阅读说明：本技术 一种集成光电子器件加工系统 (Integrated photoelectronic device processing system ) 是由 郭丽华 于 2021-07-08 设计创作，主要内容包括：本发明涉及光电子器件技术领域,更具体的说是一种集成光电子器件加工系统,一种集成光电子器件加工系统,对原料进行运输,将原料加工成为光敏电阻,将光敏电阻放置在光敏电阻加工装置上,通过改变光照来对光敏电阻进行检测,根据检测结果改变光敏电阻的收集位置,将光敏电阻的管脚剪短,通过检测结果确定的收集位置将光敏电阻收集,能对光敏电阻进行检测后区分收集。(The invention relates to the technical field of optoelectronic devices, in particular to an integrated optoelectronic device processing system which is used for transporting raw materials, processing the raw materials into a photoresistor, placing the photoresistor on a photoresistor processing device, detecting the photoresistor by changing illumination, changing the collecting position of the photoresistor according to the detection result, cutting the base pin of the photoresistor, collecting the photoresistor through the collecting position determined by the detection result, and detecting and distinguishing the photoresistor.)

1. An integrated optoelectronic device processing system, comprising: the raw materials are transported, the raw materials are processed into the photoresistors, the photoresistors are placed on the photoresistors processing device, the photoresistors are detected by changing illumination, the collecting positions of the photoresistors are changed according to detection results, pins of the photoresistors are cut short, and the photoresistors are collected through the collecting positions determined by the detection results.

2. An integrated optoelectronic device processing system as claimed in claim 1 wherein: the system also comprises the photoresistor processing device, the photoresistor processing device comprises a foot cutting knife (110), pressing plates (130), a connecting frame (140) and a sliding rod (150), the foot cutting knife (110) is fixed on the sliding rod (150), the two pressing plates (130) are fixed on the connecting frame (140), and the sliding rod (150) slides on the connecting frame (140).

3. An integrated optoelectronic device processing system as claimed in claim 2 wherein: the photoresistor processing device further comprises a blocking plate (120), wherein a cutter groove (121) is formed in the blocking plate (120), and the positions of the foot cutter (110) and the cutter groove (121) are horizontal.

4. An integrated optoelectronic device processing system as claimed in claim 3 wherein: the photoresistor processing device further comprises supporting plates (160), conveying belts (170) and rotating shafts (180), the rotating shafts (180) are all rotated on the two supporting plates (160), and the two conveying belts (170) are in friction transmission with the rotating shafts (180) respectively.

5. An integrated optoelectronic device processing system as claimed in claim 4 wherein: the two conveyer belts (170) are provided with grooves, and the grooves on the two conveyer belts (170) are one third circular.

6. An integrated optoelectronic device processing system as claimed in claim 5 wherein: the photoresistor processing device further comprises a collecting plate (210), a groove rod (220) and a driving rod (230), wherein the collecting plate (210) rotates on the two supporting plates (160), the groove rod (220) is fixed on the collecting plate (210), and the driving rod (230) slides in the groove rod (220).

7. An integrated optoelectronic device processing system as claimed in claim 6 wherein: the photoresistor processing device further comprises a limiting block (240) and a cam (290), wherein the limiting block (240) is fixed on the driving rod (230), and the cam (290) and the limiting block (240) are in friction transmission.

8. An integrated optoelectronic device processing system as claimed in claim 7 wherein: the photoresistor processing device further comprises clamping blocks (250) and moving plates (260), the limiting blocks (240) and the two clamping blocks (250) are in friction transmission, and the two clamping blocks (250) slide on the two moving plates (260) respectively.

9. An integrated optoelectronic device processing system as claimed in claim 8 wherein: the photoresistance processing device further comprises a driving assembly (280) which is provided with two driving assemblies (280), wherein one driving assembly (280) consists of an electric telescopic rod (281), two rotating rods (282) and a connecting rod (283), and the other driving assembly (280) consists of two rotating rods (282), a connecting rod (283) and an electric telescopic rod II (284).

10. An integrated optoelectronic device processing system as claimed in claim 9 wherein: the photoresistor processing device further comprises a light shield (310) and a lamp (330), wherein the light shield (310) is fixed on the two supporting plates (160), the lamp (330) is fixed on the supporting plate (160) at the right end, and the lamp (330) is located in the light shield (310).

Technical Field

The invention relates to the technical field of optoelectronic devices, in particular to an integrated optoelectronic device processing system.

Background

For example, the integrated optoelectronic device processing equipment disclosed in publication No. 208542618U comprises a box body and a transmission belt, wherein an inlet is formed in the surface of the box body, an outlet is formed in the surface of the box body, an electronic device circuit board is movably connected to the surface of the transmission belt, a cavity is formed in the box body, a supporting plate is fixedly connected to the inner wall of the box body, a baffle is formed in the surface of the supporting plate, a dust collection pipe is fixedly connected to the surfaces of the baffle and the supporting plate, and one end of the dust collection pipe is fixedly communicated with the inner wall of the cavity; the disadvantage of this patent is that the photoresistor cannot be detected and then collected differentially.

Disclosure of Invention

The invention aims to provide an integrated optoelectronic device processing system which can detect and distinguish and collect photoresistors.

The purpose of the invention is realized by the following technical scheme:

the utility model provides an integrated optoelectronic device processing system, the staff puts the photo resistance on photo resistance processingequipment, photo resistance processingequipment establishes ties photo resistance and a gear motor, put photo resistance in the dark space, come to detect photo resistance through shining of light, change the track position through gear motor's behavior to this makes qualified photo resistance and unqualified photo resistance separately collected, comes to detect photo resistance, cuts the foot to photo resistance at last.

The photo resistance processingequipment includes the foot sword of cutting, the barrier plate, the pressure strip, the link, the slide bar, a supporting plate, transportation area and axis of rotation, foot sword sliding connection is in two backup pads, foot sword fixed connection is on the slide bar, barrier plate fixed connection is in the backup pad of left end, be equipped with the sword groove on the barrier plate, sword groove position corresponds with foot sword level of cutting, two equal fixed connection of pressure strip are on the link, slide bar sliding connection is on the link, be equipped with the spring between link and the slide bar, a plurality of axis of rotation rotate respectively and connect in two backup pads, two transportation areas respectively with a plurality of axis of rotation friction transmission, all be equipped with convex groove on two transportation areas, fixed connection between two axis of rotation of front end.

The photoresistor processing device comprises a collecting plate, a groove rod, a driving rod, a limiting block and a cam, wherein the collecting plate is rotatably connected to two supporting plates, the groove rod is fixedly connected to the collecting plate, the driving rod is connected to the groove rod in a sliding mode, the limiting block is fixedly connected to the driving rod, and friction transmission is conducted between the cam and the limiting block.

The photoresistance processing device comprises clamping blocks, moving plates, a support frame, driving components, a light shield, a rotating door and a lamp, wherein a driving rod is connected on the support frame in a sliding manner, a cam is connected on the support frame in a rotating manner, the two clamping blocks are in a right trapezoid shape, the two clamping blocks are respectively connected on the two moving plates in a sliding manner, the two clamping blocks are respectively connected with the two moving plates through springs, the two moving plates are respectively connected on the support frame in a sliding manner, two driving components are arranged, one driving component comprises an electric telescopic rod, two rotating rods and a connecting rod, the other driving component comprises two rotating rods, a connecting rod and an electric telescopic rod II, the electric telescopic rod and the electric telescopic rod II are respectively fixedly connected on the support frame, the two connecting rods are respectively fixedly connected on the electric telescopic rod and the electric telescopic rod II, and the rotating rods are respectively connected on the two moving plates in a rotating manner, a plurality of dwang rotate respectively and connect on two connecting rods, and lens hood fixed connection is in two backup pads, and two revolving doors articulate both ends around the lens hood respectively, and two revolving doors all pass through torsional spring coupling with the lens hood, and support frame fixed connection is in two backup pads, and lamps and lanterns fixed connection is in one of them backup pad, and lamps and lanterns are located inside the lens hood.

The photoresistor processing device comprises a movable frame and a smearing brush, the movable frame is fixedly connected to a connecting rod at the upper end, the smearing brush is fixedly connected to the movable frame, and the movable frame is located in a light shield.

The integrated photoelectronic device processing system has the beneficial effects that:

the integrated optoelectronic device processing system can cut the pin of the photoresistor, fix the pin before cutting the pin of the photoresistor to avoid the pin position moving, improve the accuracy of cutting the pin, can distinguish and place the photoresistor with faults detected, can detect the photoresistor, divide the photoresistor with faults detected into two types of photoresistors with high resistance value which is not reduced when meeting light and low resistance value which is not increased, and mark the photoresistor with low resistance value which is not increased, so that a worker can distinguish the photoresistors with two faults, and the worker can classify, check and process the photoresistors with two faults.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of an integrated optoelectronic device processing system of the present invention;

FIG. 2 is a schematic diagram of a pin cutter of the photoresistor processing device of the present invention;

FIG. 3 is a schematic view of a support plate of the photoresistor processing device of the present invention;

FIG. 4 is a schematic view of a conveyor belt of the photoresistor processing apparatus of the present invention;

FIG. 5 is a schematic view of a collecting plate of the photoresistor processing device of the present invention;

FIG. 6 is a schematic diagram of a limiting block of the photoresistor processing device of the present invention;

FIG. 7 is a schematic view of a pressing plate of the photoresistor processing device of the present invention;

FIG. 8 is a schematic view of a clamping block of the photoresistor machining apparatus of the present invention;

FIG. 9 is a schematic view of a driving assembly of the photoresistor processing device of the present invention;

FIG. 10 is a schematic view of a light shield of the photoresistor processing device of the present invention;

fig. 11 is a schematic view of an application brush of the photoresistor processing device of the present invention.

In the figure: a foot cutter 110; a blocking plate 120; a compression plate 130; a connection frame 140; a slide bar 150; a support plate 160; a conveyor belt 170; a rotating shaft 180; a collection plate 210; a slot bar 220; a drive rod 230; a stopper 240; a clamping block 250; a moving plate 260; a support bracket 270; a drive assembly 280; a cam 290; a light shield 310; a rotating door 320; a lamp 330; a moving frame 340; a daubing brush 350.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in figure 1 of the drawings, in which,

an integrated optoelectronic device processing system, comprising: the staff puts the photo resistance on photo resistance processingequipment, photo resistance processingequipment establishes ties photo resistance and a gear motor, puts the photo resistance in the space of no light, detects the photo resistance through shining of light, changes the track position through gear motor's behavior to this makes qualified photo resistance and unqualified photo resistance separately collected, comes to detect the photo resistance, cuts the foot to the photo resistance at last.

As shown in figures 2, 3 and 4,

the integrated photoelectronic device processing system also includes a photoresistor processing device, which comprises a foot cutter 110, a barrier plate 120, a pressing plate 130 and a connecting frame 140, the foot cutting device comprises a sliding rod 150, supporting plates 160, conveying belts 170 and rotating shafts 180, wherein the foot cutting knife 110 is connected to the two supporting plates 160 in a sliding mode, the foot cutting knife 110 is fixedly connected to the sliding rod 150, a blocking plate 120 is fixedly connected to the supporting plate 160 at the left end, a knife groove 121 is formed in the blocking plate 120, the position of the knife groove 121 corresponds to the position of the foot cutting knife 110 horizontally, two pressing plates 130 are fixedly connected to a connecting frame 140, the sliding rod 150 is connected to the connecting frame 140 in a sliding mode, springs are arranged between the connecting frame 140 and the sliding rod 150, a plurality of rotating shafts 180 are respectively connected to the two supporting plates 160 in a rotating mode, the two conveying belts 170 are respectively in friction transmission with the plurality of rotating shafts 180, arc-shaped grooves are formed in the two conveying belts 170, and the two rotating shafts 180 at the front end are fixedly connected;

the sliding rod 150 is driven by external power, the external power selects a hydraulic cylinder which is fixedly connected to the supporting plate 160 at the right end, the sliding rod 150 is fixedly connected to the hydraulic cylinder, the rotating shaft 180 at the left end of the front end is driven by the external power, the external power selects a speed reducing motor which is fixedly connected to the supporting plate 160 at the left end, and one rotating shaft 180 at the left end of the front end is fixedly connected to an output shaft of the speed reducing motor;

the device can cut the pins of the photoresistor, the photoresistor stops moving after moving to the position of the pin cutter 110, at the moment, the hydraulic cylinder extends to drive the sliding rod 150 to move, the sliding rod 150 moves to drive the connecting frame 140 to move, the connecting frame 140 moves to drive the two pressing plates 130 to move, the two pressing plates 130 move and contact with the two pins of the photoresistor, and the two pins of the photoresistor are pressed on the supporting plate 160, so that the two pins are prevented from being bent when the two pins of the photoresistor are cut, the two pins of the photoresistor can not be normally cut by the pin cutter 110, defective goods which fail to cut after the cutting of the pin cutter 110 are avoided, and the two pins are fixed through the two pressing plates 130 and the supporting plate 160, in order to guarantee that can not change at two pin positions of foot knife 110 in cutting process, slide bar 150 continues to move afterwards, make two pressure strip 130 fully fix two pins through his compression spring, slide bar 150 continues to move and drives foot knife 110 and continues to move, foot knife 110 continues to move and cuts off two pins, make two pin length of photo resistance be required length, be equipped with sword groove 121 on the barrier plate 120 simultaneously, make foot knife 110 continue to move and get into sword groove 121 in, can effectively avoid foot knife 110 to be insufficient to the cutting of pin, cause the condition of disconnected foot and photo resistance adhesion, avoid still needing to carry out secondary treatment, thereby improve work efficiency and shorten process time.

As shown in figures 5 and 6 of the drawings,

the photoresistor processing device comprises a collecting plate 210, a grooved rod 220, a driving rod 230, a limiting block 240 and a cam 290, wherein the collecting plate 210 is rotatably connected to two supporting plates 160, the grooved rod 220 is fixedly connected to the collecting plate 210, the driving rod 230 is slidably connected to the grooved rod 220, the limiting block 240 is fixedly connected to the driving rod 230, and the cam 290 and the limiting block 240 are in friction transmission;

this device can distinguish the photo resistance who detects out the trouble and place, cam 290 rotates and drives stopper 240 and remove when photo resistance is normal, stopper 240 removes and drives actuating lever 230 and removes, actuating lever 230 removes and drives channel bar 220 and rotates, channel bar 220 rotates and drives collecting plate 210 and rotates, at this moment the normal photo resistance's that collecting plate 210 below corresponds collecting box, cam 290 can not rotate when the photo resistance that breaks down, at this moment the photo resistance's of the trouble that collecting plate 210 below corresponds collecting box, accomplish the differentiation to two kinds of photo resistance with this and collect, make good photo resistance and bad photo resistance directly by the separation, and distinguish automatically, need not the manpower and sort, manpower and material resources are saved, photo resistance's machining efficiency has greatly been improved.

As shown in figures 7, 8, 9 and 10,

the photoresistor processing device comprises clamping blocks 250, moving plates 260, a support frame 270, driving assemblies 280, a light shield 310, a rotating door 320 and a lamp 330, wherein a driving rod 230 is connected to the support frame 270 in a sliding manner, a cam 290 is connected to the support frame 270 in a rotating manner, the two clamping blocks 250 are both in a right trapezoid shape, the two clamping blocks 250 are respectively connected to the two moving plates 260 in a sliding manner, the two clamping blocks 250 are respectively connected to the two moving plates 260 through springs, the two moving plates 260 are both connected to the support frame 270 in a sliding manner, the two driving assemblies 280 are arranged, one driving assembly 280 comprises an electric telescopic rod 281, two rotating rods 282 and a connecting rod 283, the other driving assembly 280 comprises two rotating rods 282, a connecting rod 283 and an electric telescopic rod II 284, the electric telescopic rod 281 and the electric telescopic rod II 284 are both fixedly connected to the support frame 270, and the two connecting rods 283 are respectively fixedly connected to the electric telescopic rod 281 and the electric telescopic rod II 284, the plurality of rotating rods 282 are respectively and rotatably connected to the two moving plates 260, the plurality of rotating rods 282 are respectively and rotatably connected to the two connecting rods 283, the light shield 310 is fixedly connected to the two support plates 160, the two rotating doors 320 are respectively hinged to the front end and the rear end of the light shield 310, the two rotating doors 320 are both connected with the light shield 310 through torsion springs, the support frame 270 is fixedly connected to the two support plates 160, the lamp 330 is fixedly connected to one of the support plates 160, and the lamp 330 is located inside the light shield 310;

the cam 290 is driven by a speed reducing motor, the speed reducing motor is fixedly connected to the supporting frame 270, the cam 290 is fixedly connected to an output shaft of the speed reducing motor, two power supplies are arranged, the anode of one power supply is connected to the speed reducing motor of the cam 290 through a circuit, the cathode of one power supply is connected to the compression plate 130 at the front end, the compression plate at the rear end is connected to the speed reducing motor of the cam 290 through a circuit, the anode of the other power supply is connected to the electric telescopic rod II 284 through a circuit, the cathode of the other power supply is connected to the compression plate 130 at the front end, and the compression plate at the rear end is connected to the electric telescopic rod II 284 through a circuit;

the device can detect the quality of the processed photoresistor to detect whether the photoresistor has quality problems, and can also distinguish the photoresistor with faults and the qualified photoresistor to place, so that the work personnel can conveniently arrange the photoresistor, manpower and material resources are saved, a power supply is connected with the photoresistor through the two pressing plates 130 and then is connected to the speed reducing motor in series, under the condition of light irradiation, the resistance value of the photoresistor can be reduced, at the moment, the power supply can drive the output shaft of the speed reducing motor to rotate, the output shaft of the speed reducing motor rotates to drive the cam 290 to rotate, the cam 290 rotates to drive the limiting block 240 to move, the limiting block 240 moves to drive the collecting plate 210 to rotate, so that the collecting box of the qualified photoresistor is corresponding to the collecting plate 210, after the limiting block 240 moves, the two clamping blocks 250 are in contact with each other to drive the two clamping blocks 250 to move towards two sides, after the limiting block 240 moves through the two clamping blocks 250, the two clamping blocks 250 are reset through spring force to clamp the limiting block 240, so that the collecting plate 210 is fixed, at the moment, the photoresistor cuts the pins, the photoresistor after completing the pin cutting is transported by the two transport belts 170, the photoresistor falls on the collecting plate 210 and falls into a qualified product collecting box along the collecting plate 210, then the electric telescopic rod 281 is shortened, the electric telescopic rod 281 is shortened to drive the connecting rod 283 at the lower end to move upwards, the connecting rod 283 at the lower end moves upwards to drive the two rotating rods 282 to rotate, the two rotating rods 282 rotate to drive the two moving plates 260 to move towards two sides, the two moving plates 260 lose the limitation on the limiting block 240 after moving towards two sides, the torsion spring force drives the collecting plate 210 to reset, then the electric telescopic rod 281 extends to drive the two moving plates 260 to reset, and the two moving plates 260 drive the two clamping blocks 250 to reset, completing one-time collection of qualified photoresistors;

if the photoresistor fails, the resistance of the photoresistor cannot be reduced when the photoresistor fails and light irradiation occurs after the photoresistor fails, then a power supply and a resistor with a large resistance value are connected in series, so that a speed reduction motor cannot be driven, the cam 290 cannot rotate the collecting plate 210 without rotating, the collecting plate 210 is the collecting box of the photoresistor with the failure, and the photoresistor with the failure slides downwards along the collecting plate 210 to fall into the collecting box of the photoresistor with the failure, so that the collection of the two photoresistors is completed;

further, in order to prevent insufficient light or other external reasons, the photoresistor moves along with the two conveyor belts 170 and then enters the light shield 310, the photoresistor moves and contacts with the rotating door 320 to enter the light shield 310, the rotating door 320 can reset through the elasticity of the torsion spring, so that the photoresistor in the light shield 310 cannot be irradiated by light, and then the resistance value change of the photoresistor is changed by controlling the switch of the lamp 330, so that the detection process of the photoresistor is more stable and precise;

further, in order to make the detection of the photo resistors more sufficient, the photo resistors with faults are divided into two types, one type is that the resistance is not reduced after the photo resistors are irradiated by light, the other type is always at the minimum value, all the photo resistors with faults can not be fully distinguished in the detection process, so that the lamp 330 is turned off, the photo resistors without the photo resistors are secondarily detected, the photo resistors without the photo resistors are connected with the electric telescopic rod II 284 in series through another power supply, at the time, after the first detection is correct, the cam 290 can rotate to drive the collecting plate 210 to rotate, if the resistance value of the photo resistors is increased during the photo resistors without the light irradiation, at the time, the other power supply can not drive the electric telescopic rod II 284 to work, the position of the collecting plate 210 can not be changed, the photo resistors are proved to be normal, the collection of the photo resistors is completed, if the resistance value of the photo resistors is not changed during the photo resistors without the light irradiation, at this moment, another power just can drive electric telescopic handle II 284 and stretch out and draw back, electric telescopic handle II 284 shortens to drive two movable plates 260 and moves to both sides, two movable plates 260 move to both sides and make two clamp tight piece 250 lose the restriction to stopper 240, collecting plate 210 will reset and correspond trouble photo resistance's collecting box again, at this moment photo resistance will fall into trouble photo resistance's collecting box, fully complete photo resistance detects with this, guarantee in the qualified collecting box all qualified photo resistance, the condition of missed-detection can not appear.

As shown in figure 11 of the drawings,

the photoresistor processing device comprises a movable frame 340 and a smearing brush 350, wherein the movable frame 340 is fixedly connected to a connecting rod 283 at the upper end, the smearing brush 350 is fixedly connected to the movable frame 340, and the movable frame 340 is located in the light shield 310;

because the fault conditions of the photoresistors are two types, and the photoresistors with two types of faults both fall into one collection box, in order to facilitate workers to check and process the photoresistors with different faults, the photoresistors with the first type of fault do not have any mark and fall into the faulty collection box, the photoresistors with the second type of fault drive the connecting rods 283 at the upper ends to move downwards when the electric telescopic rod II 284 works, the connecting rods 283 at the upper ends move downwards to drive the moving frame 340 to move downwards, the moving frame 340 moves downwards to drive the smearing brush 350 to move downwards, and the smearing brush 350 moves downwards to brush colors on the photoresistors with the second type of fault as marks, so that the photoresistors with two types of faults are distinguished.