticking platform by a tool conveying unit 4;

2) grabbing the crystal support by the crystal support conveying unit 3 to a stick sticking tool in the previous step for positioning and clamping;

3) the glue consumption is accurately measured by a glue dispenser unit 10, and a six-axis robot 6 is used for dispensing resin plate glue to the crystal support according to a preset track;

4) grabbing the resin plate to the surface of the glued crystal support by the plate conveying unit 1, and gluing the resin plate to obtain a semi-finished product;

5) conveying the semi-finished product out of the gluing platform, conveying the semi-finished product to a semi-finished product pressurizing and curing unit 8 through a gluing rod conveying line 12, conveying the semi-finished product to the gluing platform again after pressurizing and curing, accurately metering the glue consumption by a glue dispenser unit, and dispensing glue to the resin plate by a six-axis robot 6 according to a preset track;

6) and grabbing the crystal bar onto the glued resin plate by the crystal bar conveying unit 2 to finish the action of adhering the crystal bar, thereby obtaining a finished product.

Example 7

Referring to fig. 11, the semi-finished product press curing unit 8 includes a semi-finished product rack 805, a semi-finished product shield 804 fitted over the semi-finished product rack 805, and a semi-finished product conveying line provided on the semi-finished product rack 805. The present embodiment semi-finished product transfer line includes a first semi-finished product transfer line 802 and a second semi-finished product transfer line 801. A semi-finished product pressurizing unit 803 is arranged on each semi-finished product conveying line and is used for pressurizing and curing the semi-finished products.

The semi-finished product pressurizing unit 803 comprises a pressurizing cylinder, a stop cylinder and a lifting mechanism, when the semi-finished product is conveyed to the semi-finished product pressurizing unit 803 by a semi-finished product conveying line, the in-place detection device arranged on the semi-finished product conveying line identifies the semi-finished product, the stop cylinder is started, the semi-finished product conveying line stops running, at the moment, the lifting mechanism arranged at the bottom of the semi-finished product pressurizing unit 803 is started to lift the semi-finished product, meanwhile, the pressurizing cylinder arranged at the top of the semi-finished product pressurizing unit 803 is started, the piston end of the cylinder extends downwards, the semi-finished product is pressed downwards until the semi-finished product pressurizing and curing operation is completed, after the semi-finished product pressurizing and curing operation is completed, the piston end of the pressurizing cylinder is lifted, the lifting mechanism descends to place the semi-finished product on the semi-finished.

The semi-finished products are conveyed to the semi-finished product pressurizing and curing unit 8 in a stacking mode through a semi-finished product conveying line for pressurizing and curing, when the semi-finished products are cured to a specified time according to process requirements, the semi-finished products are conveyed to the adhesive platform 5 through the conveying line, and the output sequence of the semi-finished products is the reverse sequence of the semi-finished product pressurizing and curing unit.

Example 8

Referring to fig. 12, the finished product pressure curing unit 9 includes a finished product rack 906, a finished product protective cover 901 covering the finished product rack 906, and a finished product curing conveyor line arranged on the finished product rack 906. The finished product curing conveying line of the embodiment comprises a first finished product curing conveying line 902, a second finished product curing conveying line 903, a third finished product curing conveying line 904 and a fourth finished product curing conveying line 905. A finished product pressurizing unit 907 is provided on each finished product curing conveying line for pressurizing and curing the finished products.

The structure of the finished product pressurizing unit 907 is consistent with that of the semi-finished product pressurizing unit, and the finished product pressurizing unit 907 also comprises a pressurizing cylinder, a stopping cylinder and a lifting mechanism, when a finished product is conveyed to the position of the finished product pressurizing unit 907 by a finished product conveying line, an in-place detection device arranged on the finished product conveying line identifies the finished product, the stopping cylinder is started, the finished product conveying line stops running, at the moment, the lifting mechanism arranged at the bottom of the finished product pressurizing unit 907 is started to lift the finished product, meanwhile, the pressurizing cylinder arranged at the top of the finished product pressurizing unit 907 is started, the piston end of the cylinder extends downwards, the finished product is pressed downwards until the finished product pressurizing and curing operation is completed, after the finished product pressurizing and curing operation is completed, the piston end of the pressurizing cylinder is lifted, the lifting mechanism descends to place the.

And conveying the finished products to a finished product pressurizing and curing unit 9 in a stacking mode through a finished product curing conveying line, pressurizing and curing, conveying the finished products to a finished product tool separating unit 7 through the conveying line when the finished products are cured to a specified time according to the process requirements, wherein the output sequence of the finished products is the reverse sequence of the finished product pressurizing and curing unit.

Example 9

Referring to fig. 13, the finished product tooling separation unit 7 includes a finished product conveyor line, a separation platform unit 705, and a truss robot unit 704. The finished product conveying line of this embodiment includes a first finished product conveying line 701 and a second finished product conveying line 702. The separating platform unit 705 is arranged at the beginning of the finished product conveying line, and the finished product is conveyed to the separating platform unit 705 after being pressurized and solidified. The truss manipulator unit 704 is disposed on top of the separation platform unit 705, and is used for separating the finished silicon rod 703 from the rod sticking tool. The separated rod sticking tool 502 and the separated finished silicon rods 703 are conveyed to the next link through a finished product conveying line, the rod sticking tool 502 is conveyed to the tool conveying unit 4 after glue cleaning, the finished silicon rods 703 are detected, if no glue residue exists, physical information of each silicon rod is stored in the system through the control system, and then the silicon rods are stored in a warehouse, and if the glue residue exists, the silicon rods are firstly cleaned and then stored in the warehouse.

When the automatic stick sticking system is used, firstly, the plate conveying unit 1 conveys the resin plate to a designated position to wait for grabbing, the crystal support conveying unit 3 conveys the crystal support to the designated position to wait for grabbing, and the tool conveying unit 4 conveys the stick sticking tool to the designated position to wait for grabbing; then, the six-axis robot 6 sequentially grabs the sticking rod tool and the crystal support, and after the crystal support is glued, the six-axis robot grabs the resin plate to be stuck with the crystal support to obtain a semi-finished product; then, conveying the semi-finished product to a semi-finished product pressurizing and curing unit, and conveying the semi-finished product to a gluing platform after curing for a specified time according to process requirements; then, the crystal bar conveying unit 2 conveys the crystal bar to a designated position to wait for grabbing, the six-axis robot 6 beats glue on the resin plate, and then the grabbed crystal bar is bonded with the resin plate to obtain a finished product; and conveying the finished product to a finished product pressurizing and curing unit after obtaining the finished product, conveying the finished product to a finished product tool separation unit 7 for separating the rod sticking tool from the crystal rod after curing for a specified time according to process requirements, conveying the rod sticking tool to the tool conveying unit 4 after glue removal after separation, and storing the crystal rod after detecting and glue removal and inputting into a system.

The utility model discloses an automation, the crystal bar informatization of stick are glued to single polycrystal makes things convenient for tracing back, reading, the inquiry of material in the production process.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the scope of the invention, i.e. the present invention is intended to cover all equivalent variations and modifications within the scope of the present invention.

Claims (10)

1. The automatic rod sticking system for the single polycrystalline silicon rod is characterized by comprising a sticking platform unit and a six-axis robot unit; one side of the viscose platform unit is provided with a plate conveying unit (1) and a crystal bar conveying unit (2); a crystal support conveying unit (3) and a tool conveying unit (4) are arranged on one side, away from the plate conveying unit (1), of the viscose platform unit; a semi-finished product pressurizing and curing unit (8) is arranged on one side, away from the crystal support conveying unit (3), of the tool conveying unit (4); and a finished product tool separation unit (7) and a finished product pressurizing and curing unit (9) are arranged on one side of the plate conveying unit (1).

2. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 1, wherein the sticking platform unit comprises 2 sticking platforms (5) symmetrically arranged on two sides of the stick conveying line (12); the six-axis robot unit comprises 2 six-axis robots (6); the semi-finished product pressurizing and curing unit (8) comprises two semi-finished product pressurizing and curing devices which are respectively arranged on two sides of the stick conveying line (12).

3. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 2, wherein the finished product tool separation unit (7) and the finished product pressure curing unit (9) are arranged on two sides of the stick conveying line (12); and the stick rod conveying line (12) is positioned at one end of the finished product tool separation unit (7) and is provided with a finished product conveying and hoisting unit (11).

4. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 1, wherein the plate conveying unit (1) comprises a plate transfer device (104), a plate buffer storage (103) and a plate conveying line; the plate transferring device (104) is arranged on one side of the plate cache library (103); and the plate conveying line is provided with a plate conveying and positioning line body (101) and a plate cleaning unit (102).

5. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 1, wherein the ingot conveying unit (2) comprises an ingot conveying line (201), and an ingot cleaning unit (202), an ingot transferring unit (203) and an ingot positioning unit (204) are arranged on the ingot conveying line (201).

6. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 1, wherein the crystal support conveying unit (3) comprises a crystal support conveying line (301), and two crystal support grabbing stations are arranged on the crystal support conveying line (301); and a crystal support positioning unit (304) and a crystal support stop check unit (305) are arranged on the crystal support grabbing station.

7. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 1, wherein the tool conveying unit (4) comprises a double-layer double-speed chain conveying unit (403) and a tool conveying lifting unit (405); a first tool grabbing station (402) and a second tool grabbing station (404) are arranged on the double-layer speed chain conveying unit (403); and one sides of the first tool grabbing station (402) and the second tool grabbing station (404) are respectively provided with a blocking and stopping secondary positioning unit (401).

8. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 1, wherein the sticking platform (5) comprises a platform frame, and a tool lifting unit (508), a centering unit (510) and a detection unit (501) are arranged on the platform frame; the tool lifting unit (508) comprises a vertical lifting assembly (509), a horizontal conveying assembly (5081) and a fixing plate (5082); the centering unit (510) is fixedly arranged on two sides of the tool lifting unit (508); the detection unit (501) is located at one end of the tool lifting unit (508) and comprises a lifting cylinder (503) and a sensor (504).

9. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 1, wherein the six-axis robot (6) comprises a robot base assembly (603) disposed at the bottom, a robot body (602) disposed at the top of the robot base assembly (603), and a robot jig unit (601) disposed on the robot body (602);

the semi-finished product pressurizing and curing unit (8) comprises a semi-finished product rack (805), a semi-finished product shield (804) sleeved outside the semi-finished product rack (805) and a semi-finished product conveying line arranged on the semi-finished product rack (805); a semi-finished product pressurizing unit (803) is arranged on the semi-finished product conveying line;

stick excellent system still includes hits rubber machine unit (10), hits the rubber gun of gluing machine unit (10) and installs on six robot tool units (601).

10. The automatic stick sticking system for the single polycrystalline silicon rod according to claim 9, wherein the finished product tool separating unit (7) comprises a finished product conveying line, a separating platform unit (705) and a truss manipulator unit (704); the finished product pressurizing and curing unit (9) comprises a finished product rack (906), a finished product protective cover (901) sleeved outside the finished product rack (906) and a finished product curing conveying line arranged on the finished product rack (906); and a finished product pressurizing unit (907) is arranged on the finished product curing conveying line.

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