CN210253187U - Foreign matter removing device and visual sorting device - Google Patents

Abstract

The utility model provides a foreign matter removing devices and vision sorting device. The foreign matter removing device is used for removing foreign matters from materials and comprises an adsorption mechanism and a material receiving mechanism, wherein the adsorption mechanism comprises a suction nozzle and a first air extraction device, the suction nozzle is connected with the first air extraction device, and the suction nozzle is set to be in a size that the foreign matters are adsorbed on the suction nozzle through the suction of the first air extraction device; the receiving mechanism comprises a receiving hopper and a second air extracting device, the second air extracting device comprises an air extracting pipe, the air extracting pipe is communicated with the receiving hopper, the receiving hopper is used for receiving the foreign matters released from the suction nozzle of the adsorption mechanism, and the second air extracting device is used for extracting the foreign matters received by the receiving hopper through the air extracting pipe. The adsorption mechanism and the material receiving mechanism are similar to a person who adopts hands to inspect, one hand is used for inspecting, and the other hand is used for collecting picked-up foreign matters, so that the foreign matters are sorted flexibly, controllably and accurately.

Description

Foreign matter removing device and visual sorting device

Technical Field

The utility model relates to a rejection technique especially relates to foreign matter removing devices and vision sorting device.

Background

In the field of color sorting, foreign matter removal operation needs to be performed on materials conveyed by a material conveying mechanism. Due to the different shapes of the foreign matters, the purpose of accurately removing the foreign matters such as the flying cotton and the hair with small volume and light weight cannot be realized by using the conventional blowing removing method. In addition, when a device such as an integral cleaner is employed, since the suction and the extraction of foreign matter are both operated by the same suction port of the same device, the sorting operation of foreign matter is inflexible, uncontrollable and inaccurate.

SUMMERY OF THE UTILITY MODEL

In view of the problem that exists among the background art, the utility model aims to provide a foreign matter removing devices and a vision sorting device, its flexible operation, controllable and the accuracy that enables the letter sorting foreign matter.

In order to achieve the above object, in a first aspect, the present invention provides a foreign matter removing device for removing foreign matters from materials, comprising an adsorption mechanism and a material receiving mechanism, wherein the adsorption mechanism comprises a suction nozzle and a first air extractor, the suction nozzle is connected to the first air extractor, and the suction nozzle is sized to make the foreign matters adsorbed on the suction nozzle by suction of the first air extractor; the receiving mechanism comprises a receiving hopper and a second air extracting device, the second air extracting device comprises an air extracting pipe, the air extracting pipe is communicated with the receiving hopper, the receiving hopper is used for receiving the foreign matters released from the suction nozzle of the adsorption mechanism, and the second air extracting device is used for extracting the foreign matters received by the receiving hopper through the air extracting pipe.

In one embodiment, the suction nozzle of the suction mechanism comprises a body part and a partition plate, wherein the body part is provided with an end face, a first cavity and a second cavity are arranged in the body part, the outer end of the first cavity is communicated with the first air extractor, and the end face of the second cavity is provided with an opening; the baffle sets up in the hookup location of first chamber and second chamber in order to separate first chamber and second chamber, and the baffle is provided with the perforating hole, and the perforating hole is with first chamber and second chamber intercommunication, and the size of perforating hole sets up to prevent the foreign matter to pass through.

In one embodiment, the body portion comprises a first hollow right frustum and a second hollow inverted frustum, the first hollow right frustum and the second hollow inverted frustum are connected together and form the second cavity, the second hollow inverted frustum forms the opening, and the position where the first hollow right frustum and the second hollow inverted frustum are connected together forms the connecting hole.

In one embodiment, the body of the nozzle is a soft body.

In one embodiment, the suction mechanism further comprises a sensor disposed within the suction nozzle and sensing a change in air pressure.

In one embodiment, the diameter of the first lumen is smaller than the diameter of the second lumen.

In one embodiment, the foreign matter removing device further comprises a first driving mechanism, the first driving mechanism comprises a connecting frame, and a suction nozzle of the adsorption mechanism is installed on the connecting frame; the adsorption mechanism further comprises a first pipe, a second pipe and a spring; the first pipe is fixed in the link, and the one end of first pipe is connected in first air exhaust device, and the one end of second pipe is located to the other end cover of first pipe, and the other end of second pipe is connected in the suction nozzle, and the spring setting is established the inside of partly at the cover of first pipe and second pipe to make the second pipe can stretch out and draw back relatively first pipe.

In one embodiment, the receiving hopper is provided with a receiving groove, and the receiving groove is connected and communicated with the air suction pipe.

In one embodiment, the foreign matter removing device further comprises a blowing mechanism and a switching valve, wherein the blowing mechanism is communicated with the switching valve; the suction nozzle and the first air extractor are communicated with the switching valve; the switching valve switches the communication between the suction nozzle and the first air extractor and the communication between the suction nozzle and the air blowing mechanism.

In order to realize the above-mentioned purpose, in the second aspect, the utility model provides a vision sorting device, it includes material conveying mechanism and identification mechanism, and material conveying mechanism is used for carrying the material, and identification mechanism is relative with material conveying mechanism and discerns the foreign matter in the material, and vision sorting device still includes according to the utility model discloses the first aspect foreign matter removing device, foreign matter removing device and discernment material communication connection reject the foreign matter from the material.

The utility model has the advantages as follows: the adsorption mechanism and the material receiving mechanism of the foreign matter removing device are similar to those of a person who adopts hands to inspect, one hand is used for inspecting, the other hand is used for collecting picked-up foreign matters, and compared with a blowing mode in the background technology or a device such as an integrated dust collector in the background technology, the foreign matter removing device is flexible, controllable and accurate in foreign matter sorting operation.

Drawings

Fig. 1 is a schematic view of a visual sorting apparatus according to the present invention, wherein a foreign matter removing device of the visual sorting apparatus is in an operating state and some components of the foreign matter removing device are schematically shown by dotted lines.

Fig. 2 is another schematic view of the visual sorting apparatus of fig. 1, in which the foreign matter removal apparatus is in another state and the components shown by the dotted lines of fig. 1 are removed.

Fig. 3 is a sectional view of the suction nozzle of the suction mechanism of the foreign matter removing apparatus according to the present invention.

Wherein the reference numerals are as follows:

f foreign matter 2 receiving mechanism

M material 21 receiving hopper

M1 material conveying mechanism 211 holding groove

M2 second air extractor of recognition mechanism 22

M3 mechanical separating mechanism 221 exhaust tube

M4 foreign matter removing device 222 vacuum generator

1 adsorption mechanism 23 containing box

11 first driving mechanism for suction nozzle 3

111 body 31 slide rail

111a end face 311 dovetail groove

P opening 32 slider

111b first cavity 321 protrusions

111c second chamber 33 first power means

111d first hollow right frustum 34 connecting frame

111e second hollow inverted truncated cone 341 plate portion

H-shaped connecting hole 342 fork part

112 second driving mechanism of partition board 4

112a through hole 41 slide plate

113 fixed seat 42 guide rail

113a inner cavity 43 second power means

12 first air extractor 44 connecting plate

13 first tube 5 blowing mechanism

14 second tube 51 compressed gas bottle

15 first nut 52 pressure control valve

151 first flange 6 switching valve

16 second nut 7 third driving mechanism

161 second flange 8 control mechanism

Detailed Description

The accompanying drawings illustrate embodiments of the present invention and it is to be understood that the disclosed embodiments are merely exemplary of the invention, which can be embodied in various forms, and therefore, specific details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention.

Further, expressions of directions indicated for explaining operations and configurations of respective members in the embodiment, such as upper, lower, left, right, front, and rear, are not absolute but relative, and although these indications are appropriate when the respective members are in the positions shown in the drawings, when the positions are changed, the directions should be interpreted differently to correspond to the changes.

Fig. 1 is a schematic view of a visual sorting apparatus according to the present invention, wherein a foreign material removing apparatus M4 of the visual sorting apparatus is in an operating state and some components of the foreign material removing apparatus M4 are schematically shown by dotted lines. Fig. 2 is another schematic view of the visual sorting apparatus of fig. 1, in which the foreign matter removal apparatus M4 is in another state and the components shown by the dotted lines of fig. 1 are removed. Fig. 3 is a sectional view of the suction nozzle 11 of the suction mechanism 1 of the foreign matter removing device M4 according to the present invention.

As shown in fig. 1, the visual sorting apparatus includes a material conveying mechanism M1, a recognition mechanism M2, and a foreign matter removal device M4. Depending on the actual situation, the visual sorting apparatus may also include a mechanical separating mechanism M3.

The material conveying mechanism M1 is used for conveying the material M. In one embodiment, the material conveying mechanism M1 is a belt conveyor. The belt of the belt conveyor conveys the material M horizontally.

The identifying mechanism M2 is opposed to the material conveying mechanism M1 and identifies the foreign matter F in the material M. Specifically, the recognition mechanism M2 may have a function of determining the interval between the foreign matter F and the material M around it, in addition to the function of recognizing the foreign matter F from the material M. For these functions, the recognition means M2 may be implemented, for example, using a camera with commercially available or well-known image processing.

The mechanical separating mechanism M3 separates the foreign matter F from the material M around the foreign matter F to a desired interval so that the foreign matter removing device M4, when in operation, only adsorbs the foreign matter F without adsorbing the material M around the foreign matter F. The operation of the mechanical disconnect mechanism M3 is typically dependent on communication with the identification mechanism M2 to determine whether activation is required. The mechanical separating mechanism M3 may be a robot, a three-dimensional moving robot arm, a brush, or the like.

The foreign matter removing device M4 is in communication connection with the identification mechanism M2 and removes the foreign matter F from the material M.

The foreign matter removing device M4 includes an adsorption mechanism 1 and a receiving mechanism 2. The foreign matter removal device M4 may further include a first driving mechanism 3 according to actual operation needs. The foreign matter removal device M4 further includes a second drive mechanism 4 according to actual operation needs. The foreign matter removing device M4 may further include a blowing mechanism 5 and a switching valve 6 according to actual operation requirements. The foreign matter removal device M4 may further include a third driving mechanism 7 according to actual operation needs. The foreign matter removing device M4 may further include a control mechanism 8 according to actual operation needs.

The suction mechanism 1 includes a suction nozzle 11 and a first suction device 12. Depending on the actual situation, the adsorption mechanism 1 may further include a first tube 13, a second tube 14, and a spring (not shown). The adsorption mechanism 1 may further include a first nut 15 and a second nut 16. The adsorption mechanism 1 may further include a sensor (not shown) which is provided in the suction nozzle 11 and senses a change in air pressure to determine whether the foreign matter F is adsorbed and whether the release of the foreign matter F is successful.

The suction nozzle 11 is connected to a first suction device 12. The suction nozzle 11 is dimensioned such that suction via the first suction device 12 causes foreign objects F to be attracted to the suction nozzle 11 (but not to the line between the suction nozzle 11 and the first suction device 12). For slender foreign bodies such as hair threads, the diameter is much smaller than the length, so that the outer diameter of the suction nozzle 11 is smaller than the length of the foreign bodies but larger than the diameter of the foreign bodies; for a foreign matter of the meandering extension type, such foreign matter has two-dimensional dimensions in planar projection, and the outer diameter of the suction nozzle 11 is smaller than one of the two-dimensional dimensions but the outer diameter of the suction nozzle 11 is larger than the other one of the two-dimensional dimensions. Likewise, for the flying foreign matter, such foreign matter has two-dimensional dimensions in planar projection as long as the outer diameter of the suction nozzle 11 is smaller than one of the two-dimensional dimensions but the outer diameter of the suction nozzle 11 is larger than the other one of the two-dimensional dimensions. In these cases, the foreign matter F is adsorbed and rested on the suction nozzle 11 by suction via the first suction device 12, and since the outer diameter of the suction nozzle 11 is larger than the corresponding one size of the foreign matter F, the first suction device 12 maintains the state in which the foreign matter F is adsorbed and rested on the suction nozzle 11 by maintaining suction. Of course, the suction nozzle 11 may be sized to allow the foreign matter F to enter the suction nozzle 11 but not the duct between the suction nozzle 11 and the first air extractor 12, in cooperation with the through-holes 112a of the rear partition, and this situation is still considered to be the foreign matter F adhering to the suction nozzle 11.

The suction nozzle 11 of the suction mechanism 1 includes a body portion 111 and a partition plate 112. The suction nozzle 11 further comprises a fixing base 113 according to the actual connection requirement.

The main body 111 has an end surface 111a, a first chamber 111b and a second chamber 111c are provided in the main body 111, an outer end of the first chamber 111b is communicated with the first air extractor 12, and the second chamber 111c has an opening P at the end surface 111 a. The diameter of the first chamber 111b is smaller than that of the second chamber 111c, thereby facilitating the volume expansion of the air blown by the air blowing mechanism 5 from the first chamber 111b to the second chamber 111c, thereby reducing the speed and pressure of the air blowing, and reliably receiving the foreign matter F adsorbed on the suction nozzle 11 by the receiving hopper 21 while releasing it. The body portion 111 includes a first hollow right frustum 111d and a second hollow reverse frustum 111e, the first hollow right frustum 111d and the second hollow reverse frustum 111e being connected together and forming a second chamber 111 c. The second hollow inverted frustum 111e forms an opening P, and a connection hole H is formed at a position where the first hollow right frustum 111d and the second hollow inverted frustum 111e are connected together. The opening P and the connection hole H form a position where the foreign matter F bridges over the suction nozzle 11, enhancing the reliability of the suction nozzle 11 in absorbing the foreign matter F. Furthermore, the air blown out by the air blowing mechanism 5 is subjected to volume contraction in the first hollow truncated cone 111d toward the connecting hole H and volume expansion in the second hollow truncated cone 111e from the connecting hole H, and the change of the volume contraction to the volume expansion lowers the speed and pressure of air blowing and simultaneously forms a sudden ejection force, thereby further facilitating soft but strong release of the foreign matter F adsorbed on the suction nozzle 11. The body 111 is a soft body, such as rubber. With the soft body portion, when the first air extractor 12 sucks air, the soft body portion (specifically, the inner surface of the second hollow inverted truncated cone 111e) is deformed by the sucked air, increasing the suction area of the foreign matter F, and further stabilizing the suction of the foreign matter F on the suction nozzle 11.

A partition plate 112 is provided at a connection position of the first and second chambers 111b and 111c to partition the first and second chambers 111b and 111c, and the partition plate 112 is provided with a through hole 112 a. The through hole 112a communicates the first chamber 111b and the second chamber 111 c. The through-hole 112a is sized to prevent the passage of foreign matter F. The through hole 112a prevents the foreign matter F from passing through the suction nozzle 11 when the size is too small, and further prevents the switching valve 6 from being clogged and the first air extractor 12 from being sucked, thereby ensuring that the usability of the switching valve 6 and the first air extractor 12 is not affected by the foreign matter F. The distribution of the through holes 112a may be determined according to the minimum diameter in the first and second cavities 111b and 111c and the size of the foreign materials F.

The fixing base 113 includes an inner cavity 113a, the inner cavity 113a connects the first cavity 111b and the first pumping device 12, and the fixing base 113 connects the main body 111 and the first pumping device 12. The arrangement of the fixing base 113 can make the connection between the suction nozzle 11 and the first suction device 12 more flexible and diversified.

The first air extractor 12 may take any known configuration. For example, a vacuum device can also be used.

The first tube 13 is fixed to the first driving mechanism 3 (specifically, a connecting bracket 34 described later), one end of the first tube 13 is connected to the first air extractor 12, the other end of the first tube 13 is fitted over one end of the second tube 14, the other end of the second tube 14 is connected to the suction nozzle 11, and the spring is provided inside the fitted portion of the first tube 13 and the second tube 14 so that the second tube 14 can be extended and retracted relative to the first tube 13. The second pipe 14 can stretch out and draw back relatively first pipe 13, can avoid adsorption apparatus 1 to produce hard striking when the material conveying mechanism M1 motion in transport material M under the drive of first actuating mechanism 3 to protect adsorption apparatus 1 and material conveying mechanism M1.

The first nut 15 is fixed to the first pipe 13, the first nut 15 has a first flange 151 projecting radially outward, the second nut 16 is fixed to the first pipe 13, the second nut 16 has a second flange 161 projecting radially outward, and the first flange 151 and the second flange 161 are opposed to and spaced apart from each other.

The receiving mechanism 2 includes a receiving hopper 21 and a second air extractor 22. Depending on the actual situation, the receiving mechanism 2 may further include a receiving box 23.

The receiving hopper 21 receives foreign matters F released from the suction nozzles 11 of the suction mechanism 1. The receiving hopper 21 has a receiving groove 211, the receiving groove 211 receives the foreign matters F released from the suction nozzle 11 by the suction mechanism 1, and after the suction mechanism 1 releases the foreign matters F from the suction nozzle 11, the suction mechanism 1 can perform the next suction without considering whether the released foreign matters F are drawn away by the receiving mechanism 2, thereby improving the working efficiency of the foreign matter removing device M4. The accommodating groove 211 is connected and communicated with the second air extractor 22 (specifically, the air extracting pipe 221), so that the foreign matters F accommodated in the accommodating groove 211 are extracted away through the second air extractor 22 (specifically, the air extracting pipe 221).

The second pumping device 22 comprises a pumping duct 221. The second air extractor 22 is used for extracting the foreign matters F received by the receiving hopper 21 through the air extracting pipe 221. Depending on the application, the second pumping device 22 may further comprise a vacuum generator 222. The air exhaust pipe 221 is communicated with the receiving hopper 21. The vacuum generator 222 is mounted on the suction pipe 221, thereby improving the integration of the components.

The housing box 23 communicates with the suction pipe 221, and the housing box 23 houses the foreign matter F sucked through the suction pipe 221 and the vacuum generator 222.

The first drive mechanism 3 is connected to the adsorption mechanism 1. The first driving mechanism 3 drives the adsorption mechanism 1 to move relative to the foreign body F. Of course, the first driving mechanism 3 may not be required, and a manual mode may be directly adopted.

The first driving mechanism 3 includes a slide rail 31, a slider 32, and a first power unit 33. Depending on the actual situation, the first driving mechanism 3 may also comprise a connecting frame 34.

The slide rail 31 has a dovetail groove 311.

The slider 32 is slidably mounted on the slide rail 31. The slider 32 has the suction nozzle 11 of the suction mechanism 1 mounted thereon. As shown in fig. 1, the slider 32 has a protrusion 321 that fits into the dovetail groove 311, and the protrusion 321 of the slider 32 is housed in the dovetail groove 311 and slides in the dovetail groove 311. The matching of the dovetail groove 311 and the protrusion 321 is beneficial to maintaining the stability of the moving direction of the slider 32, and further beneficial to ensuring the positioning accuracy of the suction nozzle 11.

The first power device 33 is connected to the sliding block 32 to drive the sliding block 32 to move along the sliding rail 31. The first power device 33 may employ an air cylinder, a lead screw transmission mechanism, or the like. In the movement mode shown in fig. 1, it is sufficient that the movement in the corresponding direction (for example, up and down or vertical as shown in the figure) can be realized.

The link 34 has the suction nozzle 11 of the suction mechanism 1 mounted thereon, and the link 34 is mounted on the slider 32. The link 34 includes a plate portion 341 and a fork portion 342. The fork 342 is interposed between the first flange 151 and the second flange 161 and is sandwiched and fixed by the first flange 151 and the second flange 161, and the plate portion 341 is connected at one end to the fork 342 and at the other end to the slider 32.

The second driving mechanism 4 is connected to the material receiving mechanism 2, and the second driving mechanism 4 drives the material receiving mechanism 2 to move relative to the suction nozzle 11 of the adsorption mechanism 1. Of course, the second driving mechanism 4 may not be required, and a manual mode may be directly adopted.

The second drive mechanism 4 includes a slide plate 41, a guide rail 42, and a second power unit 43. Depending on the actual use, the second driving mechanism 4 may further comprise a connecting plate 44.

The slide plate 41 is inserted through the guide rail 42 and slidably engaged therewith. The slide plate 41 has the receiving hopper 21 and the second air extractor 22 of the receiving mechanism 2 mounted thereon.

The guide rail 42 intersects the slide rail 31 (preferably vertically, i.e., the slide plate 41 moves in a horizontal direction) and is fixedly connected together.

The second power device 43 is connected to the slide plate 41 to move the slide plate 41 along the guide rail 42.

One end of the connecting plate 44 is fixed to the sliding plate 41, and the other end of the connecting plate 44 is sleeved and fixed to the air exhaust pipe 221.

The blowing mechanism 5 is communicated with the switching valve 6. The air blowing mechanism 5 reliably releases the foreign matter F adsorbed to the suction nozzle 11 by air blowing.

The blowing mechanism 5 includes a compressed gas bottle 51 and a pressure control valve 52. The compressed gas bottle 51 is communicated with the switching valve 6, and the compressed gas bottle 51 supplies gas via a certain velocity and pressure to reliably release the foreign matter F adsorbed to the suction nozzle 11 with such gas having the velocity and pressure. The pressure control valve 52 is provided on a passage through which the compressed gas cylinder 51 communicates with the switching valve 6.

The switching valve 6 communicates the suction nozzle 11 and the first suction device 12 therewith. The switching valve 6 switches the communication between the suction nozzle 11 and the first suction device 12 and the communication between the suction nozzle 11 and the air blowing mechanism 5. The adoption of the switching valve 6 is beneficial to simplifying the pipelines of the adsorption mechanism 1 and the blowing mechanism 5 and improving the component integration level of the foreign matter removing device M4.

The third driving mechanism 7 is fixedly connected to the slide rail 31 to drive the slide rail 31 to move. The third driving mechanism 7 may be a robot, a three-dimensional moving robot, or the like.

The control mechanism 8 is in communication with the first air extractor 12, the second air extractor 22, the first power device 33, the second power device 43, the air blowing mechanism 5, the pressure control valve 52, the switching valve 6, and the third driving mechanism 7 to control the operations thereof. Of course, the control mechanism 8 can also be connected with the material conveying mechanism M1, the recognition mechanism M2 and the mechanical separation mechanism M3 in a communication mode to realize full automation of the visual sorting device.

In summary, the suction mechanism 1 and the receiving mechanism 2 of the foreign matter removing device M4 are similar to a person who uses hands to pick up foreign matters by using two hands, one hand picks up foreign matters, and the other hand collects picked up foreign matters, so that the foreign matter removing device M4 is flexible, controllable and accurate in foreign matter sorting operation, compared with the air blowing method in the background art and compared with the device in the background art such as an integrated dust collector.

Note that, in the present invention, the aforementioned communication may be performed in a wired or wireless manner. The foreign matter removing device M4 is not limited to a visual sorting device, and may be applied to any occasion where accurate sorting is required. The visual sorting device is not limited to the field of color sorting, but can be applied to any required technical field.

The above detailed description describes exemplary embodiments, but is not intended to limit the combinations explicitly disclosed herein. Thus, unless otherwise specified, various features disclosed herein can be combined together to form a number of additional combinations that are not shown for the sake of brevity.

Claims (10)

1. A foreign matter removing device (M4) is used for removing foreign matters (F) from materials (M) and is characterized by comprising an adsorption mechanism (1) and a material receiving mechanism (2),

the adsorption mechanism (1) comprises a suction nozzle (11) and a first air extraction device (12), the suction nozzle (11) is connected to the first air extraction device (12), and the suction nozzle (11) is sized to adsorb the foreign matters (F) to the suction nozzle (11) through the suction of the first air extraction device (12);

the receiving mechanism (2) comprises a receiving hopper (21) and a second air extracting device (22), the second air extracting device (22) comprises an air extracting pipe (221), the air extracting pipe (221) is communicated with the receiving hopper (21), the receiving hopper (21) is used for receiving the foreign matters (F) released from the suction nozzle (11) of the adsorption mechanism (1), and the second air extracting device (22) is used for extracting the foreign matters (F) received by the receiving hopper (21) through the air extracting pipe (221).

2. The foreign matter removal device (M4) according to claim 1,

the suction nozzle (11) of the adsorption mechanism (1) comprises a body part (111) and a partition plate (112), wherein the body part (111) is provided with an end face (111a), a first cavity (111b) and a second cavity (111c) are arranged in the body part (111), the outer end of the first cavity (111b) is communicated with the first air extraction device (12), and the second cavity (111c) is provided with an opening (P) on the end face (111 a);

a partition plate (112) is provided at a connecting position of the first chamber (111b) and the second chamber (111c) to partition the first chamber (111b) and the second chamber (111c), the partition plate (112) is provided with a through hole (112a), the through hole (112a) communicates the first chamber (111b) and the second chamber (111c), and the through hole (112a) is sized to prevent the passage of foreign matter (F).

3. The foreign matter removal device (M4) according to claim 2, wherein the body portion (111) includes a first hollow right truncated cone (111d) and a second hollow inverted truncated cone (111e), the first hollow right truncated cone (111d) and the second hollow inverted truncated cone (111e) are connected together and form the second chamber (111c), the second hollow inverted truncated cone (111e) forms the opening (P), and a connection hole (H) is formed at a position where the first hollow right truncated cone (111d) and the second hollow inverted truncated cone (111e) are connected together.

4. The foreign matter removal device (M4) according to claim 2, wherein the body (111) of the suction nozzle (11) is a soft body.

5. The foreign matter removal device (M4) according to claim 1, wherein the suction mechanism (1) further comprises a sensor that is provided in the suction nozzle (11) and senses a change in air pressure.

6. The foreign matter removal device (M4) according to claim 2, wherein a diameter of the first cavity (111b) is smaller than a diameter of the second cavity (111 c).

7. The foreign matter removal device (M4) according to claim 1,

the foreign matter removing device (M4) also comprises a first driving mechanism (3),

the first driving mechanism (3) comprises a connecting frame (34), and a suction nozzle (11) of the adsorption mechanism (1) is arranged on the connecting frame (34);

the adsorption mechanism (1) further comprises a first pipe (13), a second pipe (14) and a spring;

the first pipe (13) is fixed on the connecting frame (34), one end of the first pipe (13) is connected to the first air extracting device (12), the other end of the first pipe (13) is sleeved on one end of the second pipe (14), the other end of the second pipe (14) is connected to the suction nozzle (11), and the spring is arranged inside the sleeved portion of the first pipe (13) and the second pipe (14) so that the second pipe (14) can stretch relative to the first pipe (13).

8. The foreign matter removal device (M4) according to claim 1,

the receiving hopper (21) is provided with a receiving groove (211), and the receiving groove (211) is connected and communicated with the air extraction pipe (221).

9. The foreign matter removal device (M4) according to claim 1,

the foreign matter removing device (M4) further comprises a blowing mechanism (5) and a switching valve (6), wherein the blowing mechanism (5) is communicated with the switching valve (6);

the suction nozzle (11) and the first air extracting device (12) are communicated with the switching valve (6);

the switching valve (6) switches the communication between the suction nozzle (11) and the first air extractor (12) and the communication between the suction nozzle (11) and the air blowing mechanism (5).

10. A visual sorting device comprising a material conveying means (M1) and a recognition means (M2), the material conveying means (M1) being adapted to convey material (M), the recognition means (M2) being opposite the material conveying means (M1) and recognizing foreign bodies (F) in the material (M), characterized in that the visual sorting device further comprises a foreign body rejecting device (M4) according to any one of claims 1 to 9, the foreign body rejecting device (M4) being in communication with the recognition means (M2) and rejecting the foreign bodies (F) from the material (M).

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