CN220807671U - Visual classification plume cutting machine - Google Patents

Abstract

The application relates to a visual classification feather stem cutting machine, which relates to the field of feather processing equipment, and comprises an operating platform and further comprises: a transport mechanism mounted on the console; a feed hopper mounted at the input end of the transport mechanism; the detection mechanism is arranged above the conveying mechanism and is positioned at the side of the feed hopper; at least three groups of classifiers respectively arranged at the sides of the conveying mechanism along the conveying direction; at least three sets of rod cutting mechanisms disposed on opposite sides of the transport mechanism and the classifier; wherein, cut pole mechanism includes: the conveying assembly is arranged at the side of the conveying mechanism and opposite to the classifier; a cutting assembly disposed at an output end of the transfer assembly; an outfeed assembly adjacent to the cutting assembly. The application has the effect of improving the efficiency and accuracy of the feather classification and pole cutting procedures, thereby improving the production efficiency and the finished product qualification rate of the whole badminton manufacturing.

Description

Visual classification plume cutting machine

Technical Field

The application relates to the field of feather processing equipment, in particular to a visual classification feather stem cutting machine.

Background

The feather is an important raw material for badminton production, and before the feather is processed into the badminton, the feather needs to be subjected to the procedures of length classification and pole cutting, so that the feather with higher morphological consistency is obtained, and a plurality of feathers on the manufactured badminton have the same morphology, so that the badminton is guaranteed to have good flight stability.

The feather sorting and stalk cutting processes are generally performed by means of manual operations, and recently, a technology of classifying feathers by an automatic classifying device has also appeared, so that the feather classifying device gradually replaces the manual operations, and stalk cutting operations of feathers are still generally performed under the manual operations.

However, the manual operation has the problems that the manual speed is low, and the overall production efficiency of the badminton is reduced; moreover, the operation process is subjectively controlled by workers, and subjective factors such as fatigue, emotion and the like of the operators and operation skills can influence the operation process, so that the errors of feather classification and cutting are increased, and further the processing efficiency and the finished product qualification rate of the shuttlecock are influenced.

Disclosure of utility model

The application provides a visual classifying and cutting machine for feather, which aims to solve the problems of low precision of feather classification and cutting and low production efficiency of shuttlecocks.

The application provides a visual classification feather cutting machine which adopts the following technical scheme:

The utility model provides a visual classification cuts feather pole machine, includes the operation panel, still includes: the transport mechanism is arranged on the operation table; the feeding hopper is arranged at the input end of the conveying mechanism; the detection mechanism is arranged above the conveying mechanism and is positioned at the side of the feed hopper; at least three groups of classifiers are respectively arranged at the sides of the conveying mechanism along the conveying direction; at least three sets of rod cutting mechanisms arranged on the opposite side of the conveying mechanism from the classifier; wherein, cut pole mechanism includes: the conveying assembly is arranged at the side of the conveying mechanism and opposite to the classifier; the cutting assembly is arranged at the output end of the conveying assembly; and a discharge assembly disposed adjacent to the cutting assembly.

By adopting the technical scheme, the detection mechanism is used for detecting the feathers, so that the accuracy of feather classification is improved, and the error of feather classification is reduced; the classifier can push the corresponding feathers, so that the feathers automatically and accurately enter the rod cutting mechanism according to the classification result; utilize cutting pole mechanism to cut the feather, improve the accuracy of cutting, improve the uniformity of feather form to cutting efficiency has been improved.

In a specific embodiment, the transport mechanism comprises: the first power sets are arranged at two ends of the operating platform; the conveying belt is arranged on the first power unit; a first tensioning roller forming a pretension to tension the conveyor belt.

By adopting the technical scheme, the conveyor belt is driven to transport under the drive of the first power set, so that the feathers are driven to transport, and the automatic transport of the feathers is realized; the first tensioning roller is used for tensioning the conveying belt, so that the situation that the conveying belt is loose or excessively tensioned is avoided, and stable transmission of the conveying belt is ensured.

In a specific embodiment, the detection mechanism comprises: at least two side plates vertically installed on the operation table; a detection space is formed between the side plates; a detector installed between the side plates and having an imaging direction toward the conveyor belt; and the display screen is arranged on the side plate.

By adopting the technical scheme, the detector detects the length of the feather on the conveyer belt, and the precision of feather grouping is improved.

In a specific embodiment, the transfer assembly comprises: the conveying belt is arranged on one side of the conveying belt and forms a preset angle with the conveying belt; the guide part is arranged at the input end of the conveyor belt and is opposite to the classifier; the guide part has a tendency to shrink along the conveying direction of the conveyor belt; the second power sets are arranged at two ends of the conveyor belt; and a second tensioning roller for forming a pretension to tension the conveyor belt.

By adopting the technical scheme, the arrangement of the guide part ensures that the feather is transmitted according to the set position and direction when being transmitted onto the conveyor belt from the conveyor belt, and the consistency of the position of the feather on the conveyor belt is improved; the second tensioning roller tensions the conveyor belt, so that the condition that the conveyor belt is loose or excessively tensioned is avoided, and stable transmission of the conveyor belt is ensured.

In a specific embodiment, the cutting assembly comprises: a blocking portion provided adjacent to an end of the conveyor belt; a cutting part arranged at one side of the blocking part; and the pushing part is positioned at one side of the cutting part.

By adopting the technical scheme, the blocking part can control the feathers to enter the cutting part in real time, block the feathers in the cutting process and set the length of the feathers required to be cut; the cutting part realizes automatic cutting of feathers, and improves cutting efficiency; the pushing part can automatically push the cut feathers, so that the feathers automatically fall into the discharging component.

In a specific embodiment, the outfeed assembly comprises: a waste channel mounted at an output end of the conveyor belt; and the discharging channel is arranged opposite to the pushing part.

Through adopting above-mentioned technical scheme, utilize the ejection of compact subassembly to collect respectively feather and feather pole after the cutting, throw into next process with the feather, abandon the feather pole, improved holistic production efficiency of badminton.

In a specific embodiment, a feed channel is provided in the feed hopper; the feed channel extends toward the conveyor belt and has a downward sloping tendency.

Through adopting above-mentioned technical scheme, the setting of the feed channel of feeder hopper has guaranteed that the feather conveys smoothly to the conveyer belt according to the direction of settlement.

In a specific embodiment, the barrier includes: the first baffle is arranged on the conveyor belt and is connected to the output end of the first baffle driver; the second baffle is positioned at one side of the first baffle and is connected with the output end of the second baffle driver; the bearing bar is arranged at the output end of the conveyor belt; the compression bar is arranged opposite to the bearing bar and can move towards the direction of the conveyor belt under the drive of the driver; the third baffle is arranged on one side of the bearing strip away from the conveyor belt and is arranged at a set distance from the bearing strip.

By adopting the technical scheme, the first baffle can be used for blocking the feathers on the conveyor belt according to the needs, so that the feathers can be ensured to enter the cutting part one by one to be cut; the second baffle is arranged to prevent the feathers from falling off in the cutting process; the third baffle can block the feathers at a set position, so that the cutting length of the feathers is ensured; the compression bar and the compression bar are matched to realize better compression of the feather, so that stability of the feather when the feather is cut into the bar is improved.

In a specific embodiment, the cutting portion includes: the cutting bracket is arranged at the side of the bearing strip; the cutting cylinder is arranged on the cutting bracket; the output end of the cutting cylinder is connected with a connecting block; a cutting driving shaft is arranged on the connecting block; the cutter handle of the fixed cutter is fixed on the cutting bracket, and the cutter body extends along one side of the bearing bar adjacent to the third baffle; and the cutter is rotated and connected with the cutting support in a rotating way, a sliding connection groove which is in sliding connection with the cutting driving shaft is formed in the cutter handle, and the cutter body is positioned on one side of the cutter body of the fixed cutter.

Through adopting above-mentioned technical scheme, utilize cutting cylinder and cutting drive shaft to guarantee the automatic operation of rotation cutter, improve the operating efficiency of cutting the pole.

In a specific embodiment, the first power set includes a first driving roller and a first driven roller, and the first driving roller and the first driven roller are respectively arranged at two ends of the conveying belt; the second power set comprises a second driving roller and a second driven roller, and the second driving roller and the second driven roller are respectively arranged at two ends of the conveyor belt.

Through adopting above-mentioned technical scheme, first power pack is used for driving the conveyer belt, and the second power pack is used for driving the conveyer belt, guarantees the smooth operation of feather between different operation processes.

In summary, the present application includes at least one of the following beneficial technical effects:

1. The detection mechanism is used for detecting the feathers and feeding imaging data back to the controller, so that the accuracy of grouping the lengths of the feathers can be improved, and the consistency of grouping the feathers is ensured;

2. According to the grouping result, the classifier can realize automatic pushing of the feathers corresponding to the grouping, and the consistency of the feather forms after grouping is ensured;

3. The cutting rod mechanism is utilized to cut the feathers to a preset length, so that the accuracy and consistency of the feather cutting are ensured, and the overall processing efficiency and the finished product qualification rate of the shuttlecock are improved.

Drawings

FIG. 1 is a schematic view of one embodiment of a visual classification plume machine of the present application.

FIG. 2 is a schematic view of a transport mechanism, hopper and detection mechanism in one embodiment of the visual classification plume machine of the present application.

Fig. 3 is a schematic view of a pole cutting mechanism in one embodiment of the visual classification pole cutting machine of the present application.

Fig. 4 is a schematic view of another view of the cutting bar mechanism in one embodiment of the visual classification bar cutting machine of the present application.

Reference numerals illustrate: 1. an operation table; 2. a transport mechanism; 21. a first power pack; 211. a first drive roll; 212. a first driven roller; 22. a conveyor belt; 3. a feed hopper; 31. a feed channel; 4. a detection mechanism; 41. a side plate; 42. a detector; 43. a display screen; 5. a classifier; 6. a rod cutting mechanism; 7. a transfer assembly; 71. a conveyor belt; 72. a guide section; 73. a second power pack; 731. a second drive roll; 732. a second driven roller; 8. a cutting assembly; 81. a blocking portion; 811. a first baffle; 812. a second baffle; 813. a compression bar; 814. a first barrier driver; 815. a second barrier driver; 816. a bearing bar; 817. a third baffle; 82. a cutting section; 821. cutting the bracket; 822. a cutting cylinder; 823. a connecting block; 824. cutting the driving shaft; 825. fixing the cutter; 826. rotating the cutter; 83. a pushing part; 9. a discharge assembly; 91. a waste channel; 92. and a discharging channel.

Detailed Description

The application is described in further detail below with reference to fig. 1-4. It should be understood that the detailed description and specific examples, while indicating and illustrating the application, are not intended to limit the application.

In the description of the present application, it should be noted that, unless explicitly stated and limited otherwise, the terms "disposed" and "connected" should be interpreted broadly, and for example, they may be fixedly connected, detachably connected, or integrally connected; either directly or indirectly via an intermediate medium, or in communication with each other or in interaction with each other. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

In this specification, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying a number of technical features being indicated, such that features defining "first," "second," "third," or the like may explicitly or implicitly include one or more of such features.

One embodiment of the visual classification plume machine of the present application, as shown in fig. 1, comprises: the device comprises an operation table 1, a conveying mechanism 2, a feeding hopper 3, a detecting mechanism 4, a classifier 5 and a rod cutting mechanism 6. Wherein, the pole cutting mechanism 6 includes: a conveying assembly 7 disposed laterally of the transport mechanism 2 and opposite to the classifier 5; a cutting assembly 8 disposed at an output end of the conveying assembly 7; an outfeed assembly 9 is disposed adjacent to the cutting assembly 8. The bottom of the operating platform 1 can be provided with a plurality of groups of supporting legs and universal wheels, which is beneficial to the movement and the fixation of the machine.

As shown in fig. 2, a feed hopper 3 is mounted at the input end of the transport mechanism 2; the feed hopper 3 is provided with a strip-shaped opening; a feed channel 31 is arranged in the feed hopper 3, and the feed channel 31 extends towards the conveying mechanism 2 and is inclined downwards; the inclination trend in this embodiment is specifically a trend of inclining obliquely downward and then horizontally to the transport mechanism 2; the strip-shaped opening is communicated with the feeding channel 31; the strip-shaped opening and the feeding channel 31 are arranged to enable the feathers to slide onto the conveying mechanism 2 under the action of dead weight and ensure that the feathers are conveyed onto the conveying mechanism 2 according to a set direction, namely, the feathers are conveyed on the conveying mechanism 2 in a state that feather rods face forwards and feather heads face backwards.

A transport mechanism 2 mounted on the operation table 1; the bottom of the transport mechanism 2 may also be provided with a transport bracket, and mounted on the console 1 along the length direction of the console 1 by the transport bracket. In this embodiment, the operation panel 1 is a rectangular operation panel 1, but the shape is not limited thereto; the transport mechanism 2 includes: a first power pack 21, a conveyor belt 22 and a first tensioning roller. The first power unit 21 includes a first driving roller 211, a first driven roller 212 and a motor which are respectively installed at both ends of the transport bracket; the motor drives a first driving roller 211 arranged at one end of the conveying bracket to rotate, so as to drive the conveying belt 22 and a first driven roller 212 arranged at the other end of the conveying bracket to rotate; a conveyor belt 22, which is arranged on the first power unit 21 in a driving way and is positioned on the transportation bracket; the conveyer belt 22 passes through the setting of three roller in folding, winding mode, forms the pretension to conveyer belt 22, avoids conveyer belt 22 to appear loose or too much tight problem, influences the transportation effect of feather.

The detection mechanism 4 sets up in the top of transport mechanism 2 and is located the side of feeder hopper 3, and detection mechanism 4 includes: a detection box, a detector 42 and a display screen 43. The detection box is arranged above the feeding end of the conveying belt 22 and beside the feeding hopper 3 and comprises two side plates 41, the side plates 41 are vertically arranged on the operating platform 1, a detection space is formed in the detection box, and the detection space provides a space for automatically detecting feathers in the transportation process. In this embodiment, the detector 42 is a detection camera mounted in a detection box for detecting feathers on the conveyor belt 22; the detection camera may be disposed above the detection box, and detect the feathers on the conveyor belt 22 in the detection box through the detection channel on the detection box. Of course, the detector 42 may be a laser sensor or an infrared sensor to detect the length of the feathers, and the display screen 43 is mounted on the side plate 41 and is used for displaying the imaging data and grouping result of the detected feathers in real time, so that the operator can monitor the detection result and the feather condition of the detector 42. However, the display screen 43 is not limited to be mounted on the side plate 41, and may be mounted on a structure such as the console 1, as long as it is mounted at a position convenient for a worker to view the feather condition.

The classifier 5 is respectively arranged at the side of the transport mechanism 2 along the transport direction and is used for respectively pushing the classified feathers to different conveying assemblies 7 according to the classified feather groups.

As shown in fig. 3 and 4, the transfer assembly 7 may be provided with a transfer bracket, a transfer belt 71, a guide 72, and a second power pack 73. The conveying support is arranged on one side of the conveying support and forms a preset angle with the conveying support. The second power unit 73 comprises a second driving roller 731, a second driven roller 732 and a motor, wherein the second driving roller 731 and the second driven roller 732 are respectively arranged at two ends of the conveyor belt 71, and the motor is arranged at a position adjacent to the second driving roller 731 and is in transmission connection with the second driving roller. The conveyor belt 71 is installed between the second driving roller 731 and the second driven roller 732, and moves under the driving of the second driving roller 731 and drives the second driven roller 732 to rotate; it is noted here that vertical side guards are mounted on both sides of the conveyor belt 71 to avoid feathers falling during transport; wherein, the side baffle adjacent to the discharging component 9 is provided with a discharging opening with a preset length, and the length of the discharging opening is greater than that of the cut feather, so that the cut feather smoothly slides out from the discharging component 9. The guide portions 72 are installed at the input ends of the conveyor belt 71 and are disposed opposite to the classifiers 5, respectively; the guide portion 72 is in a tendency of shrinking along the conveying direction of the conveyor belt 71, which is beneficial to conveying the feathers in a set direction and improves the consistency and accuracy of the positions of the feathers on the conveyor belt 71. The second tensioning roller comprises three roller shafts, the three roller shafts are respectively arranged at the bottom of the conveying bracket, and the conveying belt 71 passes through the three roller shafts in a folding and winding mode; the second tensioning roller forms a pretensioning tensioning conveyor belt 71, avoiding the phenomenon of loosening or overstretching of the conveyor belt 71.

The cutting assembly 8 includes a blocking portion 81, a cutting portion 82, and a pushing portion 83. The blocking portion 81 is provided at a position adjacent to the end of the conveyor belt 71; the cutting part 82 is provided at one side of the blocking part 81; the pushing portion 83 is located at one side of the cutting portion 82. The blocking portion 81 includes: first baffle 811: is disposed across the conveyor belt 71 and is capable of forming a barrier to feathers on the conveyor belt 71. The first baffle 811 is connected to the output end of the first baffle driver 814, and can be lifted from the conveyor belt 71 by the first baffle driver, so that feathers can enter the cutting portion 82 along with the conveyor belt 71. A sensor is installed at the position adjacent to the cutting part 82 and is used for detecting whether the position of the cutting part 82 has feathers in real time, and once the position of the cutting part 82 has feathers, the first baffle 811 is controlled to descend so as to block the feathers at the rear; and when the feathers at the position of the cutting part 82 are cut and output enough, the feathers are ensured to enter the cutting part 82 one by one. Second baffle 812: the feather is prevented from falling off in the cutting process by being positioned on one side of the first baffle 811 and connected to the output end of the second baffle driver 815; it is noted here that opposing pushers and take-up channels are also mounted on either side of the conveyor belt 22 to facilitate the recovery of feathers beyond the grouping range the length and width of the second barrier 812 is arranged to correspond to the discharge opening in the side barrier to be movable relative to the side barrier to form a seal against the discharge opening. Third baffle 817: located on one side of the second baffle 812, opposite to the first baffle 811, is used to form a barrier for the feather shaft of the feathers so that the feathers stay at a set position in the cutting portion 82. Bearing bar 816: is mounted at the output end of the conveyor belt 71 adjacent to the third baffle 817 and the feather shaft portion of the feathers is located on the bearing bar 816 after the feathers are blocked by the third baffle 817. The support bar 816 is disposed such that the upper side of the support bar 816 is higher than the upper conveyor belt 71. Pressure lever 813: the feather lifting device is opposite to the bearing strip 816 and can move towards the direction of the bearing strip 816 under the driving of the driver, the feather rod is pressed and fixed between the bearing strip 816 and the pressure rod 813, the feather part is lifted off the conveying belt 71, the situation that the conveying belt 71 is pressed by force when the feathers are cut is avoided, and the conveying force of the conveying belt 71 acts on the feathers to cause tearing of the side feathers is avoided. In this embodiment, the first baffle driver 814, the second baffle driver 815, and the third baffle driver may be cylinders, hydraulic cylinders, electric push rods, or the like.

The cutting part 82 may be provided with a cutting support 821, a cutting cylinder 822, a connection block 823, a cutting driving shaft 824, a fixed cutter 825, and a rotary cutter 826. The cutting bracket 821 is fixed to one side of the conveyor 71 and is disposed opposite to the second barrier 812. Specifically, the cutting bracket 821 may be fixed to the side fence on the side of the conveyor 71 or may be fixed to the console 1 on the side of the conveyor 71. A cutting cylinder 822 mounted on the cutting support 821. The output end of the cutting cylinder 822 is connected with a connecting block 823; a cutting drive shaft 824 is mounted on the connection block 823. The rotary cutter 826 is rotationally connected with the cutting bracket 821 through a rotating shaft, a sliding connecting groove extending along the length direction of the rotary cutter 826 is arranged on the cutter handle of the rotary cutter, and the cutting driving shaft 824 passes through the sliding connecting groove to be in sliding connection with the cutter handle of the rotary cutter 826; when the connection block 823 moves up and down under the driving of the cutting cylinder 822, the rotary cutter 826 can be driven to rotate on the cutting bracket 821 through the cooperation of the cutting driving shaft 824 and the sliding connection groove, so that the cutting action of the rotary cutter 826 is formed. A fixed cutter 825, the handle of which is fixedly installed on the cutting support 821, the cutter body extends along one side of the bearing bar 816 adjacent to the third baffle 817, such that the cutter body of the fixed cutter 825 is located at one side of the cutter body of the rotary cutter 826, and such that the rotary cutter 826 is disposed opposite to the blade of the fixed cutter 825, and when the rotary cutter 826 rotates on the cutting support 821, the blade of the rotary cutter 826 can be overlapped with the blade of the fixed cutter 825, thereby cutting feathers.

The outfeed assembly 9 may be provided with a waste channel 91 mounted at the output end of the conveyor belt 71; the waste channel 91 is used for conveying the feather bars cut according to design requirements; the discharging channel 92 is arranged opposite to the pushing part 83, and after the feather cutter is used, the cut feathers can be pushed by the pushing part 83, so that the feathers can slide out through the discharging channel 92.

The classifier 5, the pushing part 83 and the pusher in the present embodiment may be an air tap, a push rod or a fan; the classifier 5 can automatically push the feathers, and push the feathers to the rod cutting mechanism 6; the pushing part 83 realizes automatic pushing of the feathers and pushes the feathers to the discharging component 9; the pusher realizes automatic pushing of the feathers, and the feathers are pushed to the receiving channel.

The implementation principle of the visual classification plume cutting machine in the embodiment is as follows: the feathers are put into the feeding channel 31 in a state that the feather rods are forward and the feather heads are backward through manual operation, and the feathers slide onto the conveying belt 22 under the action of dead weight and are conveyed into a detection space along with the conveying belt 22; the detector 42 shoots and detects the feathers and feeds imaging data back to the controller, the controller processes the imaging data to obtain the lengths of the feathers, the feathers are grouped according to grouping requirements, the data of the feather grouping result and the feather length are fed back on the display screen 43, namely the feathers are divided into three length groups of middle length and short length according to the lengths of the feathers, and the feather groups are displayed on the display screen 43. The feather is conveyed along with the conveying belt 22, the controller controls the corresponding classifier 5 to start according to the grouping result of the feather, and the feather is pushed into the guide part 72 of the corresponding group; when the feathers are guided by the guide portion 72 to enter the conveyor belt 71 and approach the first baffle 811, a sensor provided near the cutting portion 82 detects whether or not the feathers are present in the cutting portion 82; if so, the first baffle 811 is controlled to move downwards to block the feathers, so that a plurality of feathers and colleagues are prevented from entering the position of the cutting part 82, otherwise, the first baffle is not moved, and the feathers smoothly enter the position of the cutting part 82. The second baffle 812 is positioned to block the discharge opening and to block the feathers from falling into the discharge channel 92. The feathers stay at a position spaced from the third baffle 817 by the third baffle 817, and at the same time, the driver of the third baffle drives the pressing rod 813 to move downward and press the feather shaft portion of the feathers, so that the feathers tilt up on the raised bearing bar 816 and are no longer in contact with the conveyor belt 71. Then the cutting cylinder 822 pushes the cutting driving shaft 824 on the connecting block 823 to move upwards, and drives the cutter body of the rotary cutter 826 to rotate, so that a cutting action is formed, and a feather rod with the required length is cut off. After cutting, the rotary cutter 826 is lifted upwards, the driving part drives the second baffle 812 to lift, and the pushing part 83 is controlled to push the feathers to fall into the discharging channel 92 and be discharged through the discharging channel 92. The cut down plume portion falls down to the waste channel 91 under its own weight.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (10)

1. The utility model provides a visual classification cuts feather pole machine, includes operation panel (1), its characterized in that still includes:

A transport mechanism (2) mounted on the operation table (1);

The feed hopper (3) is arranged at the input end of the conveying mechanism (2);

The detection mechanism (4) is arranged above the conveying mechanism (2) and is positioned at the side of the feed hopper (3);

At least three groups of classifiers (5) which are respectively arranged at the side of the conveying mechanism (2) along the conveying direction;

At least three sets of rod cutting mechanisms (6) arranged on the opposite side of the conveying mechanism (2) from the classifier (5);

wherein, the cutting rod mechanism (6) comprises: the conveying assembly (7) is arranged at the side of the conveying mechanism (2) and is opposite to the classifier (5);

The cutting assembly (8) is arranged at the output end of the conveying assembly (7);

-a discharge assembly (9) arranged adjacent to the cutting assembly (8).

2. The vision sorting plume machine of claim 1, wherein: the transport mechanism (2) comprises:

The first power groups (21) are arranged at two ends of the operating platform (1);

a conveyor belt (22) mounted on the first power pack (21);

a first tensioning roller forming a pretensioning force tensioning the conveyor belt (22).

3. The vision sorting plume machine of claim 2, wherein: the detection mechanism (4) comprises:

At least two side plates (41) vertically mounted on the operation table (1); a detection space is formed between the side plates (41);

a detector (42) mounted between the side plates (41) with an imaging direction toward the conveyor belt (22);

and a display screen (43) mounted on the side plate (41).

4. The vision sorting plume machine of claim 2, wherein: the transfer assembly (7) comprises:

A conveyor belt (71) which is provided on one side of the conveyor belt (22) and forms a predetermined angle with the conveyor belt (22);

A guide part (72) which is installed at the input end of the conveyor belt (71) and is arranged opposite to the classifier (5); the guide part (72) tends to shrink along the conveying direction of the conveyor belt (71);

A second power unit (73) mounted at both ends of the conveyor belt (71);

and a second tensioning roller for forming a pretension to tension the conveyor belt (71).

5. The vision sorting plume machine of claim 4, wherein: the cutting assembly (8) comprises:

A blocking portion (81) provided adjacent to an end of the conveyor belt (71);

A cutting part (82) arranged on one side of the blocking part (81);

And a pushing part (83) positioned at one side of the cutting part (82).

6. The vision sorting plume machine of claim 5, wherein: the outfeed assembly (9) comprises:

a waste channel (91) mounted at the output end of the conveyor belt (71);

and a discharge channel (92) which is arranged opposite to the pushing part (83).

7. The vision sorting plume machine of claim 2, wherein: a feeding channel is arranged in the feeding hopper (3); the feed channel extends toward the conveyor belt (22) and is inclined downward.

8. The vision sorting plume machine of claim 5, wherein: the blocking portion (81) includes:

A first baffle (811) provided on the conveyor belt (71) and connected to an output end of the first baffle driver (814);

a second barrier (812) located at one side of the first barrier (811) and connected to an output end of a second barrier driver (815);

A bearing bar (816) mounted at the output end of the conveyor belt (71);

the pressure bar (813) is arranged opposite to the pressure-bearing bar (816) and can move towards the conveyor belt (71) under the drive of the driver;

And a third baffle (817) which is arranged on one side of the bearing strip (816) away from the conveyor belt (71) and is arranged at a set distance from the bearing strip (816).

9. The vision sorting plume machine of claim 8, wherein: the cutting section (82) includes:

A cutting bracket (821) mounted on the side of the bearing bar (816);

a cutting cylinder (822) mounted on the cutting support (821); the output end of the cutting cylinder (822) is connected with a connecting block (823); a cutting driving shaft (824) is arranged on the connecting block (823);

A fixed cutter (825) with a cutter handle fixed on the cutting support (821), and a cutter body extending along one side of the bearing bar (816) adjacent to the third baffle (817);

And the rotary cutter (826) is rotationally connected with the cutting support (821), a sliding connection groove which is in sliding connection with the cutting driving shaft (824) is arranged on the cutter handle, and the cutter body is positioned on one side of the cutter body of the fixed cutter (825).

10. The vision sorting plume machine of claim 4, wherein: the first power group (21) comprises a first driving roller (211) and a first driven roller (212), and the first driving roller (211) and the first driven roller (212) are respectively arranged at two ends of the conveying belt (22); the second power unit (73) comprises a second driving roller (731) and a second driven roller (732), and the second driving roller (731) and the second driven roller (732) are respectively arranged at two ends of the conveyor belt (71).