Conveniently transportable storage and feeding device for carbon production

By designing components such as a fixed plate, limit slide rail, screw slide rail, and screw feeder, the problems of quick assembly and disassembly of the storage feeding device and the stability of material discharge were solved, enabling flexible installation and height adjustment of the storage tank and improving ease of use.

CN224477348UActive Publication Date: 2026-07-10LUOYANG XINWANG CARBON MATERIAL

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LUOYANG XINWANG CARBON MATERIAL
Filing Date
2025-08-19
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

The existing carbon product transfer vehicle's material tank cannot be quickly disassembled and assembled, the discharge is unstable and the discharge height is not adjustable, making it inconvenient to use.

Method used

A storage and feeding device was designed, comprising a fixed plate, a limiting slide rail, a lead screw slide rail, a screw feeder, and a drive motor. The storage tank can be quickly disassembled and its height adjusted by fixing bolts, moving sliders, and lead screw sliders, and stable material discharge can be achieved by combining the screw feeder.

Benefits of technology

It enables quick adaptation and installation of storage tanks, stable material discharge, and adjustable discharge height, making it more convenient to use.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model discloses a kind of storage feeding device for carbon production convenient transfer, including bottom plate, the one side fixed connection of lifting slide block has push-pull handle, and push-pull handle front and back side edge protruding fixed connection has locking seat, the second locking knob is inserted into and is connected in the inner wall of locking seat, the bottom plate lower end corner fixed connection has universal wheel, the drive motor, screw mechanism are electrically connected with PLC controller.This kind of storage feeding device for carbon production convenient transfer can be driven by fixed bolt, moving slider, moving sliding slot auxiliary clamping block flexible sliding adjustment, it is convenient to store tank and carry out quick adaptation clamping installation, and spiral feeder, inlet, feeding groove and discharge port can be stably spirally discharged, and can be extended by extending discharge pipe to carry out extension adjustment, and can be driven by screw block, screw sliding rail, screw mechanism to carry out lifting adjustment for storage tank, it is convenient to adjust discharge height, use more conveniently.
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Description

Technical Field

[0001] This utility model relates to the field of carbon production transfer technology, specifically a storage and feeding device for convenient transfer in carbon production. Background Technology

[0002] In the carbon production process, it is necessary to store and transfer carbon raw materials (such as petroleum coke, needle coke, etc.) in order to achieve raw material supply between different production processes.

[0003] A current carbon product transfer vehicle (CN202320574262.3) with lifting and lowering capability is used to transfer carbon products. A drive motor rotates the transfer box, allowing for adjustment of the transfer orientation, making it convenient to use. The rotating motor also drives the drive assembly to rotate, achieving automatic steering and improving transfer flexibility. However, it has shortcomings: the material tank cannot be quickly disassembled or assembled, and it cannot provide stable discharge. Furthermore, the discharge height is not adjustable, making it inconvenient to use. Therefore, a convenient storage and feeding device for carbon production is needed to solve these problems. Utility Model Content

[0004] The purpose of this utility model is to provide a convenient storage and feeding device for carbon production, in order to solve the problems mentioned in the background art, such as the inability to quickly disassemble and assemble the material tank of the carbon product transfer vehicle that can be lifted and used, the inability to discharge material more stably, and the inability to adjust the discharge height, which makes it inconvenient to use.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a convenient storage and feeding device for carbon production, comprising a base plate, a fixing plate vertically fixedly connected to one edge of the upper end of the base plate, and a controller electrically connected to the middle position of one side of the fixing plate; a limit slide rail vertically fixedly connected to the front corner of the upper end of the base plate, and a limit slider slidably inserted into the inner wall of the limit slide rail; a lead screw slide rail vertically fixedly connected to the rear corner of the upper end of the base plate, and a lead screw slider slidably inserted into the inner wall of the lead screw slide rail, wherein the lead screw slider and the inner wall of the lead screw slide rail penetrate through each other. A screw mechanism is connected to the upper part of the load-bearing plate, and a load-bearing plate is fixedly connected between the screw slider and the limiting slider. The upper end of the load-bearing plate has movable grooves at its front and rear corners, and a movable slider is slidably inserted into the inner wall of the movable groove. An auxiliary clamping block is fixedly connected to the upper end of the movable slider, and a fixing bolt is inserted into one side of the inner wall of the auxiliary clamping block. A storage tank is placed at the middle position of the upper end of the load-bearing plate, and an elastic rotating shaft is flipped and connected to the rear side of the upper end of the storage tank. A tank lid is fixedly connected to the other side of the elastic rotating shaft, and a positioning buckle is vertically fixed to the front side of the lower end of the tank lid. A first locking knob is connected to the side, and a positioning buckle is engaged with a positioning buckle slot. The positioning buckle slot is located at the upper front end of the storage tank, and an inlet is located at the lower end of the inner wall of the storage tank. A feeding trough is connected to the lower end of the inlet, and a screw feeder is inserted into the inner wall of the feeding trough. A drive motor is fixedly connected to one end of the screw feeder, and the drive motor is embedded in the lower side of the storage tank. An outlet is connected to the other side of the feeding trough, and a threaded mounting groove is located on the other edge of the outlet. A threaded ring is inserted into the inner wall of the threaded mounting groove. One end of the threaded ring is fixedly connected to an extended discharge pipe. The front and rear sides of the base plate are movably connected to threaded seats, and the inner walls of the threaded seats are fitted with support screws on both sides. The outer edge of the fixed plate is provided with a lifting slide groove, and the inner wall of the lifting slide groove is slidably fitted with a lifting slider. One side of the lifting slider is fixedly connected to a push-pull handle, and the front and rear edges of the push-pull handle are protruding and fixedly connected to locking seats. The inner wall of the locking seat is fitted with a second locking knob. The lower corner of the base plate is fixedly connected to a caster wheel. The drive motor, the lead screw mechanism, and the PLC controller are electrically connected.

[0006] Preferably, the push-pull handle is slidably and vertically connected to the fixed plate via a lifting slider and a lifting groove, and the push-pull handle is locked and fixedly connected to the fixed plate via a second locking knob and a locking seat.

[0007] Preferably, the storage tank is clamped and fixedly connected to the load-bearing plate by an auxiliary clamping block and a fixing bolt, and the auxiliary clamping block is laterally slidably connected to the load-bearing plate by a movable slider and a movable groove.

[0008] Preferably, the storage tank and the load-bearing plate are connected to the screw slide rail via a screw slider and a screw mechanism, and the load-bearing plate is connected to the limit slider via a limit slide rail, and the front side of the storage tank has a viewing window structure.

[0009] Preferably, the casters are arranged in a matrix at the lower end of the base plate, and the casters are self-locking. The support screw is connected to the base plate by a threaded seat in a screw-on lifting connection. The base plate has an integrated lithium battery structure on its inner wall.

[0010] Preferably, the screw feeder is rotatably connected to the feeding trough and the discharge port via a drive motor, the inlet is inclined to the edge of the feeding trough, and the extended discharge pipe is screwed and spliced ​​to the discharge port via a threaded ring and a threaded mounting groove.

[0011] Compared with the prior art, the beneficial effects of this utility model are: the convenient transfer storage and feeding device for carbon production can be flexibly adjusted by the auxiliary clamping block through the fixing bolt, moving slider, and moving chute, which facilitates the quick adaptation and clamping installation of the storage tank. It can also stably discharge material through the screw feeder, inlet, feeding chute and outlet, and can be extended and adjusted by the extension of the discharge pipe. Furthermore, the storage tank can be raised and lowered by the screw slider, screw rail and screw mechanism, which facilitates the adjustment of the discharge height and makes it more convenient to use. Attached Figure Description

[0012] Figure 1 This is a front view of a convenient storage and feeding device for carbon production according to the present invention.

[0013] Figure 2 This is a schematic diagram of the internal structure of a convenient transfer storage and feeding device for carbon production according to this utility model.

[0014] Figure 3 This utility model relates to a convenient storage and feeding device for carbon production. Figure 2 Enlarged view of point A in the middle;

[0015] Figure 4 This utility model relates to a convenient storage and feeding device for carbon production. Figure 2 Enlarged view at point B in the middle;

[0016] Figure 5 This utility model relates to a convenient storage and feeding device for carbon production. Figure 2 Enlarged view at point C;

[0017] Figure 6 This utility model relates to a convenient storage and feeding device for carbon production. Figure 2 Enlarged view at point D;

[0018] Figure 7 This utility model relates to a convenient storage and feeding device for carbon production. Figure 1 Enlarged view of point E in the middle.

[0019] In the diagram: 1. Base plate, 2. Fixing plate, 3. PLC controller, 4. Push-pull handle, 5. Storage tank, 6. Casters, 7. Elastic shaft, 8. Screw feeder, 9. Tank lid, 10. Limiting slider, 11. Limiting slide rail, 12. Inlet, 13. Threaded seat, 14. Support screw, 15. Load-bearing plate, 16. Feeding trough, 17. Drive motor, 18. Auxiliary clamping block, 19. Screw slider, 20. Screw slide rail, 21. Screw mechanism, 22. Fixing bolt, 23. Moving slider, 24. Moving slide groove, 25. Threaded ring, 26. Threaded mounting groove, 27. Extended discharge pipe, 28. Discharge port, 29. Positioning buckle, 30. Positioning buckle groove, 31. First locking knob, 32. Lifting slider, 33. Lifting slide groove, 34. Second locking knob, 35. Locking seat. Detailed Implementation

[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0021] Please see Figure 1-7This utility model provides a technical solution: a convenient storage and feeding device for carbon production, comprising a base plate 1, a fixed plate 2, a PLC controller 3, a push-pull handle 4, a storage tank 5, casters 6, an elastic rotating shaft 7, a screw feeder 8, a tank cover 9, a limiting slider 10, a limiting slide rail 11, a feed inlet 12, a threaded seat 13, a supporting screw 14, a load-bearing plate 15, a feeding trough 16, a drive motor 17, an auxiliary clamping block 18, a lead screw slider 19, a lead screw slide rail 20, a lead screw mechanism 21, a fixing bolt 22, a moving slider 23, a moving slide groove 24, a threaded ring 25, a threaded mounting groove 26, an extended discharge pipe 27, a discharge port 28, a positioning buckle 29, a positioning buckle groove 30, a first locking knob 31, a lifting slider 32, and a lifting slide groove 3. 3. A second locking knob 34 and a locking seat 35 are provided. A fixing plate 2 is vertically fixed to one edge of the upper end of the base plate 1, and a controller 3 is electrically connected to the middle of one side of the fixing plate 2. A limit slide rail 11 is vertically fixed to the front corner of the upper end of the base plate 1, and a limit slider 10 is slidably inserted into the inner wall of the limit slide rail 11. A screw slide rail 20 is vertically fixed to the rear corner of the upper end of the base plate 1, and a screw slider 19 is slidably inserted into the inner wall of the screw slide rail 20. A screw mechanism 21 is inserted through the inner wall of the screw slider 19 and the screw slide rail 20. A load-bearing plate 15 is fixedly connected between the screw slider 19 and the limit slider 10. A movable slide groove 24 is provided at the front and rear corners of the upper end of the load-bearing plate 15, and a movable slider 23 is slidably inserted into the inner wall of the movable slide groove 24. An auxiliary clamping block 18 is fixedly connected to the upper end of the movable slider 23, and a fixing bolt 22 is inserted into one side of the inner wall of the auxiliary clamping block 18. A storage tank 5 is placed at the middle position of the upper end of the load-bearing plate 15, and an elastic rotating shaft 7 is flipped and connected to the rear side of the upper end of the storage tank 5. A can lid 9 is fixedly connected to the other side of the elastic rotating shaft 7, and a positioning buckle 29 is vertically fixed to the front side of the lower end of the can lid 9. A first locking knob 31 is inserted into the front side of the positioning buckle 29, and the positioning buckle 29 is inserted into the positioning buckle groove 30. The positioning buckle groove 30 is opened at the upper front end of the storage tank 5, and an inlet 12 is opened at the lower end of the inner wall of the storage tank 5. The storage tank 5 is clamped and fixedly connected to the load-bearing plate 15 by the auxiliary clamping block 18 and the fixing bolt 22. The auxiliary clamping block 18 is moved by the movable slider 23 and the movable slider 23. The chute 24 and the load-bearing plate 15 are laterally slidably connected, allowing the storage tank 5 to be quickly assembled and disassembled via the auxiliary clamp 18. This also allows for clamping and fixing of storage tanks 5 with different structures. The storage tank 5 and the load-bearing plate 15 are connected to the screw slide rail 20 via the screw slider 19 and the screw mechanism 21, enabling screw lifting and lowering. The load-bearing plate 15 is also connected to the limiting slider 10 via the limiting slide rail 11. The front of the storage tank 5 has a viewing window structure, allowing for screw lifting and lowering adjustment of the storage tank 5 and the load-bearing plate 15, facilitating adjustment of the discharge height. The lower end of the inlet 12 is connected to a feeding trough 16, and a screw feeder 8 is inserted into the inner wall of the feeding trough 16. The screw feeder 8 is rotatably connected to the feeding trough 16 and the discharge port 28 via a drive motor 17.The inlet 12 and the edge of the feeding trough 16 are inclined. The extended discharge pipe 27 is connected to the discharge port 28 by a threaded ring 25 and a threaded mounting groove 26. This allows the screw feeder 8 to discharge material stably and efficiently through the feeding trough 16 and the discharge port 28. One end of the screw feeder 8 is fixedly connected to a drive motor 17, which is embedded in the lower end of one side of the storage tank 5. The other side of the feeding trough 16 is connected to the discharge port 28, and the other edge of the discharge port 28 has a threaded mounting groove 26. A threaded ring 25 is inserted into the inner wall of the threaded mounting groove 26, and the extended discharge pipe 27 is fixedly connected to one end of the threaded ring 25. Threaded seats 13 are movably connected to the front and rear sides of the base plate 1, and support screws 14 are inserted into the inner walls of the threaded seats 13. A lifting slide 33 is opened on the outer edge of the fixed plate 2, and a lifting slider 32 is slidably inserted into the inner wall of the lifting slide 33. A push-pull handle 4 is fixedly connected to one side of the lifting slider 32, and locking seats 35 are fixedly connected to the front and rear edges of the push-pull handle 4. The push-pull handle 4 is slidably lifted and lowered to the fixed plate 2 through the lifting slider 32 and the lifting slide 33, and is also locked and fixedly connected to the fixed plate 2 through the second locking knob 34 and the locking seat 35. This makes it easy to slide and adjust the push-pull handle 4 for easy push-pull use. The second locking knob 34 is inserted and connected to the inner wall of the locking seat 35. Universal wheels 6 are fixedly connected to the lower corner of the base plate 1. The universal wheels 6 are distributed in a matrix position at the lower end of the base plate 1 and have a self-locking structure. The support screw 14 is screwed and lifted and lowered to the base plate 1 through the threaded seat 13. The base plate 1 has an integrated lithium battery structure on the inner wall, which makes the device easy and stable to push and pull and support and fix, and stable in use. The drive motor 17, the screw mechanism 21 and the PLC controller 3 are electrically connected.

[0022] Working principle: When using this convenient storage and feeding device for carbon production, first adjust the push-pull handle 4 to the appropriate position using the lifting slider 32, lifting chute 33, second locking knob 34, and locking seat 35. Then, the can lid 9 is opened by elastically flipping it open via the elastic rotating shaft 7. Next, the material is injected into the storage tank 5, and then the can lid 9 is flipped closed and positioned by the positioning buckle 29 and positioning buckle groove 30. Then, it is locked and fixed by the first locking knob 31. Then, it is moved by pushing and pulling via the universal wheel 6. When it is necessary to discharge the material, it can be self-locked by the universal wheel 6. Then, it is supported and fixed by the threaded seat 13 and support screw 14. Then, the material is spirally discharged through the feed port 12 and the feeding chute 16 by the screw feeder 8 and the drive motor 17. When it is necessary to adjust the discharge height, the screw can be raised and lowered by the screw slider 19, screw slide rail 20, and screw mechanism 21. This is the usage process of this convenient storage and feeding device for carbon production.

[0023] It should be noted that this utility model is a storage and feeding device for convenient transfer in carbon production. All components are standard parts or parts known to those skilled in the art. Its structure and principle can be learned by those skilled in the art through technical manuals or conventional experimental methods. Furthermore, all electrical components mentioned above refer to power elements, electrical components, and the matching monitoring computer and power supply connected by wires. The specific connection method should refer to the working principle described above, and the electrical connection between each electrical component should be completed in the order of operation. The detailed connection method is a well-known technology in the field.

[0024] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. A convenient storage and feeding device for carbon production, comprising a base plate (1), wherein a fixing plate (2) is vertically fixedly connected to one edge of the upper end of the base plate (1), and a controller (3) is electrically connected to the middle position of one side of the fixing plate (2), characterized in that: A limiting slide rail (11) is vertically fixed to the front corner of the upper end of the base plate (1), and a limiting slider (10) is slidably inserted into the inner wall of the limiting slide rail (11). A screw slide rail (20) is vertically fixed to the rear corner of the upper end of the base plate (1), and a screw slider (19) is slidably inserted into the inner wall of the screw slide rail (20). A screw mechanism (21) is inserted through the inner wall of the screw slider (19) and the screw slide rail (20). A load-bearing plate (15) is fixedly connected between the screw slider (19) and the limiting slider (10). A movable slide groove (24) is provided at the front and rear corners of the upper end of the load-bearing plate (15), and a movable slide is slidably inserted into the inner wall of the movable slide groove (24). Block (23), the upper end of the movable slider (23) is fixedly connected to an auxiliary clamping block (18), and a fixing bolt (22) is inserted into one side of the inner wall of the auxiliary clamping block (18). A storage tank (5) is placed in the middle of the upper end of the load-bearing plate (15), and an elastic rotating shaft (7) is flipped and connected to the rear side of the upper end of the storage tank (5). A can lid (9) is fixedly connected to the other side of the elastic rotating shaft (7), and a positioning buckle (29) is vertically fixed to the front side of the lower end of the can lid (9). A first locking knob (31) is inserted into the front side of the positioning buckle (29), and the positioning buckle (29) is inserted into the positioning buckle groove (30). The positioning buckle groove (30) is opened at the upper front side of the storage tank (5). The storage tank (5) has an inlet (12) at the lower end of its inner wall. The inlet (12) is connected to a feeding trough (16) at the lower end. A screw feeder (8) is inserted into the inner wall of the feeding trough (16). A drive motor (17) is fixedly connected to one end of the screw feeder (8). The drive motor (17) is embedded in the lower end of one side of the storage tank (5). An outlet (28) is connected to the other side of the feeding trough (16). A threaded mounting groove (26) is provided on the edge of the other side of the outlet (28). A threaded ring (25) is inserted into the inner wall of the threaded mounting groove (26). An extension outlet pipe (27) is fixedly connected to one end of the threaded ring (25). The bottom plate (1) The front and rear sides are connected to threaded seats (13), and the inner walls of the threaded seats (13) are connected to support screws (14). The outer edge of the fixed plate (2) is provided with a lifting slide groove (33), and the inner wall of the lifting slide groove (33) is connected to a lifting slider (32). The lifting slider (32) is fixedly connected to one side with a push-pull handle (4), and the front and rear edges of the push-pull handle (4) are fixedly connected to a locking seat (35). The inner wall of the locking seat (35) is connected to a second locking knob (34). The lower corner of the base plate (1) is fixedly connected to a universal wheel (6). The drive motor (17), the screw mechanism (21) and the PLC controller (3) are electrically connected.

2. The convenient transfer storage and feeding device for carbon production according to claim 1, characterized in that: The push-pull handle (4) is connected to the fixed plate (2) in a sliding lifting connection via the lifting slider (32) and the lifting groove (33), and the push-pull handle (4) is connected to the fixed plate (2) in a locking connection via the second locking knob (34) and the locking seat (35).

3. A convenient storage and feeding device for carbon production according to claim 2, characterized in that: The storage tank (5) is clamped and fixedly connected to the load-bearing plate (15) by an auxiliary clamp (18) and a fixing bolt (22), and the auxiliary clamp (18) is laterally slidably connected to the load-bearing plate (15) by a movable slider (23) and a movable slide groove (24).

4. A convenient storage and feeding device for carbon production according to claim 3, characterized in that: The storage tank (5) and the load-bearing plate (15) are connected to the screw slide rail (20) via the screw slider (19) and the screw mechanism (21) in a screw lifting motion. The load-bearing plate (15) is connected to the limit slider (10) via the limit slide rail (11) in a limit sliding connection. The front side of the storage tank (5) has a viewing window structure.

5. A convenient storage and feeding device for carbon production according to claim 4, characterized in that: The casters (6) are arranged in a matrix at the lower end of the base plate (1), and the casters (6) are self-locking structures. The support screw (14) is connected to the base plate (1) by a threaded seat (13) in a rotating and lifting connection. The base plate (1) has an inner wall integrated lithium battery structure.

6. A convenient transfer storage and feeding device for carbon production according to claim 5, characterized in that: The screw feeder (8) is rotatably connected to the feeding trough (16) and the discharge port (28) via a drive motor (17). The inlet (12) is inclined to the edge of the feeding trough (16). The extended discharge pipe (27) is screwed and spliced ​​to the discharge port (28) via a threaded ring (25) and a threaded mounting groove (26).