CN216188929U - Device for vertically sorting materials from continuous whole conveying surface - Google Patents

Abstract

A device for vertically sorting materials from a continuous whole conveying surface comprises a supporting system, a lifting system, a cargo carrying platform and a receiving and conveying system, wherein the lifting system is arranged on the supporting system and comprises a high-end lifting system and a low-end lifting system; by using the vertical sorting machine, the materials needing to be sorted can be directly transferred to another conveying height on the original conveying surface, and the normal conveying of other materials on the original conveying surface is not influenced.

Description

Device for vertically sorting materials from continuous whole conveying surface

Technical Field

The utility model belongs to the technical field of material sorting, and particularly relates to a device for vertically sorting materials from a continuous whole conveying surface.

Background

In the existing logistics processing technology of luggage, packages and the like, due to the fact that the materials are air-permeable, the materials are not suitable for being adsorbed by a sucker, if the materials need to be vertically sorted from a main conveying line, the materials are mainly sorted by a vertical lift, a vertical swing arm sorting machine and other equipment, the equipment needs to divide the main conveying line, an inlet and an outlet of the sorting machine are respectively butted with the main conveying upstream equipment and the main conveying downstream equipment, and the materials cannot be directly grabbed and sorted from the whole conveying surface of the existing main conveying line; for simultaneously processing irregular materials with non-uniform materials, specifications, shapes and weights, no solution for vertically sorting the materials directly from the whole conveying surface of the existing main conveying line exists at present. In particular to sorting the luggage upwards from the conveying surface of equipment such as a luggage rotary table, a whole width belt conveyor and the like.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a device for vertically sorting materials from a continuous whole conveying surface, by using the vertical sorting machine, the materials to be sorted can be directly transferred to another conveying height on the original conveying surface, and meanwhile, the normal conveying of other materials on the original conveying surface is not influenced; the original material conveying platform can be a horizontal plane or an inclined plane, and after vertical sorting, the material conveying state can be controlled to be the horizontal plane or the inclined plane.

In order to solve the technical problems, the utility model adopts the following technical scheme:

including braced system, operating system, carry cargo bed and connect and get conveying system, operating system installs on braced system, operating system includes high-end operating system and low-end operating system, high-end operating system and low-end operating system install respectively in braced system's both sides, carry cargo bed both sides respectively with high-end operating system and low-end operating system be connected and be connected, connect and get conveying system including climbing conveying system, upset conveying system and snatch the mechanism, climbing conveying system fixes in the above of carrying cargo bed, upset conveying system sets up the exit end at climbing conveying system, it fixes in climbing conveying system entry end the place ahead to snatch the mechanism.

The inlet end of the climbing conveying system is designed to be a rotating shaft with a small rotating radius, the front end of the rotating shaft is provided with a grabbing mechanism, so that the cut-in steps are further reduced to the maximum extent, and the material is separated from the original conveying surface from the continuous conveying surface through the climbing conveying system by adopting an extremely low receiving surface.

Furthermore, the climbing conveying system is a belt conveyor, a material inlet end of the belt conveyor adopts a wedge-shaped bed plate which provides a climbing function for materials, a rotating shaft is installed at the wedge-shaped inlet, and the outer bearing surface of the rotating shaft can be continuous or intermittent.

Further, the revolving body can be a shaft body, and a plurality of annular sleeves capable of freely rotating can be arranged on the shaft body.

Further, the freely rotating annular sleeve may be of the rolling bearing type or of the wear-resistant sliding bearing type, which may be one or more of plastic, reinforced plastic, steel, stainless steel, ceramic, brass, rubber, latex, nylon, resin-based composition.

Furthermore, the grabbing mechanism is designed into a power rotating shaft, and the outer surface of the rotating shaft is a high friction surface.

Furthermore, the outer surface of the rotary shaft of the grabbing mechanism can be made into continuous patterns, intermittent patterns and spiral patterns along the axial length direction or the circumferential direction, and the outer surface can be made into diamond patterns, round dot patterns, toothed patterns, ratchet patterns and wave patterns.

Furthermore, the rotary shaft and the surface of the grabbing mechanism can be made of metal, plastic, reinforced plastic, rubber, latex, nylon, resin composites, aluminum, steel, stainless steel, ceramics and brass.

Furthermore, the grabbing mechanism can also adopt a wedge-shaped blade with a low friction coefficient, the bearing surface is a transition inclined surface, an acute angle is formed between the bearing surface and the conveying surface of the main conveying line, the transition at the joint between the bearing surface and the conveying surface of the main conveying line is smooth, the reverse step difference causing the material to be clamped is avoided, and the transition of the material from a continuous conveying surface to a climbing conveying system through the bearing surface can be realized through an extremely low receiving surface; when the grabbing mechanism adopts the wedge-shaped blade with low friction coefficient, the bearing surface and the bottom surface of the grabbing mechanism can be provided with unpowered rollers or balls, or grooves parallel to the material flow direction are arranged, so that the contact area of the bearing surface and the material is reduced, the frictional resistance is reduced, and meanwhile, the damage to the original conveying surface is reduced or avoided.

Furthermore, the two sides of the goods carrying platform climbing conveying system are respectively connected with a high-end lifting system sliding block and a low-end lifting system sliding block through a first rotating shaft assembly, a second rotating shaft assembly, and the high-end lifting system sliding block and the low-end lifting system sliding block are driven by corresponding driving elements to lift on a sliding rod or a sliding rail along the vertical direction.

Furthermore, when the descending stroke of the low-end lifting system is larger than that of the high-end lifting system, the receiving and conveying system can receive materials on the inclined conveying surface.

Furthermore, when the lifting strokes of the high-end lifting system and the low-end lifting system are consistent, the materials on the horizontal conveying surface can be received by the receiving and conveying system.

Furthermore, the transmission mode of the high-end lifting system and the low-end lifting system can be screw transmission, gear and rack transmission, belt transmission and chain transmission, or direct drive of an electric push rod and an air cylinder.

Further, when only the material taking of the horizontal conveying surface is needed, the high-end lifting system and the low-end lifting system can be combined into a single lifting system, and the lifting of the material taking conveying system is realized by a single driving element through belt transmission, chain transmission or other transmission modes.

Furthermore, the outlet end of the climbing conveying system is in butt joint with a turnover conveying system, and the turnover conveying system realizes turnover through a turnover motor, an electric cylinder or an air cylinder.

Furthermore, the turnover conveying system is arranged to be of a turnover type, so that the requirement for smaller material spacing can be met, and high sorting processing capacity is provided.

Furthermore, according to the difference of the types of the processed materials, the distances among the materials and the sorting processing capacity requirements, the climbing conveying system and the overturning conveying system can be combined into a conveyor without the overturning function.

Further, when the materials are conveyed reversely, the device has a vertical confluence function.

Furthermore, in another combination, the supporting frame can be configured to independently set the climbing conveying system and the grabbing mechanism on the main conveying line conveying surface at the front end of the lifting system, and after the materials climb through the climbing conveying system and are separated from the main conveying line conveying surface, the materials are received and lifted by the material receiving device in the lifting system after the climbing conveying system.

And further, the device is used for grabbing and transferring granular bulk materials, single-piece box materials, luggage or package type multi-specification box materials upwards from the conveying surfaces of a horizontal or inclined running apron turntable conveyor, a belt conveyor, a chain plate conveyor, a roller conveyor, a net chain conveyor and a module chain conveyor.

Compared with the prior art, the utility model has at least one of the following beneficial effects:

the materials to be sorted can be directly transferred to the other conveying height on the original conveying surface, and meanwhile, the normal conveying of other materials on the original conveying surface is not influenced; the original conveying surface is suitable for both a horizontal surface and an inclined surface, and the material conveying surface can be controlled to be the horizontal surface or the inclined surface after vertical sorting; the vertical sorting of various regular materials and irregular materials can be met, and conditions are provided for subsequent treatment; the upset setting can realize littleer material interval demand, provides high letter sorting throughput.

Drawings

Fig. 1 is a first structural diagram of the present invention.

FIG. 2 is a second schematic structural diagram of the present invention.

Fig. 3 is a third structural diagram of the present invention.

Fig. 4 is a schematic diagram of the inclined surface material receiving of the present invention.

Fig. 5 is a schematic view of the horizontal receiving of the present invention.

Fig. 6 is a schematic structural diagram of the receiving and conveying system of the present invention.

In the drawings, 1-a support system; 2-a lifting system; 2 a-cargo bed; 3-receiving and conveying system; 4-high-end elevator system; 5-a low end lift system; 6-climbing conveying system, 7-turning conveying system, 8-high-end lifting system sliding block, 9-low-end lifting system sliding block, 10-first rotating shaft component, 11-second rotating shaft component, 12-grabbing mechanism, 13-linear guide rail system and 14-material receiving device.

Detailed Description

As shown in fig. 1 to 6, in order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Example 1

The utility model provides a device for be used for with material from continuous whole width of cloth transport surface vertical sorting, including braced system 1, operating system 2, carry cargo bed 2a and connect and get conveying system 3, operating system 2 installs on braced system 1, operating system 2 includes high-end operating system 4 and low-end operating system 5, high-end operating system 4 and low-end operating system 5 install the both sides at braced system 1 respectively, carry cargo bed 2a both sides respectively with high-end operating system 4 and low-end operating system be connected 5 and be connected, connect and get conveying system 3 and include climbing conveying system 6, upset conveying system 7 and snatch mechanism 12, climbing conveying system 6 fixes in carrying cargo bed 2a top, upset conveying system 7 sets up the exit end at climbing conveying system 6, snatch mechanism 12 and fix in climbing conveying system 6 entry end the place ahead.

Preferably, the climbing conveying system 6 is a belt conveyor, a material inlet end of the belt conveyor adopts a wedge-shaped bed plate, the wedge-shaped bed plate provides a climbing function for materials, and a small-turning-radius rotating shaft is installed at a wedge-shaped inlet.

Preferably, the inlet end of the climbing conveying system 6 is a rotating shaft with a small rotating radius, and the outer bearing surface of the rotating shaft is continuous.

Preferably, the inlet end of the climbing conveying system 6 is a rotating shaft with a small rotating radius, and the rotating body can be a shaft body.

Preferably, the inlet end of the climbing conveying system 6 is a rotating shaft with a small rotating radius, the front end of the rotating shaft is provided with a grabbing mechanism 12, the cut-in steps are further reduced to the maximum extent, and the materials are separated from the original conveying surface from the continuous conveying surface through the climbing conveying system 6 by adopting an extremely low receiving surface.

Preferably, the grabbing mechanism 12 has a bearing surface with a low friction coefficient, the bearing surface forms an acute angle with the original conveying surface, the transition of the joint between the bearing surface and the original conveying surface is smooth, a reverse step difference causing material clamping is avoided, the transition of the materials from the continuous conveying surface to the climbing conveying system 6 through the bearing surface can be realized through an extremely low access surface, and the climbing conveying system 6 drives the materials to be separated from the original conveying surface.

Preferably, the grooves parallel to the material flow direction are arranged on the bearing surface and the bottom surface of the grabbing mechanism 12, so that the contact area between the bearing surface and the material is reduced, the friction resistance is reduced, and the damage to the original conveying surface is avoided.

Preferably, two sides of the cargo bed 2 are respectively connected with the high-end lifting system slider 8 and the low-end lifting system slider 9 through the first rotating shaft assembly 10, the second rotating shaft assembly 11, and the high-end lifting system slider 8 and the low-end lifting system slider 9 are respectively driven by corresponding driving elements to lift on the sliding rods along the vertical direction, so that the picking and conveying system 3 is lifted in the vertical direction.

Preferably, when the descending stroke of the low-end lifting system 5 is larger than that of the high-end lifting system 4, the material on the inclined conveying surface can be accessed by the access conveying system 3.

Preferably, when the lifting strokes of the high-end lifting system 4 and the low-end lifting system 5 are consistent, the receiving and conveying system 3 can receive materials of the horizontal conveying surface.

Preferably, the transmission manner of the high-end lifting system 4 and the low-end lifting system 5 can be belt transmission.

Preferably, the outlet end of the climbing conveying system 6 is butted with a turnover conveying system 7, and the turnover conveying system 7 is turned over through a turnover motor.

Preferably, the turnover conveying system 7 is arranged to be a turnover type, so that the requirement of smaller material spacing can be met, and high sorting processing capacity is provided.

Preferably, the climbing conveying system 6 and the overturning conveying system 7 can be combined into a conveyor according to different requirements of the types of the processed materials, the material intervals and the sorting processing capacity, and the overturning function is not required.

Preferably, the device has a vertical confluence function when the materials are conveyed in reverse.

The receiving and conveying system is normally arranged at a high position, the output end of the overturning conveying system 7 faces upwards, and a certain included angle is formed between the output end of the overturning conveying system and the climbing conveying system 6. When the materials on the low-end conveying platform need to climb and transfer, the high-end lifting system 4 and the low-end lifting system 5 act simultaneously to lower the receiving and conveying system 3 to a low position. When the original conveying platform is a horizontal plane, the descending strokes and the speeds of the high-end lifting system 4 and the low-end lifting system 5 are consistent; when the original conveying platform is an inclined plane, the descending speed and the descending stroke of the high-end lifting system 4 are lower than those of the low-end lifting system 5, and the inclined angle of the receiving and conveying system 3 after descending and stopping is consistent with that of the original conveying platform through the rotating shaft assembly 10 and the rotating shaft assembly 11.

The bottom surface of the head of the material along the conveying direction is separated from the original conveying platform through the grabbing mechanism 12, because the friction driving force of the original conveying platform on the bottom surface of the tail of the material and the friction driving force of the climbing conveying system 6 on the bottom surface of the head of the material are carried, the material is conveyed and climbed along the carrying surface of the climbing conveying system 6, and meanwhile, the overturning conveying system 7 is overturned downwards to be parallel to the original conveying platform and used for receiving the material conveyed by the climbing conveying system 6. When the materials completely enter the receiving and conveying system 3, the high-end lifting system 4 and the low-end lifting system 5 act simultaneously to lift the receiving and conveying system 3 to a high position and be in a horizontal state, and the materials are conveyed to downstream equipment.

Example 2

The utility model provides a device for be used for with material from continuous whole width of cloth transport surface vertical sorting, when only being applied to former conveying platform and being the horizontal plane, including braced system 1, operating system 2, carry cargo bed 2a and connect and get conveying system 3, operating system 2 is single drive arrangement, install in braced system 1's both sides, carry cargo bed 2a both sides and be connected with operating system 2 respectively, it includes climbing conveying system 6 to connect and get conveying system 3, upset conveying system 7, snatch mechanism 12, climbing conveying system 6 installs in carrying cargo bed 2 top, upset conveying system 7 installs at the material exit end of carrying cargo bed 2 top, the setting is at the exit end of climbing conveying system 6, snatch mechanism 12 and install at climbing conveying system 6 entry end.

Preferably, the climbing conveying system 6 is a belt conveyor, a material inlet end of the belt conveyor adopts a wedge-shaped bed plate, the wedge-shaped bed plate provides a climbing function for materials, and a small-turning-radius rotating shaft is installed at a wedge-shaped inlet.

Preferably, the inlet end of the climbing conveying system 6 is a rotating shaft with a small rotating radius, and the outer bearing surface of the rotating shaft is intermittent.

Preferably, the inlet end of the climbing conveying system 6 is a rotating shaft with a small rotating radius, and the rotating body is a plurality of freely rotatable annular sleeves arranged on a shaft body.

Preferably, the freely rotating annular sleeve may be of the rolling bearing type.

Preferably, the inlet end of the climbing conveying system 6 is designed to be a rotating shaft with a small rotating radius, the front end of the rotating shaft is provided with a grabbing mechanism 12, the cut-in steps are further reduced to the maximum extent, and the materials are separated from the original conveying surface from the continuous conveying surface through the climbing conveying system 6 by adopting an extremely low receiving surface.

Preferably, the gripping means 12 are designed as a powered swivel shaft, the outer surface of which is a high friction surface.

Preferably, linear guide rail systems 13 parallel to each other are respectively disposed at both sides of the lifting system 2, and the sliders 9 of the linear guide rail systems 13 are respectively connected to both sides of the cargo bed 2 a.

Preferably, the lifting system 2 is driven by a single speed reduction motor, and the goods carrying platform 2a is lifted along the linear guide rail system 13 in the vertical direction through synchronous belt transmission, so that the receiving and conveying system 3 is lifted in the vertical direction.

Preferably, the outlet end of the climbing conveying system 6 is butted with a turnover conveying system 7, and the turnover conveying system 7 realizes turnover through an electric cylinder.

Preferably, the turnover conveying system 7 is arranged to be a turnover type, so that the requirement of smaller material spacing can be met, and high sorting processing capacity is provided.

Preferably, the climbing conveying system 6 and the overturning conveying system 7 can be combined into a conveyor according to different requirements of the types of the processed materials, the material intervals and the sorting processing capacity, and the overturning function is not required.

Preferably, the device has a vertical confluence function when the materials are conveyed in reverse.

The receiving and conveying system is normally arranged at a high position, the output end of the overturning conveying system 7 faces upwards, and a certain included angle is formed between the output end of the overturning conveying system and the climbing conveying system 6. When the materials on the low-end conveying platform need to climb and transfer, the lifting system 2 lowers the receiving and conveying system 3 to a low position.

The bottom surface of the head of the material along the conveying direction is separated from the original conveying platform through the grabbing mechanism 12, because the friction driving force of the original conveying platform on the bottom surface of the tail of the material and the friction driving force of the climbing conveying system 6 on the bottom surface of the head of the material are borne, the material is conveyed and climbed along the bearing surface of the climbing conveying system 6, and meanwhile, the overturning conveying system 7 is overturned downwards to be parallel to the original conveying platform and used for receiving the material conveyed by the climbing conveying system 6. When the materials completely enter the receiving and conveying system 3, the lifting system 2 lifts the receiving and conveying system 3 to a high position and is in a horizontal state, and the materials are conveyed to downstream equipment.

Example 3

The utility model provides a device for being used for with material from continuous whole width of cloth conveying surface vertical sorting, connects to get conveying system 3 independent setting at 2 front ends of braced system, including braced system 1, braced system 2, carry cargo bed 2a and connect to get conveying system 3, and braced system 2 is single drive arrangement, installs in braced system 1's both sides, carries cargo bed 2a to be provided with receiving device 14, and both sides are connected with braced system 2 respectively, connects to get conveying system 3 and includes climbing conveying system 6, snatchs mechanism 12 and installs at climbing conveying system 6 entry end.

Preferably, the receiving and conveying system 3 is independently arranged on the conveying surface of the main conveying line at the front end of the lifting system 2 through a corresponding supporting frame and does not perform lifting action along with the lifting system 2.

Preferably, the climbing conveying system 6 is a belt conveyor, a material inlet end of the belt conveyor adopts a wedge-shaped bed plate, the wedge-shaped bed plate provides a climbing function for materials, and a small-turning-radius rotating shaft is installed at a wedge-shaped inlet.

Preferably, the inlet end of the climbing conveying system 6 is a rotating shaft with a small rotating radius, and the outer bearing surface of the rotating shaft is continuous.

Preferably, the inlet end of the climbing conveying system 6 is a rotating shaft with a small rotating radius, and the rotating body is a plurality of freely rotatable annular sleeves arranged on a shaft body.

Preferably, the freely rotating annular sleeve may be of the wear-resistant sliding bearing type, which may be made of plastic, reinforced plastic.

Preferably, the inlet end of the climbing conveying system 6 is designed to be a rotating shaft with a small rotating radius, the front end of the rotating shaft is provided with a grabbing mechanism 12, the cut-in steps are further reduced to the maximum extent, and the materials are separated from the original conveying surface from the continuous conveying surface through the climbing conveying system 6 by adopting an extremely low receiving surface.

Preferably, the gripping means 12 are designed as a powered swivel shaft, the outer surface of which is a high friction surface.

Preferably, linear guide rail systems 13 parallel to each other are respectively disposed at both sides of the lifting system 2, and the sliders 9 of the linear guide rail systems 13 are respectively connected to both sides of the cargo bed 2 a.

Preferably, the receiving device 14 is a belt conveyor.

Preferably, the lifting system 2 is driven by a single speed reduction motor, and the cargo bed 2a is lifted along the linear guide system 13 in the vertical direction by means of a synchronous belt transmission.

Preferably, the device has a vertical confluence function when the materials are conveyed in reverse.

The receiving and conveying system is normally arranged at a high position. When the material on the low end conveying platform needs to climb and shift, the bottom surface of the head of the material along the conveying direction is separated from the original conveying platform through the grabbing mechanism 12, because the friction driving force of the original conveying platform to the bottom surface of the tail of the material and the friction driving force of the climbing conveying system 6 bearing surface to the bottom surface of the head of the material are adopted, the material is conveyed and climbed along the bearing surface of the climbing conveying system 6, meanwhile, the lifting system 2 lowers the cargo carrying platform 2a to a low position, and the material is received and taken through the material receiving device 14. After the materials completely enter the material receiving device 14, the lifting system 2 lifts the material receiving device 14 to a high position and is in a horizontal state, and the materials are conveyed to downstream equipment.

Although the utility model has been described herein with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More specifically, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, other uses will also be apparent to those skilled in the art.

Claims (12)

1. An apparatus for vertically sorting material from a continuous web transport surface, characterized by: comprises a supporting system (1) and a lifting system (2), carry cargo bed (2 a) and connect and get conveying system (3), operating system (2) are installed on braced system (1), operating system (2) are including high-end operating system (4) and low side operating system (5), the both sides at braced system (1) are installed respectively in high-end operating system (4) and low side operating system (5), carry cargo bed (2 a) both sides to be connected with high-end operating system (4) and low side operating system respectively (5), connect and get conveying system (3) including climbing conveying system (6), upset conveying system (7) and snatch mechanism (12), climbing conveying system (6) are fixed in carrying cargo bed (2 a) top, upset conveying system (7) set up the exit end at climbing conveying system (6), snatch mechanism (12) and fix in climbing conveying system (6) entry end the place ahead.

2. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 1, wherein: the climbing conveying system (6) is a belt conveyor, a material inlet end of the belt conveyor adopts a wedge-shaped bed plate which provides a climbing function for materials, a rotating shaft is installed at the wedge-shaped inlet, and the outer bearing surface of the rotating shaft is continuous or intermittent.

3. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 2, wherein: the revolving body is a shaft body, or a plurality of freely rotatable annular sleeves are arranged on the shaft body.

4. A device for vertically sorting material from a continuous full width conveying surface according to claim 3, wherein: the freely rotating annular sleeve is a rolling bearing or a wear-resistant sliding bearing, and the wear-resistant sliding bearing is one or more of plastic, reinforced plastic, steel, stainless steel, ceramic, brass, rubber, latex, nylon and resin-based composite.

5. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 1, wherein: the grabbing mechanism (12) is designed as a power rotating shaft, and the outer surface of the rotating shaft is a high friction surface.

6. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 5, wherein: the outer surface of the rotary shaft of the grabbing mechanism (12) is made into continuous patterns, intermittent patterns and spiral patterns along the axial length direction or the circumferential direction, and the outer surface is made into diamond patterns, round dot patterns, toothed patterns, ratchet patterns and wave patterns.

7. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 5, wherein: the rotary shaft and the surface of the grabbing mechanism (12) are made of metal, plastic, reinforced plastic, rubber, latex, nylon, resin composites, aluminum, steel, stainless steel, ceramics and brass.

8. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 1, wherein: the grabbing mechanism (12) is designed into a smooth bearing surface wedge body with a low friction coefficient, and unpowered rollers or balls or grooves parallel to the material flow direction are arranged on the bearing surface and the bottom surface of the grabbing mechanism (12).

9. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 1, wherein: the two sides of the climbing conveying system of the cargo carrying platform (2 a) are respectively connected with a high-end lifting system sliding block (8) and a low-end lifting system sliding block (9) through a first rotating shaft assembly (10), a second rotating shaft assembly (11), and the high-end lifting system sliding block (8) and the low-end lifting system sliding block (9) are driven by corresponding driving elements to lift on a sliding rod or a sliding rail along the vertical direction.

10. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 1, wherein: the transmission modes of the high-end lifting system (4) and the low-end lifting system (5) are screw transmission, gear and rack transmission, belt transmission and chain transmission, or direct drive of an electric push rod and an air cylinder.

11. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 1, wherein: when the material is only taken from the horizontal conveying surface, the high-end lifting system (4) and the low-end lifting system (5) can be combined into a single lifting system, and the single driving element realizes the lifting of the taking and conveying system (3) through a belt transmission and chain transmission mode.

12. An apparatus for vertically sorting material from a continuous web conveying surface according to claim 1, wherein: in addition, the climbing conveying system (6) and the grabbing mechanism (12) are combined and independently arranged on the main conveying line conveying surface at the front end of the lifting system through the combined supporting frame, and after materials climb through the climbing conveying system (6) and are separated from the main conveying line conveying surface, the materials are received, taken and lifted by the material receiving device (14) in the lifting system (2) behind the climbing conveying system (6).

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