CN204953374U - Capsule sorting machine - Google Patents

Abstract

The utility model discloses a capsule sorting machine, including frame, motor, install the shooting device in the frame, image analysis system carries out analysis processes to the image that the shooting device photographed in addition, is equipped with feeding system, terminal surface shooting system and periphery shooting system in the frame, and feeding system includes the storage wheel, and storage wheel opposite side still is equipped with the first drawing -inroller and a sorption wheel of terminal surface laminating, be equipped with a plurality of first arc recesses on the outer circumference of first drawing -inroller, terminal surface shooting system includes the second drawing -inroller, is equipped with a plurality of second arc recesses on the outer circumference, still includes the terminal surface camera that links to each other with image analysis system, periphery shooting system includes inner tube and urceolus, and the inner tube is all movable with the urceolus, and it is poor that both have speed. The utility model discloses a slew velocity of control inner tube and urceolus, the speed that can control both linear velocities is poor, that is the roll length of capsule, the rotational speed of urceolus still can further improve, can guarantee that the treatment effeciency of machine improves by a wide margin.

Description

Capsule sorter

Technical field

The utility model belongs to capsule mechanical field, particularly relates to a kind of capsule sorter.

Background technology

In capsule manufacture, unavoidably there will be some defect wares, as cracking, burr, bubble, spot etc., before dispatching from the factory, these defect wares need to be sorted out.Identify foundation mainly its optical characteristics of defect ware, these defects are all from all finding out in appearance.Therefore, in early days, be carry out sorting in the mode of manual identified, as Chinese patent 200920299531X discloses a kind of sorting table of capsule, he is actually under light source irradiation, is manually detected by defective work.Along with the development of image recognition technology, computer recognizing sorting in recent years becomes main flow, as Chinese patent application 2014101405772 discloses a kind of full-automatic optical defective capsule sorter, the Master's thesis " studying based on the identification of the capsule surface defect of machine vision and Sorting Technique " (Zhejiang University, 2013) that and for example Hou Hai flies also relates to the research of this area.These technical schemes are all taken pictures to capsule to be checked by video camera, and then computer is to the photo analysis research taken, and finds out defective capsule, it is sorted out.Current high-speed camera machine technology and image analysis technology relative maturity, be enough to the analysis dealing with capsule; How impact selection efficiency and the mainly mechanical part of reliability, namely deliver to video camera place and how to take by capsule.

In the paper of Hou Haifei, its mechanical part devises unique capsule groove, and capsule can be overturn along with the transmission of conveyer belt, each upset about 90 °, overturns three times, collects the capsule image of four width different surfaces altogether, completely covers capsule one week, reach the effect detected completely.This scheme can ensure all standing of shooting speed and shooting angle, but the clamping force of capsule groove is difficult to control, and easily crushes capsule; The speed of capsule upset is simultaneously difficult to increase substantially, thus have impact on the efficiency of selection.

And in 2014101405772, its mechanical system has a sorter, sorter offers the hole of circumferential arrangement; The pedestal that sorter is arranged on printing opacity rotates, and when sorter rotates, the capsule to be checked promoted in its hole rolls on pedestal, and now video camera carries out multiframe shooting to capsule.This mode is the sorting mode of at present most main flow, is also the immediate prior art of the utility model.Finding in practice, also there are some problems in this technical scheme, is that error rate can not reach requirement on the one hand, there is undetected defect ware; Be that efficiency is difficult to further raising on the other hand, process 7 ~ 80,000 capsules per hour can be accomplished at present, be difficult to improve again.

Summary of the invention

The purpose of this utility model is to provide a kind of capsule sorter of more high efficient and reliable.

The technical solution adopted in the utility model is such: capsule sorter, comprise frame, motor, frame is provided with filming apparatus, also have image analysis system to carry out analyzing and processing to the image that filming apparatus photographed, it is characterized in that: frame is equipped with feed system, end face camera system and periphery camera system, feed system comprises storing wheel, storing wheel is opening tubular, centre is provided with cylinder shape groove, and axial cross section is in " recessed " font, and the notch of cylinder shape groove connects with feeding port; Storing wheel opposite side is also provided with the first drawing-inroller and first sorption wheel of end face laminating, and storing wheel, the first drawing-inroller and the first sorption wheel are fixed on the same axis successively; The excircle of the first drawing-inroller is provided with some first arc grooves, for accommodating capsule to be checked; The end face that first sorption wheel and the first drawing-inroller are affixed and be circumferentially provided with air port, match with the first arc groove position in air port; Overlap outside the periphery of the first drawing-inroller and the first sorption wheel and have protecting of tubular structure to expect to take turns; Described protecting outside material wheel is provided with the first airduct, protects inside material wheel periphery and is provided with ventilation slot, and the first airduct is connected with ventilation slot through protecting material wheel outer wall; Described first airduct connects vacuum extractor, for the first arc groove place provides negative pressure;

End face camera system comprises the second drawing-inroller, and described second drawing-inroller is opening tubular, and excircle is provided with some second arc grooves, for accommodating capsule to be checked; Described second drawing-inroller inside is also provided with the second sorption wheel, and the second sorption wheel connects vacuum extractor, for the second arc groove place provides negative pressure; Also comprise the end face camera be connected with image analysis system, end face camera is provided with two, is placed in the second drawing-inroller both sides respectively;

Periphery camera system comprises inner core and urceolus, and inner core and urceolus are cylinder shape, coaxially arrange, and urceolus is located at outside inner core; Urceolus is provided with some holes, and capsule to be checked is contained in hole, and urceolus promotes capsule to be checked and rolls on inner core; Periphery camera to capsule shoot multi-frame images to be checked, by analyzing captured image to differentiate and sorting inferior capsule; Inner core and urceolus are all movable, and both have speed difference;

Motor drives each rotatable parts work by transmission mechanism.

Further, the front end of the first arc groove of described feed system is provided with flaring targeting port, and the first arc groove end is provided with the adsorption orifice that groove depth is greater than the first arc groove mid portion; Described adsorption orifice lower end communicates with the air port on the first sorption wheel end face; The center of the mid portion of described first arc groove, adsorption orifice and the first sorption wheel end face uptake is not at sustained height; Air port on described first sorption wheel end face is corresponding with tuyere position circumferentially, inner connected by air channel, right angle; Described air port is circumferentially connected with the first airduct; Described storing wheel inwall is provided with a circle dentalation; The sidewall of cylinder shape groove is provided with opening, and bottom portion of groove is provided with axis hole; Described material wheel below of protecting is provided with discharging opening, and discharging opening matches with the first arc groove position.

Further, the second drawing-inroller and second sorption wheel of described end face camera system are coaxially arranged, matched in clearance, and the second drawing-inroller is fixed on power transmission shaft, and the second sorption wheel and power transmission shaft are separated by with bearing; Described second sorption wheel end face is provided with the second airduct, and the second airduct connects vacuum extractor; Described second sorption wheel be circumferentially provided with the arc ventilating opening communicated with the second airduct together, described arc ventilating opening originates in the second sorption wheel and protects the points of tangency of expecting to take turns, and ends at the points of tangency of the second sorption wheel and urceolus; Be provided with wind inlet in second arc groove, wind inlet is connected with arc ventilating opening.

During utility model works, capsule to be checked enters from feeding port, and it is inner that the opening through cylinder shape groove sidewall enters storing wheel, and the fluctuation of dentalation on inwall taken turns by the rotation utilizing storing to take turns and storing, makes capsule to be checked produce mobile in storing wheel and beat; Vacuum extractor produces negative pressure by the air channel, right angle in the first airduct and the first sorption wheel in the first arc groove, is adsorbed in the first arc groove by capsule to be checked from storing wheel inside; The groove depth of adsorption orifice is greater than the first arc groove mid portion, and is connected with air channel, right angle below adsorption orifice, and make air port on capsule to be checked and the first sorption wheel end face not on the same line, capsule to be checked can not block air port; First airduct acts on the first sorption wheel air port circumferentially by ventilation slot, and ventilation slot position is relative with the middle top of the first sorption wheel direction of rotation, and namely the sphere of action of the first airduct is the middle top of the first sorption wheel direction of rotation; When capsule to be checked has departed from the sphere of action of the first airduct, the inwall protecting material wheel can make capsule to be checked not depart from the first arc groove, along with the first drawing-inroller rotates, capsule to be checked falls in the second arc groove of end face camera system from the discharging opening protecting material wheel below, detects.

Then, vacuum extractor adsorbs air in the second arc groove by the second airduct, is firmly adsorbed on by capsule to be checked in second arc groove; Second drawing-inroller can with drive axis, second sorption wheel and power transmission shaft are separated by with the second bearing, then the second drawing-inroller can rotate relative to the second sorption wheel, when the second arc groove on the second drawing-inroller leaves the sphere of action of arc ventilating opening, the capsule to be checked at the second arc groove place no longer affects by negative pressure, depart from the second arc groove, fall into periphery camera system and enter next step detection.

The inner core of periphery camera system and urceolus are all rotating, and after capsule to be checked enters the hole of urceolus, are be pushed and roll on inner core equally; But now, capsule, relative to the rolling speed of inner core, is not the velocity of rotation depending on urceolus, but depends on the speed difference of urceolus and inner core.In the utility model, the shooting interval of periphery camera is consistent with the rotation phase of urceolus, and namely urceolus often rotates the distance of an adjacent holes, and video camera shooting once; Now the rolling length of capsule is not the distance of an adjacent holes, but will deduct the rotation distance of inner core.By controlling the velocity of rotation of inner core and urceolus, the speed difference of both linear velocities can be controlled, that is the rolling length of capsule.In practice, can by this Numerical Control at 1/4 of capsule girth, namely take 90 °, 4 shootings can cover whole circumference completely at every turn.As the capsule of other models need be sorted, then according to the girth of capsule to be checked, regulate the velocity of rotation of inner core, still can accomplish all standing of shooting angle.

And on the other hand, the treatment effeciency of machine, because periphery camera shooting speed almost can ad infinitum improve, therefore depends primarily on the velocity of rotation of urceolus, this refers to the speed of urceolus relative to surrounding environment.And the rotating speed of urceolus still can improve further, that is, although capsule is slack-off relative to the rolling speed of inner core, its movement velocity relative to surrounding environment is still very fast, can ensure that the treatment effeciency of machine improves significantly.

Accompanying drawing explanation

Be described in further detail below in conjunction with accompanying drawing and embodiment of the present utility model

Fig. 1 is structure sectional view of the present utility model;

Fig. 2 is side view of the present utility model;

Fig. 3 is the structure sectional view of the utility model feed system;

Fig. 4 is the structure sectional view of the utility model end face camera system;

Fig. 5 is the structure sectional view of the utility model periphery camera system;

Fig. 6 is the structural representation of the utility model storing wheel;

Fig. 7 is the structural representation of the utility model first sorption wheel;

Fig. 8 is the structural representation that the utility model protects material wheel;

Fig. 9 is the structural representation of the utility model second sorption wheel;

Figure 10 is the structural representation of the utility model second drawing-inroller;

Figure 11 is the structural representation of the utility model inner core;

Figure 12 is the part-structure schematic diagram of the utility model cylinder circle.

Be labeled as in figure: motor 1, the first power transmission shaft 11, driving wheel 12, the first drive 13, second drive 14,3rd drive 15, outer shaft 16, Inner axle 17, second driving shaft 18, the 3rd power transmission shaft 19,4th power transmission shaft 20, driving pulley 21, belt 22, driven pulley 23;

Feed system 3, feeding port 31, storing wheel 32, cylinder shape groove 321, opening 322, dentalation 323, axis hole 324, first drawing-inroller 33, first sorption wheel 34, first arc groove 35, targeting port 351, adsorption orifice 352, air port 36, air channel, right angle 37, protects material wheel 38, discharging opening 381, ventilation slot 382, division board 383, the first airduct 39;

End face camera system 5, second sorption wheel 51, second airduct 52, second drawing-inroller 53, second arc groove 54, arc ventilating opening 55, wind inlet 56, end face camera 57;

Periphery camera system 7, inner core 71, urceolus 72, cylindrical shell 721, cylinder circle 722, hole 7221;

Periphery camera 4, light source 6, blowning installation 8, clutch shaft bearing 91, the second bearing 92, signal wheel 10, optoelectronic switch 101.

Detailed description of the invention

See accompanying drawing.The present embodiment is a complete inferior capsule sorter, comprises feed system 3, end face camera system 5 and periphery camera system 7.The machine of accompanying drawing 1 comprises two symmetrical mutually covers, and for sake of convenience, the present embodiment only describes wherein a set of.

Feed system 3 comprises feeding port 31, storing wheel the 32, first drawing-inroller 33, first sorption wheel 34 and protects material wheel 38; The structure of described storing wheel 32 is opening tubular, and centre is provided with cylinder shape groove 321, and axial cross section is in " recessed " font; The notch of cylinder shape groove 321 connects with feeding port 31, is provided with axis hole 324 bottom cylinder shape groove 321, and recess sidewall is provided with opening 322; Storing is taken turns 32 inwalls and is provided with a circle dentalation 323, for the capsule to be checked that loosening heap is crowded together, is convenient to drive capsule to rotate; It is relative with the outer circumferential position of the first drawing-inroller 33 that 32 inwalls taken turns by storing; The excircle of the first drawing-inroller 33 is provided with equally distributed first arc groove 35 of a circle, first arc groove 35 front end is provided with flaring targeting port 351, first arc groove 35 end and is provided with the adsorption orifice 352 that groove depth is greater than the first arc groove 35 mid portion; The end face that first sorption wheel 34 and the first drawing-inroller 33 are affixed and be circumferentially provided with air port 36, end face is corresponding with position, air port 36 circumferentially, is innerly connected by air channel, right angle 37; Air port on described first sorption wheel 34 end face is docked with the adsorption orifice 352 on the first drawing-inroller 33, and simultaneously not on the same line, namely capsule to be checked can not block air port at the center of the first arc groove 35, adsorption orifice 352 and sorption wheel 34 end face uptake 36; The center in the air port on described first arc groove 35, adsorption orifice 352 and the first sorption wheel 34 end face, not at same straight line, blocks air port for preventing capsule to be checked; Described storing wheel the 32, first drawing-inroller 33 and the first sorption wheel 34 are fixed on the 3rd power transmission shaft 19 successively, the 3rd power transmission shaft 19 are fixed with the 3rd drive 15; Described protecting expects that wheel 38 is for tubular structure, is enclosed within the first drawing-inroller 33 and the first sorption wheel 34 periphery; Described protecting outside material wheel 38 is provided with the first airduct 39, protects inside material wheel 38 periphery and is provided with ventilation slot 382, and the first airduct 39 is communicated with ventilation slot phase 382 through protecting material wheel 38 outer wall; Ventilation slot 382 is connected with the first sorption wheel 34 air port circumferentially; Protect below material wheel 38 and be provided with discharging opening 381, relative with the first drawing-inroller 33 the first arc groove 35 position circumferentially; Be provided with division board 383 below the gap that described storing wheel 32 and protecting expect between wheel 38, division board 383 is fixed on below the end face that protects and expect wheel 38; Ensure that the capsule to be checked in storing wheel 32 enters in the first arc groove 35 of the first drawing-inroller 33 from top.

End face camera system 5 comprises the second sorption wheel 51, second drawing-inroller 53 and end face camera 57, second sorption wheel 51 end face is provided with the second airduct 52, second airduct near pay-off, the second sorption wheel 51 be circumferentially provided with one arc ventilating opening 55; Described second drawing-inroller 53 is opening tubular, cover on the second sorption wheel 51 peripheral and with its matched in clearance; Described second drawing-inroller 53 is circumferentially provided with equally distributed second arc groove 54 of a circle, for accommodating capsule to be checked; Be provided with wind inlet 56 in second arc groove, wind inlet 56 and the second sorption wheel 51 arc ventilating opening 55 position is circumferentially relative; Described arc ventilating opening 55 one end is positioned at the second sorption wheel 51 and protects the points of tangency of expecting wheel 38, and the other end is positioned at the points of tangency of the second sorption wheel 51 and urceolus 72; Described second drawing-inroller 53 is fixed on second driving shaft 18, drives by second driving shaft being fixed the second drive 14; Described second sorption wheel 51 is enclosed within second driving shaft 18, and is separated by with the second bearing 92 between second driving shaft 18.End face camera 57 is provided with two, is placed in the both sides of the second drawing-inroller 53 respectively.

Periphery camera system 7 comprises inner core 71 and urceolus 72, the substrate parts of inner core 71 that is described in utility model content part, the push mechanism of urceolus 72 that is described in utility model content part, inner core 71 to be arranged on interior axle 17 and to be driven by interior axle and rotates, urceolus 72 to be arranged on outer shaft 16 and to be driven by outer shaft and rotates, interior axle 17 is driven by driven pulley 23, and outer shaft 16 is driven by the first drive 13, is separated by between interior axle and outer shaft with clutch shaft bearing 91.The material of inner core 71 is clear glass, inside cylinder, light source 6 is also housed.Urceolus 72 is made up of cylindrical shell 721 and cylinder circle 722, and cylinder circle is fixed on cylindrical shell becomes an entirety, and is axially being coated on the outside of inner core; Cylinder circle has some penetrating holes 7221, is uniformly distributed in the whole periphery of cylinder circle.(Figure 11 is one section of cylinder circle).

Periphery camera system also comprises periphery camera 4, above the hole 7221 being placed in urceolus, and corresponding with light source 6, to improve shooting precision.

Urceolus 72 is outer is provided with blowning installation 8, with solenoid control simultaneously.

The present embodiment also comprises dynamical system, and dynamical system comprises motor 1, and motor 1 drives fixing driving wheel 12 in the middle of the first power transmission shaft 11, first power transmission shaft 11, and left end fixes the 4th drive 24; Driving wheel is meshed with the first drive 13, and the first drive 13, second drive 14, the 3rd drive 15 three engage successively; 4th drive 24 engages with the 5th drive 25, and the 5th drive 25 is coaxially fixed on the 4th power transmission shaft 20 with driving pulley 21, and driving pulley 21 connects driven pulley 23 by belt 22.Driven pulley 21 drives Inner axle 17, drives inner core 71 to rotate; First drive 13 drives outer shaft 16, drives urceolus 72 to rotate; Driven pulley 21 is identical with the rotation direction of the first drive 13.Second drive 14 drives second driving shaft 18, drives the second drawing-inroller 53 in end face camera system 5; 3rd drive 15 drives the 3rd power transmission shaft 19, drives storing wheel the 32, first drawing-inroller 33 and the first sorption wheel 34 in feed system 3.3rd power transmission shaft 19 is also provided with signal wheel 10, is provided with optoelectronic switch 101 above signal wheel 10, signal wheel 10 is circumferentially provided with induction tooth, and the quantity of induction tooth is consistent with the quantity of the first drawing-inroller 33 the first arc groove 35 circumferentially; Optoelectronic switch 101 connection signal treatment system, when signal wheel 10 rotates, induction tooth is through optoelectronic switch 101, and optoelectronic switch 101 is responded to and is equivalent to the first arc groove 35 for 1 time and turns to next position.

During the present embodiment work, capsule to be checked is sent into from feeding port, the opening 322 of cylinder shape groove 321 sidewall in the middle of storing wheel 32 enters storing wheel inside, storing wheel rotates with the 3rd power transmission shaft 19, utilize the rotation of storing wheel 32 and storing to take turns the fluctuation of dentalation 323 on 32 inwalls, make capsule to be checked produce mobile in storing wheel 32 and beat; The tubaeform targeting port 351 of the first drawing-inroller 33 the first arc groove 35 front end is circumferentially inner towards storing wheel 38, first airduct 39 is by air channel, right angle 37 extracting air in the first sorption wheel 34, be connected with air channel, right angle 37 below the adsorption orifice of the first arc groove end, make capsule to be checked be adsorbed on the first arc groove of the first drawing-inroller 33; First airduct 39 acts on the first sorption wheel 34 air port circumferentially by ventilation slot 382, ventilation slot 382 position is relative with the middle top of the first sorption wheel 34 direction of rotation, and namely the sphere of action of the first airduct 39 is the middle top of the first sorption wheel 34 direction of rotation; When capsule to be checked has departed from the sphere of action of the first airduct 39, the inwall protecting material wheel 38 can make capsule to be checked not depart from the first arc groove 35, along with the first drawing-inroller 33 rotates, capsule to be checked falls in the second arc groove 54 of the second drawing-inroller 53 from the discharging opening 381 protected below material wheel 38.

When capsule to be checked departs from the first arc groove, capsule to be checked is positioned at the first drawing-inroller 33 and the tangent position of the second drawing-inroller 53, and capsule to be checked just in time falls in the second drawing-inroller 53 the second arc groove 54 circumferentially; Second airduct 52 is by the second sorption wheel 51 arc ventilating opening 55 extracting air circumferentially, and capsule to be checked is adsorbed in the second arc groove 54 by the wind inlet 56 in the second arc groove; Now, the both ends of the surface of capsule to be checked taken by the end face camera 57 being positioned at the second drawing-inroller 53 both sides, and the image after shooting is sent to image analysis system; Second drawing-inroller 53 rotates along with second driving shaft 18, and when the second drawing-inroller 53 forwards below to, departed from the sphere of action of arc ventilating opening 55, capsule to be checked loses absorption affinity, thus departs from the second arc groove 54.

When capsule to be checked departs from the second arc groove 54, capsule to be checked is positioned at the second drawing-inroller 53 position tangent with urceolus 72, and capsule to be checked just in time falls in the hole 7221 of urceolus cylinder circle 722; Capsule bottom surface to be checked and inner core 71 touch, inner core 71 drives rotation by interior axle 17, and urceolus 72 drives rotation by outer shaft 16, inner core 71 and urceolus 72 rotating in same direction, and inner core velocity of rotation is different from urceolus velocity of rotation, rotation while capsule to be checked is driven by urceolus; Now, light source 6 is radiated on capsule to be checked through the inner core 71 that material is transparent, and capsule periphery to be checked taken by the periphery camera 4 be placed in above urceolus hole 7221, and the image of shooting is sent to image analysis system.

When image analysis system finds that there is as cracking, burr, bubble, the capsule of the flaws such as spot, signal processing system receives the number of times that optoelectronic switch 101 is responded to, thus judge which first arc groove inferior capsule is positioned at, because the second arc groove 54 on the first arc groove 35 on the first drawing-inroller 33 and the second drawing-inroller 53 and the hole 7221 of urceolus 72 are all one to one, so can judge inferior capsule is positioned at which hole 7221, and Controlling solenoid valve break-make, defect ware capsule is blown off hole 7221 by the blowning installation 8 outside urceolus 72.

During the present embodiment work, the rotating speed of inner core 71 and urceolus 72 follows following formula: m* Δ V/ =L/4.In formula: m is the distance between adjacent two holes, for the linear velocity of urceolus periphery, Δ V is the difference of the linear velocity of inner/outer tube periphery, and L is the girth of capsule to be checked.By the design of such velocity ratio, urceolus 72 can be made often to rotate a phase place, namely often move the distance of a hole, periphery camera is taken once, 90 degree that just in time can photograph capsule circumference.

Visible, the present embodiment is by strengthening , the treatment effeciency of machine can be improved; According to the girth adjustment Δ V of different capsule, can ensure that namely often take four times covers whole circumference all the time.Goal of the invention of the present utility model can be realized well.

Claims (3)

1. capsule sorter, comprise frame, motor, frame is provided with filming apparatus, also have image analysis system to carry out analyzing and processing to the image that filming apparatus photographed, it is characterized in that: frame is equipped with feed system, end face camera system and periphery camera system, feed system comprises storing wheel, storing wheel is opening tubular, centre is provided with cylinder shape groove, and axial cross section is in " recessed " font, and the notch of cylinder shape groove connects with feeding port; Storing wheel opposite side is also provided with the first drawing-inroller and first sorption wheel of end face laminating, and storing wheel, the first drawing-inroller and the first sorption wheel are fixed on the same axis successively; The excircle of the first drawing-inroller is provided with some first arc grooves, for accommodating capsule to be checked; The end face that first sorption wheel and the first drawing-inroller are affixed and be circumferentially provided with air port, match with the first arc groove position in air port; Overlap outside the periphery of the first drawing-inroller and the first sorption wheel and have protecting of tubular structure to expect to take turns; Described protecting outside material wheel is provided with the first airduct, protects inside material wheel periphery and is provided with ventilation slot, and the first airduct is connected with ventilation slot through protecting material wheel outer wall; Described first airduct connects vacuum extractor, for the first arc groove place provides negative pressure;

End face camera system comprises the second drawing-inroller, and described second drawing-inroller is opening tubular, and excircle is provided with some second arc grooves, for accommodating capsule to be checked; Described second drawing-inroller inside is also provided with the second sorption wheel, and the second sorption wheel connects vacuum extractor, for the second arc groove place provides negative pressure; Also comprise the end face camera be connected with image analysis system, end face camera is provided with two, is placed in the second drawing-inroller both sides respectively;

Periphery camera system comprises inner core and urceolus, and inner core and urceolus are cylinder shape, coaxially arrange, and urceolus is located at outside inner core; Urceolus is provided with some holes, and capsule to be checked is contained in hole, and urceolus promotes capsule to be checked and rolls on inner core; Periphery camera to capsule shoot multi-frame images to be checked, by analyzing captured image to differentiate and sorting inferior capsule; Inner core and urceolus are all movable, and both have speed difference;

Motor drives each rotatable parts work by transmission mechanism.

2. capsule sorter as claimed in claim 1, it is characterized in that: the front end of the first arc groove of described feed system is provided with flaring targeting port, the first arc groove end is provided with the adsorption orifice that groove depth is greater than the first arc groove mid portion; Described adsorption orifice lower end communicates with the air port on the first sorption wheel end face; The center of the mid portion of described first arc groove, adsorption orifice and the first sorption wheel end face uptake is not at sustained height; Air port on described first sorption wheel end face is corresponding with tuyere position circumferentially, inner connected by air channel, right angle; Described air port is circumferentially connected with the first airduct; Described storing wheel inwall is provided with a circle dentalation; The sidewall of cylinder shape groove is provided with opening, and bottom portion of groove is provided with axis hole; Described material wheel below of protecting is provided with discharging opening, and discharging opening matches with the first arc groove position.

3. capsule sorter as claimed in claim 1, is characterized in that: the second drawing-inroller and second sorption wheel of described end face camera system are coaxially arranged, matched in clearance, and the second drawing-inroller is fixed on power transmission shaft, and the second sorption wheel and power transmission shaft are separated by with bearing; Described second sorption wheel end face is provided with the second airduct, and the second airduct connects vacuum extractor; Described second sorption wheel be circumferentially provided with the arc ventilating opening communicated with the second airduct together, described arc ventilating opening originates in the second sorption wheel and protects the points of tangency of expecting to take turns, and ends at the points of tangency of the second sorption wheel and urceolus; Be provided with wind inlet in second arc groove, wind inlet is connected with arc ventilating opening.