CN219378063U - Crushed aggregates detects removing devices and sorting system - Google Patents

Abstract

The utility model provides a crushed aggregates detection and removal device and a separation system, which belong to the field of detection and separation, wherein the device comprises a crushed aggregates detection module, a crushed aggregates removal module, a material streamline and a crushed aggregates detection controller, and the crushed aggregates removal module comprises a crushed aggregates box, a top suction conveying belt group and a material receiving conveying belt group, so that crushed aggregates are trapped and removed; for the complete materials, controlling the top suction conveyor belt to form vacuum by the crushed detection controller, thereby adsorbing and conveying the materials on the tail end of a material streamline below, naturally separating and dropping the materials on the tail end of the top suction conveyor belt to the material receiving conveyor belt, and continuously conveying the complete materials downstream; through this application, can provide the detection in advance and select separately in advance for the separation of sheet material, replace the swing through the top suction to pick the material very big promotion work efficiency and productivity, be convenient for relate to the silicon chip of sheet product, PCB field popularization and application.

Description

Crushed aggregates detects removing devices and sorting system

Technical Field

The utility model belongs to the field of silicon wafer detection and separation, relates to a tailing storage technology, and particularly discloses a crushed aggregates detection and removal device and a separation system.

Background

Silicon wafers are widely used in photovoltaic and semiconductor fields as important industrial raw materials. The quality of the silicon wafer needs to be strictly controlled before the silicon wafer is produced and delivered, so as to ensure the quality of products such as solar cells, circuit boards and the like manufactured by the silicon wafer. The silicon wafer sorting machine is automatic detection and sorting equipment integrating automation, measurement and visual flaw detection, is applied to a solar silicon wafer production process, is a blanking sorting device and a silicon wafer intelligent sorting machine disclosed in patent (publication No. CN 112605010A) applied by China, can realize measurement and detection of thickness, TTV, line mark, resistivity, size, dirt, edge breakage, hidden crack and other items of a solar silicon wafer slice and a cleaned original wafer, automatically sorts the silicon wafer into different boxes according to quality grade requirements according to sorting menus, fully meets the quality control requirements of silicon wafer use factories, and is an indispensable link in production.

At present, broken silicon wafers often exist in a silicon wafer material box, which causes adverse effects on subsequent detection, so that I disclose a crushed aggregates detection and removal device and silicon wafer detection and separation equipment in a patent CN213558494U, which are used for removing fragments before detection so as to ensure stable operation of subsequent procedures. However, the detected chips need to be crushed or not to be oscillated by the oscillating structure when being removed, which severely limits the feeding rate. Therefore, a new type of particle kicking device needs to be designed to meet the current requirements of high efficiency and high productivity.

In order to seek to improve the efficiency of scrap removing more efficiently, the conveying mode, the identification method and other aspects can be considered, and besides belt conveying such as CN213558494U, conveying of wafers by vacuum adsorption can also be considered such as EP2256796A1, CN110540043A and the like, but unlike the conveying, the complete wafers and the fragments are carried out on the same direction streamline plane instead of being staggered up and down, so that the schemes in the two previous patents cannot be simply applied and need to be improved; the recognition method is determined by the efficiency, computational power, etc. of image processing, which is to be subject to the development of image processing technology.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model aims to provide a crushed aggregates detection and removal device and a sorting system, which can solve the problems.

Design principle: the current graphic processing is combined with top suction screening to convey qualified or complete materials, and fragments or unqualified materials are downwards left along with a conventional conveying belt, so that complete material and crushed aggregates are separated, and the sorting efficiency is improved.

The crushed aggregates detection and removal device comprises a crushed aggregates detection module, a crushed aggregates removal module, a material streamline and a crushed aggregates detection controller, wherein the crushed aggregates removal module is arranged at the downstream of the crushed aggregates detection module; the fragment detection module is erected above the material flow line to carry out image detection on materials conveyed on the material flow line; under the control of the crushed material detection controller, the crushed material removing module pre-sorts the materials detected by the crushed material detection module, and removes the crushed materials in a interception way, and sucks the complete materials in a top suction way and transfers the complete materials to the downstream side by a belt.

Furthermore, the crushed aggregates are removed the module and adopt the top to inhale unloading mode, and the top of crushed aggregates removal module inhale unloading direction and the incoming material direction of material streamline crisscross parallel arrangement from top to bottom.

Further, the fragment detection module comprises a detection camera assembly and a bottom light source assembly which are arranged in the detection box frame; the material streamline penetrates through the detection box frame to convey materials; the detection camera component is arranged on the inner side of the top of the detection box frame and is used for collecting images of materials on a lower material flow line; the bottom light source component is arranged below the material streamline and is used for providing a light source for the above material so as to improve the imaging effect of the detection camera component.

Further, the debris detection module further comprises a detection blowing assembly arranged in or before the detection box frame and used for blowing air to the upper surface of the material on the material flow line before debris detection so as to blow away the impurity dust on the surface of the material.

Further, the crushed aggregates removing module comprises a crushed aggregates box, a top suction conveying belt group and a material receiving conveying belt group which are arranged on the removing frame group; the crushed aggregates box sets up the terminal below of material streamline, connect the material conveyer belt group to set up the terminal top of crushed aggregates box, the top is inhaled the conveyer belt group from the top and is spanned the terminal and the setting that connect the conveyer belt group front end of material streamline are hung.

Further, the top suction conveying belt group comprises a belt frame, a conveying belt group, a coupler, a top suction motor, an adsorption assembly, a material sensor and a top suction door frame; the two groups of conveyor belt groups are arranged on two sides of the belt frame and are driven to operate by the coupler and the top suction motor; the adsorption component is arranged in the middle of the belt frame along the streamline transmission direction, and the adsorption bottom surface of the adsorption component is higher than the belt bottom surface of the conveyor belt group, so that separated adsorption belt material transmission is realized; the belt rack and the top suction motor are mounted below the top suction door frame in a hanging manner through the adapter plate; the material inductor is arranged at the front end of the belt rack and is used for inducing whether materials arrive or not.

Further, the material receiving conveyor belt group comprises a material receiving frame, a material receiving belt group, a material receiving end shaft, a material receiving driving belt group, a material receiving motor and a material receiving support column; the material receiving frame is fixed on the eliminating frame group through the material receiving support column; two groups of material receiving belt groups are arranged on two sides of the material receiving frame through material receiving end shafts; the two groups of material band groups are driven by the material receiving driving band group and the material receiving motor to operate and are used for receiving and transmitting the materials falling from the upper top suction conveying band group.

Further, the material streamline comprises a streamline side plate, a streamline transmission belt, a streamline end shaft, a streamline idler wheel, a streamline driving shaft, a streamline motor, a side plate frame and a streamline support; the two streamline side plates are arranged in parallel and have adjustable intervals, and are supported on the streamline support through the side plate frames at two ends; the streamline end shafts are arranged at two ends of the streamline side plates; the streamline transmission belt is supported and installed through the streamline end shaft, the streamline idler pulley and the streamline driving wheel, and is driven and transmitted through the streamline driving shaft and the streamline motor.

Further, the crushed aggregates detects the removing devices still includes ion fan subassembly, ion fan subassembly includes ion fan, fan adaptor and fan frame, ion fan is just to material streamline end arrangement down for remove dust, cooling and destatic to the material that the preliminary examination was accomplished.

The utility model also provides a sorting system, which comprises a feeding device, a detecting device and a discharging sorting device; the crushed aggregates detection and removal device is arranged between the feeding equipment and the detection equipment, the feeding equipment detects the type of the silicon wafer and whether crushing occurs or not through an optical camera and image processing, and the crushed silicon wafer is removed, so that the crushed silicon wafer is prevented from flowing into the detection equipment.

Compared with the prior art, the utility model has the beneficial effects that: through the crushed aggregates detection removing device and the sorting system of this application, can provide detection in advance and presorted for the sorting of sheet material, replace the very big promotion work efficiency and the productivity of swing pick material through the top suction and carry, be convenient for relate to the silicon chip of sheet product, PCB field popularization and application.

Drawings

FIGS. 1-2 are schematic diagrams of a particle detection and removal apparatus of the present utility model;

FIG. 3 is a schematic diagram of a debris detection module;

FIG. 4 is a schematic diagram of a particle reject module;

FIG. 5 is a schematic view of a material flow line;

FIG. 6 is a schematic flow line diagram of material loading, inspection, and culling;

FIG. 7 is a schematic diagram of an intelligent silicon wafer sorting system.

In the figure:

100. a debris detection module;

110. detecting a camera assembly; 111. a camera; 112. a lens; 113. a camera adapter;

120. a bottom light source assembly; 121. a bottom light source; 122. a light source base plate; 123. a light source bottom post; 124. a light source reinforcing member;

130. detecting a box frame; 131. a section bar frame; 132. a door panel assembly; 133. a streamline port;

200. a crushed aggregates removing module;

210. a chaff box; 211. a case body; 212. a magazine rack;

220. a top suction conveying belt group; 221. a belt rack; 222. a conveyor belt group; 223. a coupling; 224. a top suction motor; 225. an adsorption assembly; 226. a material sensor; 227. a top suction portal;

230. a material receiving conveyor belt group; 231. a receiving rack; 232. a material receiving band group; 233. a receiving end shaft; 234. a material receiving driving belt group; 235. a material receiving motor; 236. receiving a material supporting column;

240. removing the frame group;

300. a material streamline; 301. a streamline side plate; 302. a streamline transmission belt; 303. a streamline end shaft; 304. a streamline idler wheel; 305. a streamline drive wheel; 306. a streamlined drive shaft; 307. a streamline motor; 308. side board frame; 309. a streamline support; 310. a streamline material sensor;

400. a machine table;

500. an ion fan assembly; 501. an ion fan; 502. a fan adaptor; 503. a fan frame;

1000. discharging and sorting equipment

2000. A detection device;

3000. and feeding equipment.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. 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.

It should be appreciated that as used in this specification, a "system," "apparatus," "mechanism," "unit" and/or "module" is one method for distinguishing between different components, elements, parts, portions or assemblies at different levels. However, if other words can achieve the same purpose, the words can be replaced by other expressions.

Crushed aggregates detects removing devices

A scrap detection and removal device, see fig. 1 and 2, comprises a scrap detection module 100, a scrap removal module 200, a material flow line 300 and a scrap detection controller.

Arrangement relation: the chip detection module 100, the crushed aggregates removing module 200 and the material streamline 300 are arranged on the machine table 400; the crushed aggregates removing module 200 is arranged downstream of the debris detecting module 100; the chip detection module 100 is erected above the material flow line 300 to perform image detection on the materials conveyed on the material flow line 300; the method is characterized in that: under the control of the crushed material detection controller, the crushed material removing module 200 pre-selects the materials detected by the crushed material detection module 100, intercepts and removes the crushed materials, and sucks the complete materials and transfers the complete materials to the downstream.

Further, the crushed aggregates removing module 200 adopts a top suction and discharging mode, and the top suction and discharging direction of the crushed aggregates removing module 200 is staggered and parallel to the feeding direction of the material streamline 300.

Wherein, referring to fig. 3, the debris detection module 100 includes a detection camera assembly 110 and a bottom light source assembly 120 disposed within a detection case frame 130; the material flow line 300 transports material through the detection box rack 130; the detection camera assembly 110 is arranged on the inner side of the top of the detection box frame 130 and is used for collecting images of materials on the lower material streamline 300; the bottom light source assembly 120 is disposed below the material flow line 300, and is configured to provide a light source for the material above to enhance the imaging effect of the inspection camera assembly 110.

Further, the inspection camera assembly 110 includes a camera 111, a lens 112, and a camera adapter 113, and the camera 111 is connected to an upper portion of the inspection box frame 130 through the camera adapter 113 and captures an image downward.

Further, the bottom light source assembly 120 includes a bottom light source 121, a light source bottom plate 122, a light source bottom column 123 and a light source reinforcement 124, and the bottom light source 121 on the uppermost layer is disposed below the material flow line 300 and provides a light source upwards.

In one example, the light source of the bottom light source assembly 120 employs a surface light source.

Further, the detecting box frame 130 includes a section bar frame 131, a door plate assembly 132, and a streamline opening 133 formed in the material conveying direction; the streamline port 133 is used for the material streamline 300 to penetrate the detection box frame 130 in the material conveying direction so as to convey the material downstream.

Further, the chip detection module 100 further includes a detection blowing assembly (not shown) disposed in or before the detection box frame 130, for blowing air toward the upper surface of the material on the material flow line 300 before chip detection, so as to blow off the dust on the surface of the material.

Referring to fig. 4, the crushed aggregates removing module 200 includes a crushed aggregates box 210, a top suction conveyor belt set 220 and a receiving conveyor belt set 230 arranged on a removing frame set 240; the crushed aggregates box 210 is arranged below the tail end of the material flow line 300, the material receiving conveyer belt group 230 is arranged above the tail end of the crushed aggregates box 210, and the top suction conveyer belt group 220 spans the tail end of the material flow line 300 and the front end of the material receiving conveyer belt group 230 from above.

Further, the particle box 210 includes a box body 211 and a box rack 212 which are disposed in an open and inclined manner.

Further, the top suction conveyor belt set 220 includes a belt rack 221, a conveyor belt set 222, a coupling 223, a top suction motor 224, an adsorption assembly 225, a material sensor 226 and a top suction door frame 227; two groups of conveyor belt groups 222 are arranged on two sides of the belt frame 221 and are driven to run through the coupler 223 and the top suction motor 224; the adsorption component 225 is arranged in the middle of the belt rack 221 along the streamline transmission direction, and the adsorption bottom surface of the adsorption component 225 is higher than the belt bottom surface of the conveyor belt group 222, so that separated adsorption belt material transmission is realized; the belt frame 221 and the top suction motor 224 are suspended and installed below the top suction door frame 227 through an adapter plate; the material sensor 226 is disposed at the front end of the belt frame 221, and is used for sensing whether material arrives.

The belt rack 221 is provided with a suction through hole for installing a suction cup or a suction head of the suction assembly 225.

Each set of conveyor belt sets 222 includes two conveyor end shafts, an end shaft wheel, a plurality of idler wheels, a drive shaft, and a conveyor belt mounted on the end shaft wheel and the plurality of idler wheels.

The output end of the top suction motor 224 is connected with the transmission shaft of the transmission belt group 222 through a coupling 223, so as to drive the belt transmission.

Further, the material receiving conveyer belt group 230 includes a material receiving frame 231, a material receiving belt group 232, a material receiving end shaft 233, a material receiving driving belt group 234, a material receiving motor 235 and a material receiving supporting column 236. The receiving rack 231 is fixed to the reject rack set 240 by the receiving support columns 236; two sets of material receiving band groups 232 are arranged on two sides of the material receiving frame 231 through material receiving end shafts 233; two sets of material take-up belt sets 232 are driven in operation by the material take-up drive belt sets 234 and the material take-up motor 235 to receive and transport material from the upper set 220 of overhead suction conveyor belts.

Wherein, referring to fig. 5, the material flow line 300 comprises a flow line sideboard 301, a flow line conveyor 302, a flow line end shaft 303, a flow line idler 304, a flow line drive wheel 305, a flow line drive shaft 306, a flow line motor 307, sideboard frames 308 and a flow line support 309.

Two streamlined side plates 301 are arranged in parallel and at an adjustable distance and are supported at both ends on the streamlined support 309 by means of the side plate holders 308.

The streamline end shafts 303 are disposed at both ends of the streamline side plate 301.

The streamline conveyor 302 is supportingly mounted by the streamline end shaft 303, streamline idler gear 304 and streamline driving wheel 305, and drives transmission via the streamline driving shaft 306 and streamline motor 307.

The streamlined drive shafts 306 extending through the two sets of edge frames 308 are supported at both ends by bearing frame sets on streamlined supports 309.

The streamlined motor 307 is supported on a streamlined mount 309 by a streamlined motor mount.

An induction mounting groove is formed on the streamline side plate 301 for mounting the streamline material inductor 310.

Further, the crushed aggregates detection and removal device further comprises an ion fan assembly 500, wherein the ion fan assembly 500 comprises an ion fan 501, a fan adapter 502 and a fan frame 503, and the ion fan 501 is downward arranged opposite to the tail end of the material streamline 300 and is used for dedusting, cooling and static removing the material after the pre-detection.

Working principle: the working principle of the crushed aggregates detection and removal device, namely a crushed aggregates detection and removal method, see fig. 6, comprises the following steps:

s1, feeding: material is transported through the material flow line 300.

S2, crushed aggregates detection: whether the material flowing downwards is damaged or not is detected by the chip detection module 100.

S3, removing and sorting: for broken material, directly into the terminal chaff pod 210 via the material flow line 300; for the complete materials, the crushed detection controller controls the top suction conveying belt group 220 to make vacuum, so that the materials on the tail end of the lower material streamline 300 are adsorbed and conveyed, naturally separated and fall onto the material receiving conveying belt group 230 at the tail end of the top suction conveying belt group 220, and the complete materials are continuously conveyed downstream.

In addition, ion blowing is further included between the crushed aggregates detection and the reject sorting, and the ion fan assembly 500 is used for dedusting, cooling and static removing of the materials with the end pre-detection of the material streamline 300.

Through verification, the efficiency of the whole machine is improved by 25% -30% by the top suction sorting mode, and the problems are well solved.

Sorting system

Referring to fig. 7, the intelligent silicon wafer sorting system comprises a feeding device 3000, a detecting device 2000 and a discharging sorting device 1000; the crushed aggregates detection and removal device is arranged between the feeding device 3000 and the detecting device 2000, the feeding device 3000 detects the type of the silicon wafer and whether the silicon wafer is crushed or not through an optical camera and image processing, and the crushed silicon wafer is removed, so that the crushed silicon wafer is prevented from flowing into the detecting device 2000.

Wherein, the blanking sorting equipment 1000 adopts a non-contact adsorption type slicing device, thereby improving the sorting flow efficiency, and the multi-layer staggered material box accommodating device improves the material box replacement efficiency; the detection device 2000 integrates multiple detection, including but not limited to measurement and detection of thickness, TTV, line mark, resistivity, size, dirt, edge breakage, hidden crack, etc., and can increase or decrease detection items in a modularized manner according to actual requirements; the broken materials are removed in advance through the broken material detection and removal device, so that the overall productivity of the system is improved.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (9)

1. The crushed aggregates detection and removal device comprises a crushed aggregates detection module (100), a crushed aggregates removal module (200), a material streamline (300) and a crushed aggregates detection controller, wherein the crushed aggregates removal module (200) is arranged at the downstream of the crushed aggregates detection module (100); the debris detection module (100) is erected above the material streamline (300) to detect images of materials conveyed on the material streamline (300); the method is characterized in that:

the crushed aggregates removing module (200) adopts a top suction and discharging mode, and the top suction and discharging direction of the crushed aggregates removing module (200) and the feeding direction of the material streamline (300) are arranged in a vertically staggered and parallel manner;

the crushed material removing module (200) is used for pre-sorting materials detected by the crushed material detecting module (100) under the control of the crushed material detecting controller, so that crushed materials are trapped and removed, and the whole materials are sucked up and conveyed to the downstream through the belt.

2. The particle detection and removal device of claim 1, wherein: the debris detection module (100) comprises a detection camera assembly (110) and a bottom light source assembly (120) which are arranged in a detection box frame (130); the material streamline (300) penetrates through the detection box frame (130) to convey materials; the detection camera assembly (110) is arranged on the inner side of the top of the detection box frame (130) and is used for collecting images of materials on a lower material streamline (300); the bottom light source assembly (120) is arranged below the material streamline (300) and is used for providing a light source for the above material so as to improve the imaging effect of the detection camera assembly (110).

3. The particle detection and removal device of claim 2, wherein: the debris detection module (100) further comprises a detection blowing component arranged in or before the detection box frame (130) and used for blowing air to the upper surface of the material on the material streamline (300) before debris detection so as to blow off the dust on the surface of the material.

4. The particle detection and removal device of claim 1, wherein: the crushed aggregates removing module (200) comprises crushed aggregates boxes (210), a top suction conveying belt group (220) and a material receiving conveying belt group (230) which are arranged on a removing frame group (240); the crushed aggregates box (210) is arranged below the tail end of the material streamline (300), the material receiving conveyer belt group (230) is arranged above the tail end of the crushed aggregates box (210), and the top suction conveyer belt group (220) spans the tail end of the material streamline (300) and the front end of the material receiving conveyer belt group (230) from above.

5. The particle detection and removal apparatus of claim 4, wherein: the top suction conveying belt set (220) comprises a belt frame (221), a conveying belt set (222), a coupler (223), a top suction motor (224), an adsorption assembly (225), a material sensor (226) and a top suction door frame (227); two groups of conveyor belt groups (222) are arranged on two sides of the belt frame (221) and are driven to operate through the coupler (223) and the top suction motor (224); the adsorption component (225) is arranged in the middle of the belt frame (221) along the streamline transmission direction, and the adsorption bottom surface of the adsorption component (225) is higher than the belt bottom surface of the conveyor belt group (222), so that separated adsorption of the belt for conveying materials is realized; the belt frame (221) and the top suction motor (224) are mounted below the top suction door frame (227) in a hanging manner through an adapter plate; the material sensor (226) is arranged at the front end of the belt rack (221) and is used for sensing whether materials arrive or not.

6. The particle detection and removal apparatus of claim 4, wherein: the material receiving conveyor belt group (230) comprises a material receiving frame (231), a material receiving belt group (232), a material receiving end shaft (233), a material receiving driving belt group (234), a material receiving motor (235) and a material receiving support column (236);

the material receiving rack (231) is fixed to the rejecting rack set (240) through the material receiving support column (236); two groups of material receiving band groups (232) are arranged on two sides of the material receiving frame (231) through material receiving end shafts (233); the two sets of material band groups (232) are driven by the material receiving driving band groups (234) and the material receiving motor (235) to operate so as to receive and transmit the materials falling from the upper top suction conveying band group (220).

7. The particle detection and removal device of claim 1, wherein: the material streamline (300) comprises a streamline side plate (301), a streamline transmission belt (302), a streamline end shaft (303), a streamline idler wheel (304), a streamline driving wheel (305), a streamline driving shaft (306), a streamline motor (307), a side plate frame (308) and a streamline support (309);

two streamline side plates (301) are arranged in parallel and with adjustable space and are supported on the streamline support (309) through the side plate frames (308) at two ends;

the streamline end shafts (303) are arranged at two ends of the streamline side plate (301);

the streamline transmission belt (302) is supported and installed through the streamline end shaft (303), the streamline idle wheel (304) and the streamline driving wheel (305), and drives and transmits through the streamline driving shaft (306) and the streamline motor (307).

8. The particle detection and removal device of claim 1, wherein: the crushed aggregates detects removing devices and still includes ion fan subassembly (500), ion fan subassembly (500) are including ion fan (501), fan adaptor (502) and fan frame (503), ion fan (501) are to material streamline (300) end arrangement down for remove dust, cooling and destatics to the material that the preliminary examination ended.

9. A sorting system, characterized by: the sorting system comprises a feeding device (3000), a detecting device (2000) and a discharging sorting device (1000); the crushed aggregates detection and removal device according to claim 8 is arranged between the feeding equipment (3000) and the detection equipment (2000), and the feeding equipment (3000) is used for detecting the type of the silicon wafer and whether crushing occurs, so that the crushed silicon wafer is removed and the crushed silicon wafer is prevented from flowing into the detection equipment (2000).