A telescoping machine takeoff

By installing a material-retrieving component and a transfer component on the first section of the telescopic conveyor, the belt conveyor surface is raised to form a lower step, which solves the problem that the automatic loading device cannot retrieve materials on the first section of the telescopic conveyor, thereby improving space utilization efficiency and increasing material-retrieving speed.

CN224492416UActive Publication Date: 2026-07-14KUNMING DINGCHENG TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
KUNMING DINGCHENG TECH
Filing Date
2025-07-29
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

The existing automatic loading device cannot pick up materials on the first section of the telescopic conveyor, which results in occupying space outside the warehouse and affecting the parking position of vehicles.

Method used

Design a material handling device for a telescopic conveyor, including a material handling component and a transfer component. The material handling component is installed on the first section of the telescopic conveyor and forms a lower step by raising the belt conveyor surface. The transfer component is connected to an automatic loading device to realize the transfer of materials.

Benefits of technology

The automatic loading device can pick up materials on the first section of the telescopic conveyor, avoiding the occupation of space outside the warehouse, reducing investment in factory construction, and improving material picking speed and adaptability.

✦ Generated by Eureka AI based on patent content.

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Abstract

The embodiment of the utility model discloses a telescopic machine material taking device relates to the freight handling technical field. The telescopic machine material taking device includes the material taking subassembly of installing on the first section of telescopic machine, material taking subassembly is configured as: reciprocating motion along the conveying direction of telescopic machine, and in the first section of telescopic machine's beginning material taking position, the belt conveying surface of beginning material taking position is lifted, makes the belt conveying surface of the rear side of beginning material taking position higher than the belt conveying surface of front side. The utility model can make automatic loading device material taking on telescopic machine first section.
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Description

Technical Field

[0001] This utility model relates to the field of logistics loading and unloading technology, and in particular to a telescopic conveyor material handling device. Background Technology

[0002] In recent years, logistics loading and unloading technology has developed rapidly, resulting in a variety of automated loading devices. Currently, the loading process of automated loading devices is as follows: materials are fed to the telescopic conveyor by manual labor, robotic arms, or sorting conveyors; the telescopic conveyor transports the materials to the automated loading device; and the automated loading device stacks the materials into the truck bed.

[0003] Patent application CN202510162002.9 discloses an automatic loading device and method for bagged materials in a sealed truck compartment. The device in this patent can only dock with the end of a telescopic conveyor to retrieve materials, and cannot retrieve materials from the first section of the conveyor. Therefore, space needs to be reserved between the end of the telescopic conveyor and the truck compartment for the loading device. This results in the automatic loading device occupying too much space outside the warehouse and encroaching on vehicle parking spaces. Patent application CN202420127390.8 discloses a loading and unloading docking system. The solution provided by this patent also only allows docking with the end of the telescopic conveyor to retrieve materials, and cannot return to the first section of the conveyor to retrieve materials. Similarly, this results in the automatic loading system occupying too much space outside the warehouse and encroaching on vehicle parking spaces. Utility Model Content

[0004] In view of this, this utility model provides a telescopic conveyor material retrieval device for use in combination with an automatic loading device, so that the automatic loading device can return to the first section of the telescopic conveyor inside the warehouse to retrieve materials, thus solving the problem in the prior art where the automatic loading device cannot return to the first section of the telescopic conveyor to retrieve materials and thus occupies too much space outside the warehouse.

[0005] This utility model embodiment provides a material handling device for a telescopic conveyor, including: a material handling component installed on the first section of the telescopic conveyor;

[0006] The material handling component is configured to reciprocate along the conveying direction of the telescopic conveyor, and at the starting material handling position of the first section of the telescopic conveyor, raise the belt conveyor surface at the starting material handling position, so that the belt conveyor surface behind the starting material handling position is higher than the belt conveyor surface in front of the starting material handling position.

[0007] In a first embodiment, the telescopic conveyor material handling device further includes a transfer component, one end of which is mounted on an automatic loading device for transferring materials from the telescopic conveyor to a truck bed, and the other end is suspended in the air.

[0008] The transfer component is configured to move with the automatic loading device to the front of the material picking component, and to make the suspended end of the transfer component the same height as the starting material picking position and the distance between them less than a preset distance.

[0009] In the second embodiment, the material handling component includes:

[0010] Two guide rails are installed on the left and right sides of the telescopic machine and guide it along the conveying direction of the telescopic machine; wherein, the left and right directions are horizontally transverse to the conveying direction of the telescopic machine.

[0011] Two racks are fixedly installed on the two guide rails respectively.

[0012] Two support plates are symmetrically arranged on the left and right sides of the telescopic machine, and the support plates are provided with grooves.

[0013] A gear assembly connected to the support plate, the gear assembly including two gears and a gear drive assembly, the two gears respectively meshing with two racks, and the gear drive assembly driving the gears to rotate;

[0014] A linear motion module is installed on each of the support plates;

[0015] The second roller is fixedly connected to the linear motion modules on the left and right sides at its left and right ends, and the second roller is located on the underside of the belt of the telescopic machine;

[0016] A first motor is fixedly connected to each linear motion module; the first motor drives the linear motion module, thereby driving the second roller to move along the groove, so as to raise the belt conveyor surface of the telescopic machine; and

[0017] The redirecting roller assembly is located below the second roller. After the belt of the telescopic conveyor passes over the second roller from top to bottom, it returns to the original conveying direction through the redirecting roller assembly.

[0018] In a third embodiment, the gear drive assembly includes:

[0019] Two square bearing housings are fixedly mounted on two support plates respectively;

[0020] The speed reducer is fixedly mounted on one of the support plates;

[0021] The second motor is fixedly mounted on the reducer;

[0022] A first drive shaft passes through the reducer and two square bearing seats, and the two gears are respectively fixedly installed on the left and right sides of the first drive shaft;

[0023] The first roller is positioned between the two gears and is rotatably mounted on the first drive shaft.

[0024] In the fourth embodiment, the guide rail is a U-shaped guide rail with a U-shaped groove, and the openings of the U-shaped grooves of the two guide rails on the left and right sides are arranged opposite each other.

[0025] The material handling assembly also includes multiple guide units installed on the bottom side of the support plate. Each guide unit includes a stepped shaft and a flange bearing. The stepped shaft is fixedly installed on the support plate. The inner circle of the flange bearing is rotatably installed on the stepped shaft, and the outer circle is movably installed in the U-shaped groove of the guide rail. The flange of the flange bearing is in contact with the guide rail.

[0026] In the fifth embodiment, the redirecting roller assembly includes three redirecting rollers, the axis of which is parallel to the axis of the second roller.

[0027] The first and second redirecting rollers are both located below the second roller, and in the conveying direction of the telescopic conveyor, the first redirecting roller is located behind the second roller, and the second redirecting roller is located in front of the second roller; the third redirecting roller is located above the rear of the second redirecting roller; wherein, forward is defined as the positive direction of the conveying direction of the telescopic conveyor, and backward is the opposite direction of forward;

[0028] The belt of the telescopic machine extends backward after passing over the second roller from top to bottom, then forward after passing over the first redirecting roller from top to bottom, then forward after passing over the front side of the second redirecting roller from bottom to top, then forward after passing over the third redirecting roller from back to front, and finally extends towards the front side of the telescopic machine.

[0029] In a sixth embodiment, the conveying component is further configured to convey material from back to front.

[0030] This utility model provides a material handling device for a telescopic conveyor. A material handling component is installed on the first section of the telescopic conveyor, and a transfer component is installed on an automatic loading device for transferring materials from the telescopic conveyor to a truck bed. The material handling device is moved to the starting material handling position of the first section of the telescopic conveyor. The material handling device raises the belt conveyor surface at the starting material handling position, making the belt conveyor surface behind the starting material handling position higher than the belt conveyor surface in front, forming a step. After the transfer component moves with the automatic loading device to the front of the material handling component, since the suspended end of the transfer component is at the same height as the starting material handling position and the distance between them is less than a preset distance, the automatic loading device can handle the material handling on the first section of the telescopic conveyor and then transfer it to the transfer component. This avoids the automatic loading device occupying space outside the warehouse, reducing the factory construction investment for logistics companies. Furthermore, when handling material on the first section of the telescopic conveyor, the conveying direction and the material handling direction of the telescopic conveyor are opposite, which can significantly improve the material handling speed. In addition, the telescopic conveyor material handling device of this invention has two modes: conveying and material handling, which can adapt to more operating scenarios. The telescopic conveyor material handling device of this invention can also adapt to a large range of left and right deviations at the end of the telescopic conveyor. Attached Figure Description

[0031] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0032] Figure 1 A schematic diagram of a telescopic conveyor material handling device and its application scenario provided by an embodiment of this utility model;

[0033] Figure 2 A schematic diagram of the material handling component provided in an embodiment of this utility model;

[0034] Figure 3 Partial view of the material handling component of this utility model Figure I ;

[0035] Figure 4 Partial view of the material handling component of this utility model Figure I Another perspective sectional view;

[0036] Figure 5 Partial view of the material handling component Figure II ;

[0037] Figure 6 This is a schematic diagram of the belt winding path for the material handling assembly;

[0038] Figure 7A schematic diagram of the transmission component structure provided by this utility model;

[0039] Figure 8 This is a schematic diagram of the material handling device for a telescopic conveyor provided in an embodiment of the present invention, showing the material handling process in the first section of the telescopic conveyor.

[0040] Figure 9 A schematic diagram illustrating the conveying status of the material-picking component when the conveying component is not picking up materials;

[0041] Figure 10 This is a schematic diagram of the material handling end of the transfer component of this utility model in the extended state of the telescopic conveyor.

[0042] Figure 11 This is a top view of the telescopic machine of this utility model in the extended state, with the end in the material-taking position.

[0043] Figure label:

[0044] 1. Material; 2. Telescopic conveyor; 3. Warehouse; 4. Material handling assembly; 5. Transfer assembly; 201. Belt; 401. Guide rail; 402. Rack; 403. First roller; 404. Support plate; 405. Second roller; 406. Idling roller; 407. Gear; 408. Stepped shaft; 409. Flange bearing; 410. Linear motion module; 411. First motor; 412. Reducer; 413. Second motor; 414. Square bearing housing; 415. 1. Drive shaft; 501. First geared motor; 502. First bracket; 503. T-bearing; 504. Synchronous belt; 505. Second drive shaft; 506. Synchronous pulley; 507. Second bracket; 508. Second geared motor; 509. Crank; 510. Tie rod; 511. Third bracket; 512. Side rail; 513. Connecting plate; 514. Passive shaft; 515. Side support plate; A. Groove; B. Inclined structure at the end of the telescopic conveyor; C. Starting material handling position. Detailed Implementation

[0045] The present invention will now be described in further detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for illustrative purposes only and are not intended to limit the scope of the invention. Furthermore, it should be noted that, for ease of description, the accompanying drawings show only the parts relevant to the present invention, and not the entire structure.

[0046] In the description of this utility model, unless otherwise explicitly specified and limited, the terms "connected", "linked", and "fixed" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal connection of two components or the interaction between two components.

[0047] In this utility model, unless otherwise explicitly specified and limited, "above" or "below" the second feature can include direct contact between the first and second features, or contact between the first and second features through another feature between them. Furthermore, "above," "over," and "on top" of the second feature include the first feature directly above or diagonally above the second feature, or simply indicates that the first feature is at a higher horizontal level than the second feature. "Below," "below," and "under" the second feature include the first feature directly below or diagonally below the second feature, or simply indicates that the first feature is at a lower horizontal level than the second feature. In the description of this embodiment, the terms "above," "below," "left," "right," etc., of orientation or positional relationship are based on the orientation or positional relationship shown in the drawings and are only for ease of description and simplification of operation, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model.

[0048] Figure 1 A schematic diagram of a telescopic conveyor material handling device and its application scenario provided by an embodiment of this utility model, as shown below. Figure 1 As shown, the telescopic conveyor 2 is installed inside the material warehouse 3. The output end of the telescopic conveyor 2 generally has multiple sections. The first section is fixedly installed inside the material warehouse 3. From the first section to the end of the telescopic conveyor 2, they are sequentially named the second section, the third section, and so on. The telescopic conveyor 2 achieves its telescopic function by telescopically extending each section after the first section. When it is necessary to load or unload materials, it extends outward from the door of the material warehouse 3 to connect with the automatic loading device used to transfer materials from the telescopic conveyor to the cargo compartment of a freight car parked outside the platform of the warehouse 3. Figure 1 (Automatic loading device not shown).

[0049] In this embodiment of the utility model, for ease of explanation, as follows: Figure 1 As shown, the directions that are horizontally transverse to the conveying direction of the telescopic machine 2 are defined as left and right directions, the forward direction of the conveying direction of the telescopic machine 2 is defined as forward, and the opposite direction of forward is defined as backward.

[0050] like Figure 1 As shown, the telescopic conveyor material handling device provided by this utility model includes a material handling component 4, which is movably installed on the first section of the telescopic conveyor 2. The material handling component 4 is configured to reciprocate along the conveying direction of the telescopic conveyor 2, and at the starting material handling position of the first section of the telescopic conveyor 2, raise the belt conveying surface of the telescopic conveyor 2.

[0051] The telescopic conveyor material handling device provided in this embodiment of the utility model has a material handling component installed on the first section of the telescopic conveyor. The material handling device is moved to the starting material handling position of the first section of the telescopic conveyor. The material handling device raises the belt conveyor surface at the starting material handling position, so that the belt conveyor surface behind the starting material handling position is higher than the belt conveyor surface in front, forming a step. This allows the automatic loading device at the front end to extend into and connect with the material handling component from the step, thereby achieving the purpose of the automatic loading device picking up materials on the first section of the telescopic conveyor. This avoids the automatic loading device occupying space outside the warehouse and reduces the factory construction investment of logistics companies.

[0052] Preferably, such as Figure 1 As shown, the telescopic conveyor material handling device provided by this utility model also includes a transfer component 5, one end of which is installed on an automatic loading device for transferring materials from the telescopic conveyor 2 to the cargo compartment of a freight car. Figure 1 (Not shown in the image) One end is suspended above the other; the transfer component 5 is configured to move with the automatic loading device to the front of the picking component 4, and to make the suspended end of the transfer component 5 the same height as the starting picking position and the distance between them less than a preset distance. The telescopic conveyor 2 transports the material 1 to the picking component 4, and the transfer component 5 can further transport the material 1 to the automatic loading device. In this embodiment, by setting the transfer component 5, the suspended end of the transfer component 5 can be placed at the lower step position formed by the picking component 4, achieving perfect docking with the picking component 4, solving the problem of inconsistent height difference between the conveyor belts of different vehicle carriages and the telescopic conveyor 2, and the fact that the suspended end of the transfer component 5 is the same height as the starting picking position and the distance between them is less than the preset distance can ensure that the material smoothly transitions from the picking component 4 to the transfer component 5, improving the conveying stability.

[0053] Figure 2 This is a schematic diagram of the material handling component provided in an embodiment of the present utility model. Figure 3 Partial view of the material handling component of this utility model Figure I , Figure 4 Partial view of the material handling component of this utility model Figure I Another perspective sectional view, Figure 5 Partial view of the material handling component Figure II , Figure 6 This is a schematic diagram of the belt winding path for the material handling assembly.

[0054] In some embodiments, such as Figures 2 to 4As shown, the material handling assembly 4 includes: guide rails 401, racks 402, support plates 404, gear assemblies, a second roller 405, linear motion modules 410, a first motor 411, and a redirecting roller group; wherein: there are two guide rails 401, which are respectively installed on the left and right sides of the telescopic conveyor 2 and guided along the conveying direction of the telescopic conveyor; there are two racks 402, which are respectively fixedly installed on the two guide rails 401. There are two support plates 404, which are symmetrically arranged on the left and right sides of the telescopic conveyor 2. The support plates 404 are provided with grooves A, which serve to constrain the movement path of the second roller 405. The gear assembly is connected to the support plates 404. The gear assembly includes two gears 407 and a gear drive assembly. The two gears 407 mesh with the two racks 402 respectively, and the gear drive assembly drives the gears 407 to rotate. A linear motion module 410 is installed on each support plate 404, and the left and right ends of the second roller 405 are fixedly connected to the linear motion modules 410 on the left and right sides. The second roller 405 is located below the belt 201 of the telescopic conveyor 2. Each linear motion module 410 is fixedly connected to a first motor 411. A redirecting roller assembly is located below the second roller 405. After the belt 201 of the telescopic conveyor 2 passes over the second roller 405 from top to bottom, it returns to its original conveying direction via the redirecting roller assembly. In these embodiments, the first motor 411 drives the linear motion module 410, which in turn drives the second roller 405 to move along groove A, thereby raising or lowering the height of the belt conveying surface of the telescopic conveyor 2.

[0055] In some embodiments, such as Figure 4 As shown, the gear drive assembly includes: two square bearing seats 414, a reducer 412, a second motor 413, a first drive shaft 415, and a first roller 403; wherein, the two square bearing seats 414 are respectively fixedly mounted on two support plates 404 on the left and right sides; the reducer 412 is fixedly mounted on one of the support plates 404, for example... Figure 4 A reducer 412 is schematically mounted on a support plate 404 on the right side; a second motor 413 is fixedly mounted on the reducer 412; a first drive shaft 415 passes through the reducer 412 and two square bearing seats 414, and two gears 407 are respectively fixedly mounted on the left and right sides of the first drive shaft 415; a first roller 403 is arranged in the middle of the two gears 407 and is rotatably mounted on the first drive shaft 415. In these embodiments, the second motor 413 drives the reducer 412, which in turn drives the first drive shaft 415 to rotate, and the first drive shaft 415 drives the gears 407 to rotate. The gears 407 mesh with the rack 402 to drive the material handling assembly 4 to move back and forth.

[0056] In some embodiments, such as Figure 5As shown, the guide rail 401 is a U-shaped guide rail with a U-shaped groove, and the openings of the U-shaped grooves of the two guide rails 401 on the left and right sides are arranged opposite each other. The material handling assembly 4 also includes multiple guide units installed on the bottom side of the support plate 404. The guide unit includes a stepped shaft 408 and a flange bearing 409; wherein, the stepped shaft 408 is fixedly installed on the support plate 404; the inner circle of the flange bearing 409 is rotatably installed on the stepped shaft 408, and the outer circle is movably installed in the U-shaped groove of the guide rail 401, and the flange of the flange bearing 409 is in contact with the guide rail 401. In these embodiments, the arrangement of the guide units can maintain the material handling assembly 4 moving back and forth in the conveying direction of the telescopic conveyor 2.

[0057] In some embodiments, such as Figure 3 and Figure 6 As shown, the redirecting roller assembly includes three redirecting rollers 406, with the axis of each roller 406 parallel to the axis of the second roller 405. The first and second redirecting rollers 406 are positioned below the second roller 405, and in the conveying direction of the telescopic conveyor 2, the first redirecting roller 406 is located behind the second roller 405, and the second redirecting roller 406 is located in front of the second roller 405; the third redirecting roller 406 is positioned above and behind the second redirecting roller 406. The belt 201 of the telescopic conveyor 2 extends backward after passing over the second roller 405 from top to bottom, then forward after passing over the first redirecting roller 406 from top to bottom, then forward after passing over the front of the second redirecting roller 406 from bottom to top, and finally forward after passing over the third redirecting roller 406 from back to front, extending towards the front of the telescopic conveyor 2. The belt conveyor paths configured in these embodiments can both transport material 1 from warehouse 3 forward to the truck in front, and transport material 1 from the truck in reverse to warehouse 3, thus meeting the dual requirements of automatic loading and unloading.

[0058] In some embodiments, the transfer component 5 of this invention is configured such that its suspended end rotates vertically in a vertical plane around the connection position between the transfer component 5 and the automatic loading device, and conveys materials from back to front. This allows the transfer component to adapt to different output heights of the material handling component 4. Specifically, the transfer component 5 includes a conveying unit and a rotating unit. The conveying unit is used to convey materials from back to front. The rotating unit is connected to the conveying unit and is used to rotate the rear side of the conveying unit vertically in a vertical plane around the second drive shaft 505 to align with the end of the telescopic conveyor 2 or the beginning of the material handling position of the first section.

[0059] Figure 7 This is a schematic diagram of the transmission component structure provided by the present invention. Preferably, as shown in the diagram... Figure 7As shown, the conveying unit includes: a first geared motor 501, a first bracket 502, a T-shaped bearing 503, a synchronous belt 504, a second drive shaft 505, a synchronous pulley 506, a side rail 512, a connecting plate 513, a driven shaft 514, and a side support plate 515.

[0060] The first bracket 502 and the T-type bearing 503 are fixedly installed on the frame of the automatic loading device used to transfer materials on the telescopic machine 2 to the truck bed.

[0061] The first geared motor 501 is fixedly mounted on the first bracket 502;

[0062] The second drive shaft 505 passes through two T-bearings 503 at both ends, and one end of the second drive shaft 505 is fixedly connected to the output shaft of the first geared motor 501 via a coupling; multiple synchronous pulleys 506 are fixedly connected to the second drive shaft 505.

[0063] There are two side support plates 515, and the front ends of the two side support plates 515 can be rotatably installed on the left and right sides of the second drive shaft 505 respectively.

[0064] The connecting plate 513 is located in the middle of the two side support plates 515 and connects the two side support plates 515 into a whole;

[0065] The passive shaft 514 is rotatably mounted on the rear ends of the left and right side support plates 515 at both ends. Multiple synchronous pulleys 506 are fixedly connected to the passive shaft 514. The synchronous pulleys 506 on the second drive shaft 505 and the synchronous pulleys 506 on the passive shaft 514 are connected by a synchronous belt 504.

[0066] There are two edge guards 512, which are symmetrically fixed on the left and right sides of the connecting plate 513.

[0067] In these embodiments, the first geared motor 501 drives the second drive shaft 505 to rotate, and the second drive shaft 505 drives the multiple synchronous pulleys 506 on it to rotate, so that the synchronous belt mechanism composed of the synchronous belt 504 and the synchronous pulleys 506 can realize the conveying of material 1.

[0068] In some embodiments, such as Figure 7As shown, the rotating unit includes: a second bracket 507, a second geared motor 508, a crank 509, a pull rod 510, and a third bracket 511. The second bracket 507 is fixedly mounted on the frame of the automatic loading device; the third bracket 511 is fixedly mounted on a side support plate 515 on the left or right side; the second geared motor 508 is fixedly mounted on the second bracket 507; one end of the crank 509 is fixedly mounted on the output shaft of the second geared motor 508; one end of the pull rod 510 is rotatably connected to the other end of the crank 509, and the other end of the pull rod 510 is rotatably connected to the third bracket 511; the crank 509, the pull rod 510, and the side support plate 515 connected to the pull rod 510 form a four-bar linkage mechanism. The second geared motor 508 drives the crank 509 to rotate, thereby causing the rear side of the conveying unit to rotate up and down around the second drive shaft 505 in the vertical plane.

[0069] Figure 8 This is a schematic diagram showing the material handling device of the telescopic conveyor provided in an embodiment of the present invention handling material in the first section of the telescopic conveyor. (In conjunction with...) Figure 8 The material handling method of the telescopic conveyor material handling device provided by this utility model includes the following steps S11~S15:

[0070] S11: The material taking component 4 moves along the conveying direction of the telescopic conveyor 2 to the starting material taking position C of the first section of the telescopic conveyor 2;

[0071] S12: The material taking component 4 raises the belt conveyor surface at the starting material taking position C of the telescopic conveyor 2, so that the belt conveyor surface behind the starting material taking position C of the first section of the telescopic conveyor 2 is higher than the belt conveyor surface in front, thereby forming a step between the belt conveyor surface behind the starting material taking position C and the belt conveyor surface in front.

[0072] like Figure 8 As shown, the material handling assembly 4 raises the second roller 405 ( Figure 4 The first motor 411 drives the linear motion module 410 to drive the second roller 405 to move upward along the groove A. Since the positions of the three redirecting rollers 406 are fixed, the belt conveyor surface behind the second roller 405 will be higher than the belt conveyor surface in front of the second roller 405, thus forming a step.

[0073] S13: The transfer component 5 rotates around the second drive shaft 505 in the vertical plane until the end of the transfer component 5 near the telescopic machine 2 is at the same height as the starting material picking position C.

[0074] The transmission component 5 rotates around the second drive shaft 505 in a vertical plane, so that the transmission component 5 is close to the upper side of the lower step at one end of the telescopic machine 2, and the conveyor belt at this end of the transmission component 5 is controlled to be at the same height as the conveyor surface of the belt 201 at the starting material pick-up position C of the first section of the telescopic machine 2.

[0075] S14: Transport material 1 from the starting material pick-up position C of the first section of the telescopic conveyor 2 to the transfer assembly 5;

[0076] In this process, the belt 201 on the drive transmission assembly 5 moves from back to front, and together with the telescopic conveyor 2, it transports the material 1 at the starting material pick-up position C to the transmission assembly 5, and the transmission assembly 5 continues to transport it forward to the automatic loading device.

[0077] S15: When the material 1 at the starting pick-up position C of the first section of the telescopic conveyor 2 is conveyed to the transfer component 5, the pick-up component 4 moves backward in the opposite direction of the conveying direction of the telescopic conveyor 2, and the transfer component 5 moves synchronously with the pick-up component 4 in the same direction, so as to realize continuous pick-up at different positions on the first section of the telescopic conveyor 2.

[0078] In this process, the telescopic conveyor 2 continuously conveys material 1 forward, while the material taking component 4 moves backward in the opposite direction of the conveying direction of the telescopic conveyor 2. The transmission component 5 moves synchronously with the material taking component 4 to take material. Since the feeding direction of the telescopic conveyor is opposite to the movement direction of the material taking component 4, the material taking speed can be greatly accelerated and the material taking efficiency can be improved.

[0079] This completes the objective of retrieving material from the first section of the telescopic conveyor 2.

[0080] Preferably, when the transfer component 5 does not need to pick up material from the first section of the telescopic conveyor 2, after S14, step S15 is further included: the material picking component 4 lowers the belt conveyor surface of the telescopic conveyor 2.

[0081] Figure 9 This is a schematic diagram illustrating the conveying status of the material-picking component when the conveyor component is not picking up materials, as shown below. Figure 9 As shown, when the transfer component does not need to pick up material on the first section of the telescopic conveyor 2, the second roller 405 is controlled to move downward along the groove A to a low position, so that the height difference between the front and rear belt conveyor surfaces at the starting material picking position of the first section of the telescopic conveyor 2 is less than a preset threshold. Preferably, the second roller 405 is positioned so that its height is less than the height difference between the front and rear belt conveyor surfaces at the starting material picking position of the first section of the telescopic conveyor 2. Figure 9 The height of the upper right-side redirecting roller 406 of the second roller 405 is consistent with that of the middle roller. At this time, the conveyor belt 201 transitions smoothly from front to back, without affecting the forward or reverse conveying of material 1 by the telescopic conveyor 2.

[0082] The telescopic conveyor material handling device provided in this embodiment of the utility model can handle material not only on the first section of the telescopic conveyor, but also at the end of the telescopic conveyor. Figure 10 This is a schematic diagram of the material handling at the end of the transfer component 5 when the telescopic conveyor 2 is extended. The material handling process of the transfer component 5 at the end of the telescopic conveyor 2 when it is extended is as follows:

[0083] S21: The transmission component 5 rotates around the second drive shaft 505 in the vertical plane until one end of the transmission component 5 near the telescopic machine 2 rests on the inclined structure B at the front end of the telescopic machine 2.

[0084] S22: The telescopic conveyor 2 transports material 1 to the transfer assembly 5;

[0085] S23: The telescopic conveyor 2 retracts in the opposite direction of its own conveying direction, and the transmission component 5 moves synchronously with the telescopic conveyor 2 to pick up the material.

[0086] Thus, the conveying component 5 follows the telescopic conveyor 2 to pick up material at the end of the telescopic conveyor 2, achieving the intended purpose. This telescopic conveyor material handling device has both conveying and picking modes, enabling it to adapt to a wider range of operating scenarios.

[0087] Preferably, such as Figure 11 As shown, the two side bars 512 of the transmission component 5 are arranged in a figure-eight shape. This ensures that even if the end of the telescopic machine 2 that is connected to the transmission component 5 deviates from the left or right relative to the transmission component 5, the material 1 can still be picked up smoothly. This increases the docking range of the transmission component 5 and can adapt to a larger range of left and right deviations of the telescopic machine end.

[0088] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this utility model should be included within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the scope of the claims.

Claims

1. A telescopic conveyor material handling device, characterized in that, include: Material handling assembly (4) installed on the first section of the telescopic conveyor (2); The material taking component (4) is configured to reciprocate along the conveying direction of the telescopic machine (2), and at the starting material taking position of the first section of the telescopic machine (2), raise the belt conveyor surface at the starting material taking position, so that the belt conveyor surface behind the starting material taking position is higher than the belt conveyor surface in front.

2. The telescopic conveyor material handling device according to claim 1, characterized in that, The telescopic conveyor material handling device also includes a transfer component (5), one end of which is installed on an automatic loading device for transferring materials on the telescopic conveyor (2) to the cargo compartment of a truck, and the other end is suspended in the air; The transfer component (5) is configured to move to the front of the material taking component (4) along with the automatic loading device, and to make the suspended end of the transfer component (5) the same height as the starting material taking position and the distance between them less than the preset distance.

3. The telescopic conveyor material handling device according to claim 1, characterized in that, The material handling component (4) includes: Two guide rails (401) are installed on the left and right sides of the telescopic machine (2) and guided along the conveying direction of the telescopic machine; wherein, the left and right directions are horizontally transverse to the conveying direction of the telescopic machine (2); Two racks (402) are fixedly installed on the two guide rails (401) respectively; Two support plates (404) are symmetrically arranged on the left and right sides of the telescopic machine (2). The support plates (404) are provided with grooves (A). A gear assembly connected to the support plate (404) includes two gears (407) and a gear drive assembly. The two gears (407) mesh with two racks (402) respectively, and the gear drive assembly drives the gears (407) to rotate. Linear motion module (410), one linear motion module (410) is installed on each of the support plates (404); The second roller (405) is fixedly connected to the linear motion modules (410) on the left and right sides at its left and right ends. The second roller (405) is located on the lower side of the belt (201) of the telescopic machine (2). A first motor (411) is fixedly connected to each linear motion module (410); the first motor (411) is used to drive the linear motion module (410) and thus drive the second roller (405) to move along the groove (A) to raise the belt conveyor surface of the telescopic machine (2); and The redirecting roller assembly is located below the second roller (405). After the belt (201) of the telescopic machine (2) passes over the second roller (405) from top to bottom, it returns to the original conveying direction through the redirecting roller assembly.

4. The telescopic conveyor material handling device according to claim 3, characterized in that, The gear drive assembly includes: Two square bearing seats (414) are fixedly installed on two support plates (404) respectively; The speed reducer (412) is fixedly mounted on one of the support plates (404); The second motor (413) is fixedly mounted on the reducer (412); A first drive shaft (415) passes through the reducer (412) and two square bearing seats (414), and two gears (407) are respectively fixedly installed on the left and right sides of the first drive shaft (415); The first roller (403) is arranged in the middle of the two gears (407) and is rotatably mounted on the first drive shaft (415).

5. The telescopic conveyor material handling device according to claim 3, characterized in that, The guide rail (401) is a U-shaped guide rail with a U-shaped groove, and the openings of the U-shaped grooves of the two guide rails (401) on the left and right sides are arranged opposite each other; The material handling assembly (4) also includes a plurality of guide units installed on the bottom side of the support plate (404). The guide unit includes a stepped shaft (408) and a flange bearing (409). The stepped shaft (408) is fixedly installed on the support plate (404). The inner circle of the flange bearing (409) is rotatably installed on the stepped shaft (408), and the outer circle is movably installed in the U-shaped groove of the guide rail (401). The flange of the flange bearing (409) is in contact with the guide rail (401).

6. The telescopic conveyor material handling device according to claim 3, characterized in that, The redirecting roller assembly includes three redirecting rollers (406), the axis of which is parallel to the axis of the second roller (405); The first and second redirecting rollers (406) are both located below the second roller (405). In the conveying direction of the telescopic conveyor (2), the first redirecting roller (406) is located behind the second roller (405), and the second redirecting roller (406) is located in front of the second roller (405). The third redirecting roller (406) is located above the second redirecting roller (406). The forward direction is defined as the positive direction of the conveying direction of the telescopic conveyor (2), and the backward direction is the opposite direction of the forward direction. The belt (201) of the telescopic machine (2) extends backward after passing over the second roller (405) from top to bottom, then extends forward after passing over the first redirecting roller (406) from top to bottom, then passes over the front side of the second redirecting roller (406) from bottom to top, and then passes over the third redirecting roller (406) from back to front, and then extends towards the front side of the telescopic machine (2).

7. The telescopic conveyor material handling device according to claim 2, characterized in that, The transfer component (5) is also configured to transport materials from back to front.