CN113000406A

CN113000406A - A sorter for qualified appraisal of chip

Info

Publication number: CN113000406A
Application number: CN202110179901.1A
Authority: CN
Inventors: 刘增丰
Original assignee: Dongguan Zhaoyi Information Technology Co ltd
Current assignee: Dongguan Zhaoyi Information Technology Co ltd
Priority date: 2021-02-07
Filing date: 2021-02-07
Publication date: 2021-06-22

Abstract

The invention discloses a classification device for chip qualification, which comprises a detection shell, wherein a transmission cavity is arranged in the detection shell, a bilaterally symmetrical rotating shaft is rotationally arranged on the front end wall of the transmission cavity, a front rotating belt pulley and a rear rotating belt pulley are fixedly arranged on the rotating shaft, the bilaterally symmetrical rotating belt pulleys are connected through a transmission belt, and a fixed block fixedly arranged between the front end wall and the rear end wall of the transmission cavity is arranged between the bilaterally symmetrical rotating belt pulleys.

Description

A sorter for qualified appraisal of chip

Technical Field

The invention relates to the technical field of identification machines, in particular to a sorting device for chip qualification.

Background

The chip at the present stage is developing at a high speed, the shadow of the chip is required in each industry, and some identification chips are mainly used for rapidly identifying the quantity, specification and the like of articles, so that the quantity and the types of the articles are known, and quantity identification errors easily occur when the induction degree of some chips is too high, so that data deviation occurs, but the chips belong to qualified chips capable of being identified when being detected.

The application sets forth a sorter for qualification of chips that can solve the above-mentioned problems.

Disclosure of Invention

Aiming at the defects of the technology, the invention provides a classification device for chip qualification, which can overcome the defects.

The invention discloses a classification device for chip qualification, which comprises a detection shell, wherein a transmission cavity is arranged in the detection shell, a bilaterally symmetrical rotating shaft is rotatably arranged on the front end wall of the transmission cavity, front and back symmetrical rotating belt pulleys are fixedly arranged on the rotating shaft, the bilaterally symmetrical rotating belt pulleys are connected through a transmission belt, and a fixed block fixedly arranged between the front end wall and the back end wall of the transmission cavity is arranged between the bilaterally symmetrical rotating belt pulleys;

thirty-two pushing blocks arranged in an array are fixedly arranged on the periphery of the transmission belt, the pushing blocks on the periphery of the transmission belt are in front-back symmetry and are fixedly connected, sliding cavities with upward openings and left-right symmetry are arranged in the upper end face of the fixed block, a moving block is arranged in the sliding cavities in a sliding mode, a connecting cavity is arranged on the lower side of the moving block, a sliding rack is arranged between the connecting cavity and the sliding cavities in a sliding mode, the upper end of the sliding rack is fixedly connected with the lower end face of the moving block, the lower end of the sliding rack is hinged with a connecting rod, the lower end of the connecting rod is hinged with a connecting block, the front side of the connecting cavity is communicated with the sliding cavity, the connecting block is arranged at the communication position of the sliding cavity and the connecting cavity in a sliding mode, the front end of the connecting block is hinged with;

the sliding cavity upside intercommunication is equipped with the promotion chamber, lower sliding block slidable mounting slide the chamber with promote between the chamber, the sliding block up end has set firmly the linking spring down, linking spring upper end has set firmly last sliding block, it is equipped with the hinge bar to go up the articulated hinge bar in sliding block upper end, the hinge bar upper end is articulated to be equipped with the thrust piece, promote the chamber with the chamber intercommunication slides, fixed spring has set firmly on the preceding terminal surface of rear half of thrust piece, fixed spring front end fixed mounting be in slide in the chamber front end wall.

Preferably, a driven motor is fixedly arranged in the rear end of the transmission cavity, the front end of the driven motor is in power connection with the rear end of the left rotating shaft, a rotating gear with an upward opening is communicated with the inner wall of the upper end of the transmission cavity, a left-right symmetric identification sensor is fixedly arranged in the inner wall of the upper end of the transmission cavity, an isolation plate is fixedly arranged on the lower end face of the left identification sensor, a pressure shaft is rotatably arranged on the right end wall of the communication position of the rotating gear and the transmission cavity, a pressure plate is fixedly arranged on the periphery of the pressure shaft, a connecting spring is fixedly arranged on the right end face of the pressure plate, and the right end of the connecting spring is fixedly arranged in the right end wall of the communication position of the rotating gear and.

Preferably, a belt pulley cavity is arranged at the rear side of the right end wall at the communication part of the rotating gear and the transmission cavity, the rear end of the pressure shaft is rotatably arranged between the communicating part of the rotating gear and the transmission cavity and the belt pulley cavity, a connecting helical gear fixedly arranged on the pressure shaft is arranged in the belt pulley cavity, a connecting helical gear is arranged at the rear side of the connecting helical gear in a meshing connection way, the connecting bevel gear is fixedly arranged on a pulley shaft, the upper end and the lower end of the pulley shaft are respectively and rotatably arranged between the upper end wall and the lower end wall of the pulley cavity, a left connecting belt pulley fixedly arranged on the belt pulley shaft is arranged above the connecting bevel gear, the belt pulley cavity right side is equipped with connects the chamber, the belt pulley right side is connected on a left side is equipped with and is located connect the right side of intracavity and connect the belt pulley, the right side connect the belt pulley with connect the chamber and connect through linking up the belt.

Preferably, the belt pulley fixed mounting is connected on the right side on the connecting axle down, the connecting axle lower extreme rotates to be installed in the connecting chamber lower end wall, the belt pulley upside is connected on the right side is equipped with fixed mounting and is in connecting epaxial connection ratchet group down, connect and to have set firmly the connecting axle on the ratchet group, it rotates to install to go up the connecting axle upper end in the connecting chamber upper end wall, it is equipped with fixed mounting to connect ratchet group upside and is in go up the epaxial rotating gear of connecting, the meshing of rotating gear front side is connected and is equipped with the removal rack, remove rack slidable mounting connect the chamber with between the rotating gear, remove the rack left end and prolong to the rotating gear internal fixation has the slurcam, the slurcam slidable mounting is in the rotating gear.

Preferably, a motor cavity is arranged between the sliding cavities which are bilaterally symmetrical, a connecting motor is fixedly arranged in the upper end wall of the motor cavity, the lower end of the connecting motor is provided with a driving shaft in a power connection mode, a driving helical gear is fixedly arranged on the driving shaft, driven helical gears which are in meshing connection are symmetrically arranged on the left side and the right side of the driving helical gear, the driven helical gears are fixedly arranged on a driven shaft, a supporting plate is fixedly arranged on the lower end wall of the motor cavity, one end, close to the central line of the connecting motor, of the driven shaft is rotatably arranged in the end face of the supporting plate on one side, far away from the central line of the connecting motor, a transmission ratchet set is fixedly arranged on one side, far away from the central line of the connecting motor, of the driven helical gear, the transmission ratchet set is fixedly, and a connecting gear fixedly arranged on the connecting shaft is arranged in the connecting cavity, and the connecting gear is meshed and connected with the sliding rack.

Preferably, the rear side of the sliding cavity is communicated with an opening cavity with a backward opening, the rear end face of the opening cavity on the right side is provided with a movable plate in a sliding installation manner, the upper end face of the movable plate is internally provided with a blocking groove with an upward opening, a blocking block is rotatably installed between the left end wall and the right end wall of the blocking groove, the rear end face of the blocking block is fixedly provided with a compression spring, the lower end of the compression spring is fixedly installed on the lower end wall of the blocking groove, the rear side of the blocking groove is provided with a penetrating cavity positioned in the movable plate, the penetrating cavity penetrates through the upper end face and the lower end face of the movable plate, the upper end wall of the opening cavity on the rear side is fixedly provided with a marking block, the lower end face of the movable plate is fixedly provided with a connecting rack, the lower end of the opening cavity on the right side is communicated, the transmission gear is fixedly arranged on a gear shaft, the right end of the gear shaft is rotatably arranged in the right end wall of the gear cavity, the left side of the transmission gear is provided with a linking ratchet group fixedly arranged on the gear shaft, the left end of the linking ratchet group is fixedly arranged with an output shaft, the left end of the output shaft is rotatably arranged in the left end wall of the gear cavity, the left side of the linking ratchet group is provided with an output belt pulley fixedly arranged on the output shaft, the rear side of the output belt pulley is provided with a transmission belt pulley, the transmission belt pulley is connected with the output belt pulley through a linking belt, the transmission belt pulley is fixedly arranged on a transmission shaft, the left end and the right end of the transmission shaft are respectively rotatably arranged between the left end wall and the right end wall of the gear cavity, the right, the right side of the sliding cavity is provided with a discharging cavity which penetrates through the upper end face and the lower end face of the fixed block, and the opening of the discharging cavity faces downwards.

The beneficial effects are that: the invention can rapidly identify the chips, classify the unqualified chips and the chips with over-high induction degree, and mark the qualified marks on the chips between induction qualification to classify, thereby more reasonably recovering the unqualified chips and further testing the chips with over-high induction degree so as to recycle the chips.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic view of A-A of FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic view of B-B in FIG. 1 according to an embodiment of the present invention;

FIG. 4 is an enlarged schematic view of the structure at C in FIG. 3 according to an embodiment of the present invention;

FIG. 5 is a schematic view of D-D of FIG. 3 according to an embodiment of the present invention;

FIG. 6 is an enlarged schematic view of the structure at E in FIG. 1 according to an embodiment of the present invention;

FIG. 7 is a schematic view of F-F in FIG. 6 according to an embodiment of the present invention;

FIG. 8 is an enlarged schematic view of the structure at G in FIG. 1 according to an embodiment of the present invention;

FIG. 9 is a schematic diagram of H-H in FIG. 1 according to an embodiment of the present invention.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-9, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a classification device for chip qualification, which comprises a detection shell 10, wherein a transmission cavity 11 is arranged in the detection shell 10, a rotation shaft 14 which is bilaterally symmetrical is rotatably arranged on the front end wall of the transmission cavity 11, a rotation belt pulley 15 which is bilaterally symmetrical is fixedly arranged on the rotation shaft 14, the rotation belt pulley 15 which is bilaterally symmetrical is connected through a transmission belt 13, a fixed block 16 which is fixedly arranged between the front end wall and the rear end wall of the transmission cavity 11 is arranged between the rotation belt pulleys 15 which are bilaterally symmetrical, thirty-two pushing blocks 12 which are arranged in an array are fixedly arranged on the periphery of the transmission belt 13, the pushing blocks 12 on the periphery of the transmission belt 13 which are bilaterally symmetrical are fixedly connected, a sliding cavity 28 which is provided with an upward opening and is bilaterally symmetrical is arranged in the upper end surface of the fixed block 16, a moving block 26 is arranged, a sliding rack 27 is slidably installed between the connecting cavity 39 and the sliding cavity 28, the upper end of the sliding rack 27 is fixedly connected with the lower end face of the moving block 26, the lower end of the sliding rack 27 is hinged with a connecting rod 40, the lower end of the connecting rod 40 is hinged with a connecting block 43, the front side of the connecting cavity 39 is communicated with a sliding cavity 45, the connecting block 43 is slidably installed at the communication position of the sliding cavity 45 and the connecting cavity 39, the front end of the connecting block 43 is hinged with a connecting rod 44, the front end of the connecting rod 44 is hinged with a lower sliding block 46, the upper side of the sliding cavity 45 is communicated with a pushing cavity 52, the lower sliding block 46 is slidably installed between the sliding cavity 45 and the pushing cavity 52, a connecting spring 47 is fixedly arranged on the upper end face of the lower sliding block 46, an upper sliding block 48 is fixedly arranged on the upper end of the connecting spring 47, and a hinged rod 49 is arranged on the upper end of the upper sliding block 48, articulated pole 49 upper end is articulated to be equipped with thrust piece 50, promote chamber 52 with slide the chamber 28 intercommunication, the fixed spring 51 has set firmly on the preceding terminal surface of the latter half of thrust piece 50, fixed spring 51 front end fixed mounting slide in the chamber 28 front end wall.

Beneficially, a driven motor 87 is fixedly arranged in the rear end of the transmission cavity 11, the front end of the driven motor 87 is in power connection with the rear end of the left rotating shaft 14, a rotating gear 18 with an upward opening is communicated in the upper end wall of the transmission cavity 11, identification sensors 78 which are symmetrical left and right are fixedly arranged in the upper end wall of the transmission cavity 11, an isolation plate 79 is fixedly arranged on the lower end face of the identification sensor 78 on the left side, a pressure shaft 75 is rotatably arranged on the right end wall of the communication position of the rotating gear 18 and the transmission cavity 11, a pressure plate 76 is fixedly arranged on the periphery of the pressure shaft 75, a connecting spring 77 is fixedly arranged on the right end face of the pressure plate 76, and the right end of the connecting spring 77 is fixedly arranged in the right end wall of the communication position of the rotating gear 18 and the transmission.

Beneficially, a pulley cavity 74 is provided at the rear side of the right end wall of the communication part between the rotary gear 18 and the transmission cavity 11, the rear end of the pressure shaft 75 is rotatably installed between the communication part between the rotary gear 18 and the transmission cavity 11 and the pulley cavity 74, an engaging bevel gear 31 fixedly installed on the pressure shaft 75 is provided in the pulley cavity 74, a connecting bevel gear 71 is provided at the rear side of the engaging bevel gear 31 in a meshing connection manner, the connecting bevel gear 71 is fixedly installed on a pulley shaft 73, the upper and lower ends of the pulley shaft 73 are respectively rotatably installed between the upper and lower end walls of the pulley cavity 74, a left connecting pulley 72 fixedly installed on the pulley shaft 73 is provided above the connecting bevel gear 71, a connecting cavity 19 is provided at the right side of the pulley cavity 74, and a right connecting pulley 24 located in the connecting cavity 19 is provided at the right side of the left connecting pulley 72, the right connecting pulley 24 is connected to the connecting chamber 19 by a connecting belt 25.

Advantageously, said right connecting pulley 24 is fixedly mounted on said lower connecting shaft 23, the lower end of said lower connecting shaft 23 is rotatably mounted in the lower end wall of said connecting chamber 19, a connecting ratchet set 22 fixedly arranged on the lower connecting shaft 23 is arranged on the upper side of the right connecting belt pulley 24, an upper connecting shaft 21 is fixedly arranged on the connecting ratchet wheel set 22, the upper end of the upper connecting shaft 21 is rotatably arranged in the upper end wall of the connecting cavity 19, the upper side of the connecting ratchet set 22 is provided with a rotating gear 18 fixedly arranged on the upper connecting shaft 21, a movable rack 20 is engaged and connected with the front side of the rotating gear 18, the movable rack 20 is slidably arranged between the connecting cavity 19 and the rotating gear 18, the left end of the movable rack 20 extends into the rotating gear 18 and is fixedly provided with a pushing plate 17, and the pushing plate 17 is slidably arranged in the rotating gear 18.

Beneficially, a motor cavity 86 is arranged between the sliding cavities 28 which are bilaterally symmetrical, a connection motor 29 is fixedly arranged in the upper end wall of the motor cavity 86, a driving shaft 84 is arranged at the lower end of the connection motor 29 in a power connection manner, a driving helical gear 83 is fixedly arranged on the driving shaft 84, driven helical gears 82 which are in meshing connection are symmetrically arranged on the left and right sides of the driving helical gear 83, the driven helical gears 82 are fixedly arranged on a driven shaft 81, a supporting plate 85 is fixedly arranged on the lower end wall of the motor cavity 86, one end of the driven shaft 81, which is close to the center line of the connection motor 29, is rotatably arranged in the end surface of the supporting plate 85, which is far away from the center line of the connection motor 29, a transmission ratchet set 80 is fixedly arranged on a connection shaft 41, one end of the connection shaft 41, which is far away from the center line of the connection motor 29, is rotatably arranged between the motor cavity 86, a connecting gear 42 fixedly mounted on the connecting shaft 41 is arranged in the connecting cavity 39, and the connecting gear 42 is engaged with the sliding rack 27.

Beneficially, an opening cavity 70 with a backward opening is communicated with the rear side of the sliding cavity 28, a moving plate 65 is slidably mounted on the rear end surface of the opening cavity 70 on the right side, a blocking groove 67 with an upward opening is formed in the upper end surface of the moving plate 65, a blocking block 66 is rotatably mounted between the left end wall and the right end wall of the blocking groove 67, a compression spring 68 is fixedly arranged on the rear end surface of the blocking block 66, the lower end of the compression spring 68 is fixedly mounted on the lower end wall of the blocking groove 67, a penetrating cavity 69 located in the moving plate 65 is arranged on the rear side of the blocking groove 67, the penetrating cavity 69 penetrates through the upper end surface and the lower end surface of the moving plate 65, a marking block 63 is fixedly arranged on the upper end wall of the opening cavity 70 on the rear side, a connecting rack 56 is fixedly arranged on the lower end surface of the moving plate 65, a gear cavity 57 is communicated with the lower end wall of the, a transmission gear 60 is arranged on the rear side of the right sliding rack 27 in a meshed connection mode, the transmission gear 60 is fixedly installed on a gear shaft 59, the right end of the gear shaft 59 is rotatably installed in the right end wall of the gear cavity 57, a linking ratchet group 58 fixedly installed on the gear shaft 59 is arranged on the left side of the transmission gear 60, an output shaft 61 is fixedly installed on the left end of the linking ratchet group 58, the left end of the output shaft 61 is rotatably installed in the left end wall of the gear cavity 57, an output belt pulley 62 fixedly installed on the output shaft 61 is arranged on the left side of the linking ratchet group 58, a transmission belt pulley 53 is arranged on the rear side of the output belt pulley 62, the transmission belt pulley 53 is connected with the output belt pulley 62 through a linking belt 25, the transmission belt pulley 53 is fixedly installed on a transmission shaft 54, and the, the right side of the transmission belt pulley 53 is provided with a semicircular gear 55 fixedly mounted on the transmission shaft 54, the semicircular gear 55 is meshed with the connecting rack 56, the right side of the sliding cavity 28 on the right side is provided with a discharging cavity 30 penetrating through the upper end face and the lower end face of the fixed block 16, and meanwhile, the opening of the discharging cavity 30 faces downwards.

When the work is started:

1. the chips are sequentially placed in a rotating gear 18, then a driven motor 87 is started, the driven motor 87 drives a left rotating shaft 14 to rotate, the left rotating shaft 14 rotates to drive a left rotating belt pulley 15 to rotate, the left rotating belt pulley 15 rotates to drive a right rotating belt pulley 15 to rotate through a transmission belt 13, the transmission belt 13 rotates to drive the pushing blocks 12 to rotate, the chips at the communication position of the rotating gear 18 and the transmission cavity 11 fall between the two pushing blocks 12 and then move rightwards under the driving of the transmission belt 13, after the chips move to the lower side of the left identification sensor 78, the left identification sensor 78 identifies the chips through the isolation of an isolation plate 79, and after the identification is successful, the induction degree of the chips is over high, so that the connecting motor 29 drives a driving shaft 84 to rotate forwards, the driving shaft 84 rotates to drive the driving bevel gear 83 to rotate, the driving bevel gear 83 rotates to drive the driven bevel gear 82 to rotate, the driven bevel gear 82 rotates to drive the driven shaft 81 to rotate, when the driven shaft 81 rotates forwards, the left connecting shaft 41 is driven to rotate through the left transmission ratchet set 80, the right transmission ratchet set 80 does not drive the right connecting shaft 41 to rotate, when the driven shaft 81 rotates reversely, the right transmission ratchet set 80 drives the right connecting shaft 41 to rotate reversely, and at the moment, the left connecting shaft 41 which is not driven by the left transmission ratchet set 80 rotates.

2. The left connecting shaft 41 rotates to drive the left connecting gear 42 to rotate, the left connecting gear 42 rotates to drive the left sliding rack 27 to move downwards, the left sliding rack 27 moves downwards to drive the left moving block 26 to move downwards and drive the left connecting block 43 to move backwards through the left connecting rod 40, the left moving block 26 moves downwards to drop a chip passing through the upper part of the moving block 26 to the upper part of the moving block 26 in the left sliding cavity 28, meanwhile, the left connecting block 43 moves forwards through the left connecting rod 44 to drive the left lower sliding block 46 to move upwards, the left lower sliding block 46 moves upwards to drive the left upper sliding block 48 to move upwards, the left upper sliding block 48 moves upwards to drive the left thrust block 50 to move backwards through the left hinge rod 49, the thrust block 50 on the left side cannot move backwards when moving backwards and is blocked by the moving block 26, so that the upper sliding block 48 which is not carried by the lower sliding block 46 moves upwards to become a compression connecting spring 47, when the moving block 26 moves to the lower side of the thrust block 50, the thrust block 50 moves backwards under the driving of the resilience force of the connecting spring 47, so that a chip above the moving block 26 on the left side is driven to move backwards to enter the open cavity 70 on the left side, then the chip is classified and stored outside the device, then the connecting motor 29 is switched off, and the thrust block 50 returns to the initial position under the driving of the resilience force of the fixed spring 51, so that the sliding rack 27 is driven to move upwards to return to the initial position.

3. When the chip moves to the lower side of the identification sensor 78 on the left side, the identification sensor 78 on the left side does not identify the chip through the isolation of the isolation plate 79, but when the chip moves to the lower side of the identification sensor 78 on the right side, the identification sensor 78 on the right side identifies the chip, and when the identification is successful, the sensitivity of the chip is in the most qualified state, so that the connection motor 29 drives the driving shaft 84 to rotate in the reverse direction, the driving shaft 84 rotates to drive the driving helical gear 83 to rotate, the driving helical gear 83 rotates to drive the driven helical gear 82 to rotate, the driven helical gear 82 rotates to drive the driven shaft 81 to rotate, when the driven shaft 81 rotates in the forward direction, the driving ratchet wheel set 80 on the left side drives the engaging shaft 41 on the left side to rotate, at this time, the driving ratchet 80 on the right side does not drive the engaging shaft 41 to rotate, when the driven shaft 81 rotates in the reverse direction, the driving ratchet set 80 on the right, the left side of the coupling shaft 41, which is not provided by the left side of the transmission ratchet group 80, is now rotated.

4. The right-side connecting shaft 41 rotates to drive the right-side connecting gear 42 to rotate, the right-side connecting gear 42 rotates to drive the right-side sliding rack 27 to move downwards, the right-side sliding rack 27 moves downwards to drive the right-side moving block 26 to move downwards and drive the right-side connecting block 43 to move backwards through the right-side connecting rod 40, meanwhile, the sliding rack 27 moves downwards to drive the transmission gear 60 to rotate forwards, the sliding transmission gear 60 is driven to rotate reversely when the sliding rack 27 moves upwards, the right-side moving block 26 moves downwards to enable chips passing through the upper portion of the moving block 26 to fall to the upper portion of the moving block 26 in the right-side sliding cavity 28, meanwhile, the right-side connecting block 43 moves forwards to drive the right-side lower sliding block 46 to move upwards through the right-side connecting rod 44, the right-side lower sliding block 46 moves upwards to drive the right-side upper, the upper sliding block 48 on the right moves upwards to drive the thrust block 50 on the right to move backwards through the hinge rod 49 on the right, the thrust block 50 on the right cannot move backwards when moving block 26 blocks backwards, so that the upper sliding block 48 without the lower sliding block 46 moves upwards to compress the engaging spring 47, and when the moving block 26 moves to the lower side of the thrust block 50, the thrust block 50 is driven to move backwards by the resilience of the engaging spring 47, so that the chip above the moving block 26 on the right is driven to move backwards to enter the moving plate 65 in the open cavity 70 on the right.

5. Meanwhile, the transmission gear 60 rotates to drive the gear shaft 59 to rotate, the gear shaft 59 rotates in a forward direction without driving the output shaft 61 to rotate through the engaging ratchet set 58, the gear shaft 59 rotates in a reverse direction, the output shaft 61 is driven to rotate through the engaging ratchet set 58, so that the sliding rack 27 moves upwards to return to an initial position, the output belt pulley 62 rotates to drive the transmission belt pulley 53 to rotate, the transmission belt pulley 53 rotates to drive the transmission shaft 54 to rotate, the transmission shaft 54 rotates to drive the semicircular gear 55 to rotate, the semicircular gear 55 rotates to drive the connecting rack 56 to move upwards, the connecting rack 56 moves upwards to drive the moving plate 65 to move upwards, the moving plate 65 moves upwards to make the chip mark qualified on the mark block 63, and after the semicircular gear 55 is meshed with the connecting rack 56 and separated, the connecting rack 56 drives the connecting rack 56 to move downwards to return to the initial position under the gravity of the moving plate 65, when the next chip is pushed to the upper part of the moving plate 65, the last marked chip is pushed backwards to the inside of the through cavity 69, then the chip slides to the outside of the device for classified storage, then the connection motor 29 is closed, and the thrust block 50 returns to the initial position under the driving of the resilience force of the fixed spring 51, so that the sliding rack 27 is driven to move upwards to return to the initial position.

6. When the chip is not sensed by the bilateral symmetry recognition sensor 78, the chip is completely unqualified, so that when the chip is moved to the upper part of the discharging cavity 30, the chip falls out of the device through the discharging cavity 30 for classified storage.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a sorter for chip qualification, includes and detects the casing, its characterized in that: a transmission cavity is arranged in the detection shell, a rotation shaft which is bilaterally symmetrical is rotatably arranged on the front end wall of the transmission cavity, a rotation belt pulley which is bilaterally symmetrical is fixedly arranged on the rotation shaft, the rotation belt pulley which is bilaterally symmetrical is connected through a transmission belt, and a fixed block which is fixedly arranged between the front end wall and the rear end wall of the transmission cavity is arranged between the rotation belt pulley which is bilaterally symmetrical;

the sliding cavity upside intercommunication is equipped with the promotion chamber, lower sliding block slidable mounting slide the chamber with promote between the chamber, the sliding block up end has set firmly the linking spring down, linking spring upper end has set firmly last sliding block, it is equipped with the hinge bar to go up the articulated hinge bar in sliding block upper end, the hinge bar upper end is articulated to be equipped with the thrust piece, promote the chamber with the chamber intercommunication slides, fixed spring has set firmly on the preceding terminal surface of rear half of thrust piece, fixed spring front end fixed mounting be in slide in the chamber front end wall. .

2. The sorting device for qualification of chips of claim 1, wherein: the transmission cavity rear end internal fixation has the driven motor, the driven motor front end with left axis of rotation rear end power is connected, the intercommunication is equipped with opening pivoted gear up in the transmission cavity upper end wall, the transmission cavity upper end wall internal fixation has bilateral symmetry's discernment inductor, and is left the terminal surface sets firmly isolated board under the discernment inductor, the pivoted gear with the right-hand member wall internal rotation installation of the intercommunication department in transmission cavity is equipped with the pressure shaft, the pressure plate has set firmly on the pressure shaft periphery, the pressure plate right-hand member face sets firmly coupling spring, coupling spring right-hand member fixed mounting be in the pivoted gear with in the right-hand member wall of the intercommunication department in transmission cavity.

3. The sorting device for qualification of chips of claim 1, wherein: a belt pulley cavity is arranged at the rear side of the right end wall of the communication part of the rotating gear and the transmission cavity, the rear end of the pressure shaft is rotatably arranged between the communication part of the rotating gear and the transmission cavity and the belt pulley cavity, a connecting helical gear fixedly arranged on the pressure shaft is arranged in the belt pulley cavity, a connecting helical gear is arranged at the rear side of the connecting helical gear in a meshing connection way, the connecting bevel gear is fixedly arranged on a pulley shaft, the upper end and the lower end of the pulley shaft are respectively and rotatably arranged between the upper end wall and the lower end wall of the pulley cavity, a left connecting belt pulley fixedly arranged on the belt pulley shaft is arranged above the connecting bevel gear, the belt pulley cavity right side is equipped with connects the chamber, the belt pulley right side is connected on a left side is equipped with and is located connect the right side of intracavity and connect the belt pulley, the right side connect the belt pulley with connect the chamber and connect through linking up the belt.

4. The sorting device for qualification of chips of claim 1, wherein: the right side is connected belt pulley fixed mounting and is in on the connecting axle down, the connecting axle lower extreme rotates to be installed in the connecting chamber lower end wall, the right side is connected the belt pulley upside and is equipped with fixed mounting and connect the epaxial ratchet group of connecting down, it has last connecting axle to connect to have set firmly on the ratchet group, it rotates to install to go up the connecting axle upper end and connects in the chamber upper end wall, it is equipped with fixed mounting to connect the ratchet group upside and is in go up the epaxial rotating gear of connecting, the meshing of rotating gear front side is connected and is equipped with the removal rack, remove rack slidable mounting connect the chamber with between the rotating gear, it extends extremely to remove the rack left end the rotating gear internal fixation has the slurcam, slurcam slidable mounting is in the.

5. The sorting device for qualification of chips of claim 1, wherein: a motor cavity is arranged between the sliding cavities which are bilaterally symmetrical, a connecting motor is fixedly arranged in the upper end wall of the motor cavity, the lower end of the connecting motor is provided with a driving shaft in power connection, a driving helical gear is fixedly arranged on the driving shaft, driven helical gears which are in meshing connection are symmetrically arranged on the left and right sides of the driving helical gear, the driven helical gears are fixedly arranged on a driven shaft, a supporting plate is fixedly arranged on the lower end wall of the motor cavity, one end of the driven shaft, which is close to the central line of the connecting motor, is rotatably arranged in the end surface of the supporting plate, which is far away from one side of the central line of the connecting motor, a transmission ratchet set is fixedly arranged on one side of the driven helical gear, which is far away from the central line of the connecting motor, is rotatably arranged between the motor cavity and the linking cavity, and a connecting gear which is fixedly, the connecting gear is meshed with the sliding rack.

6. The sorting device for qualification of chips of claim 1, wherein: the rear side of the sliding cavity is communicated with an opening cavity with a backward opening, a moving plate is arranged on the right side of the rear end surface of the opening cavity in a sliding manner, a blocking groove with an upward opening is formed in the upper end surface of the moving plate, a blocking block is arranged between the left end wall and the right end wall of the blocking groove in a rotating manner, a compression spring is fixedly arranged on the rear end surface of the blocking block, the lower end of the compression spring is fixedly arranged on the lower end wall of the blocking groove, a penetrating cavity positioned in the moving plate is arranged on the rear side of the blocking groove and penetrates through the upper end surface and the lower end surface of the moving plate, a marking block is fixedly arranged on the upper end wall of the opening cavity on the rear side of the moving plate, a connecting rack is fixedly arranged on the lower end surface of the moving plate, a gear cavity is communicated in the lower end wall, the transmission gear is fixedly arranged on a gear shaft, the right end of the gear shaft is rotatably arranged in the right end wall of the gear cavity, the left side of the transmission gear is provided with a linking ratchet group fixedly arranged on the gear shaft, the left end of the linking ratchet group is fixedly arranged with an output shaft, the left end of the output shaft is rotatably arranged in the left end wall of the gear cavity, the left side of the linking ratchet group is provided with an output belt pulley fixedly arranged on the output shaft, the rear side of the output belt pulley is provided with a transmission belt pulley, the transmission belt pulley is connected with the output belt pulley through a linking belt, the transmission belt pulley is fixedly arranged on a transmission shaft, the left end and the right end of the transmission shaft are respectively rotatably arranged between the left end wall and the right end wall of the gear cavity, the right, the right side of the sliding cavity is provided with a discharging cavity which penetrates through the upper end face and the lower end face of the fixed block, and the opening of the discharging cavity faces downwards.