A carbonization device for processing biodegradable bamboo fibers
By combining the design of the electric push rod-driven sliding seat and the connecting frame, the automatic positioning and stable feeding of bamboo fiber are realized, which solves the problem of low feeding efficiency of existing equipment and improves production efficiency and automation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN UNIVERSE ECO TECH CO LTD
- Filing Date
- 2025-07-25
- Publication Date
- 2026-06-19
AI Technical Summary
Existing bamboo fiber processing carbonization equipment has low feeding efficiency and lacks automation, resulting in high labor intensity and low production efficiency.
The sliding seat and connecting frame are driven by a first electric push rod and a second electric push rod to achieve automatic positioning and stable feeding of bamboo fiber, and continuous feeding is achieved by combining gravity and pushing force.
It improved feeding efficiency, enhanced the automation level and operational stability of the equipment, reduced labor intensity, and increased production efficiency.
Smart Images

Figure CN224377956U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of biomass carbonization technology, and in particular to a biodegradable bamboo fiber processing carbonization device. Background Technology
[0002] A biodegradable bamboo fiber carbonization device is used to process bamboo fiber, causing physical and chemical changes through a series of processes. This device is mainly used in the field of biomass material improvement and utilization, especially for the processing of bamboo or bamboo fiber. Its core purpose is to improve the performance of bamboo fiber through the carbonization process, such as durability, insect resistance, and stability, while ensuring that the processed bamboo fiber has a certain degree of biodegradability to meet environmental protection requirements.
[0003] Existing bamboo fiber processing carbonization equipment typically includes a carbonization furnace, a heating system, a temperature control device, and a corresponding material conveying structure. Its working principle is to carbonize bamboo fiber in a high-temperature, high-humidity, or high-pressure environment to remove perishable components such as sugar and starch, thereby improving the stability and durability of the material. However, in practical applications, existing equipment generally suffers from low feeding efficiency. Traditional feeding methods are mostly manual or semi-automatic, lacking efficient automated feeding structures, resulting in long feeding times for each process, which not only increases labor intensity but also reduces overall production efficiency.
[0004] To address the aforementioned issues, a biodegradable bamboo fiber processing and carbonization device capable of rapid feeding needs to be designed. Utility Model Content
[0005] To overcome the drawback of low feeding efficiency, this utility model provides a biodegradable bamboo fiber processing carbonization device.
[0006] The technical solution of this utility model is as follows: A biodegradable bamboo fiber processing carbonization device includes a carbonization furnace, an exhaust pipe, a furnace cover, a support base, a stop block, a first sliding seat, a support frame, a connecting plate, a guide plate, a first electric push rod, a second sliding seat, a connecting frame, a mounting frame, a second electric push rod, and a connecting frame. An exhaust pipe is connected to the carbonization furnace. A furnace cover is rotatably connected to the front left side of the carbonization furnace. A support base is connected to the lower side inside the carbonization furnace. Stop blocks are symmetrically connected to the left and right sides of the front side of the support base. A first sliding seat is slidably connected to the support base. A support frame is connected to the upper side of the first sliding seat. A connecting plate is connected to the lower right side of the carbonization furnace. A guide plate is connected to the front side of the connecting plate. A second sliding seat is slidably connected to the guide plate. A first electric push rod is installed on the right side of the guide plate. The left end of the first electric push rod is fixedly connected to the second sliding seat. A connecting frame is connected to the upper side of the second sliding seat. A mounting frame is connected to the right side of the second sliding seat. A second electric push rod is installed inside the mounting frame. A connecting frame is connected to the left end of the second electric push rod. The connecting frame and the connecting frame slide together.
[0007] Optionally, it also includes a sliding frame, which is slidably connected to the support frame.
[0008] Optionally, it also includes a flange, with the left end of the exhaust pipe connected to a flange.
[0009] Optionally, it also includes a pull handle, with pull handles symmetrically provided on the upper and lower sides of the front side of the furnace cover.
[0010] Optionally, it also includes handles, with handles symmetrically connected to the left and right sides of the support frame.
[0011] Optionally, it also includes wheels, with wheels symmetrically mounted on the outer side of the second sliding seat.
[0012] The beneficial effects of this utility model are as follows: Through the arrangement of the first electric push rod, the second sliding seat, the connecting frame, the mounting bracket, the second electric push rod and the connecting bracket, the first electric push rod drives the second sliding seat to move along the guide plate, and the second sliding seat drives the connecting frame and subsequent components to move horizontally as a whole, thereby achieving the positioning of the feeding component; while the second electric push rod drives the connecting bracket to move, so that the bamboo fiber falls smoothly to the designated position under the combined action of gravity and pushing force, ensuring that the feeding process is continuous and controllable, which not only improves the feeding efficiency, but also enhances the automation and stability of the equipment operation. Attached Figure Description
[0013] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0014] Figure 2 This is a three-dimensional structural diagram of the components of this utility model, including the gas outlet pipe, furnace cover, and support base.
[0015] Figure 3 This is an exploded view of the stop block, the first sliding seat, and the support frame of this utility model.
[0016] Figure 4 This is a three-dimensional structural diagram of the connecting plate, guide plate, and first electric push rod of this utility model.
[0017] Figure 5 This is an exploded view of the connecting frame, mounting bracket, and second electric push rod of this utility model.
[0018] Figure 6 This is an exploded view of the support frame, handle, and sliding bracket of this utility model.
[0019] Reference numerals: 1-Carbonization furnace, 101-Gas outlet pipe, 102-Flange, 2-Furnace cover, 21-Pull handle, 3-Support base, 31-Stop block, 4-First sliding seat, 5-Support frame, 51-Handle, 6-Sliding frame, 7-Connecting plate, 8-Guide plate, 9-First electric push rod, 10-Second sliding seat, 1001-Wheel, 11-Connecting frame, 12-Mounting bracket, 13-Second electric push rod, 14-Connecting bracket. Detailed Implementation
[0020] The present invention will now be described in detail with reference to the accompanying drawings.
[0021] Example: A biodegradable bamboo fiber processing carbonization device, such as Figures 1-6 As shown, the system includes a carbonization furnace 1, an exhaust pipe 101, a flange 102, a furnace cover 2, a handle 21, a support base 3, a stop block 31, a first sliding seat 4, a support frame 5, a handle 51, a sliding frame 6, a connecting plate 7, a guide plate 8, a first electric push rod 9, a second sliding seat 10, a wheel 1001, a connecting frame 11, a mounting bracket 12, a second electric push rod 13, and a connecting bracket 14. The carbonization furnace 1 is connected to an exhaust pipe 101, which is used to discharge waste gas or steam generated during the carbonization process. A flange 102 is connected to the left end of 101. A furnace cover 2 is rotatably connected to the front left side of the carbonization furnace 1. The furnace cover 2 is used to seal the carbonization furnace 1 to prevent heat and gas leakage. Pull handles 21 are symmetrically provided on the upper and lower sides of the front side of the furnace cover 2. A support base 3 is connected to the lower side inside the carbonization furnace 1. A stop block 31 is symmetrically connected to the left and right sides of the front side of the support base 3. The stop block 31 is used to limit the movement range of the first sliding seat 4 to prevent the first sliding seat 4 from sliding out excessively. The first sliding seat 4 is slidably connected to the support base 3. A support frame is connected to the upper side of the first sliding seat 4. 5. The support frame 5 is used to support the sliding frame 6. Handles 51 are symmetrically connected to the left and right sides of the support frame 5. The sliding frame 6 is slidably connected to the support frame 5. A connecting plate 7 is connected to the lower right side of the carbonization furnace 1. A guide plate 8 is connected to the front side of the connecting plate 7. A second sliding seat 10 is slidably connected to the guide plate 8. Wheels 1001 are symmetrically installed on the front and back of the outer side of the second sliding seat 10. A first electric push rod 9 is installed on the right side of the guide plate 8. The left end of the first electric push rod 9 is fixedly connected to the second sliding seat 10. The first electric push rod 9 can drive... The second sliding seat 10 moves. A connecting frame 11 is connected to the upper side of the second sliding seat 10. A mounting frame 12 is connected to the right side of the second sliding seat 10. The mounting frame 12 is used to install the second electric push rod 13. The second electric push rod 13 is installed inside the mounting frame 12. The second electric push rod 13 can drive the connecting frame 14 to move and control the bamboo fiber feeding action. The left end of the second electric push rod 13 is connected to the connecting frame 14. The connecting frame 14 slides with the connecting frame 11. The connecting frame 14 is used to support the bamboo fiber to be carbonized.
[0022] When this device is needed to carbonize bamboo fiber, the operator first pulls handle 21 to rotate and open the furnace cover 2, thus exposing the operating space inside the carbonization furnace 1. Then, the operator pulls handle 51 to slide the support frame 5, sliding frame 6, and first sliding seat 4 horizontally outward along the support base 3 until the first sliding seat 4 moves to contact and be limited by the two stops 31. At this point, the operator stops pulling handle 51. Next, the operator activates the first electric push rod 9, which pushes the second sliding seat 10 along the guide plate. 8. Move to the left. The second sliding seat 10 drives the connecting frame 11, the second electric push rod 13, the connecting frame 14, and the bamboo fiber to be carbonized loaded on it to move to the left together until the connecting frame 11 is completely inside the support frame 5. Then, close the first electric push rod 9. Subsequently, start the second electric push rod 13. The second electric push rod 13 drives the connecting frame 14 to move to the right. During the movement of the connecting frame 14, the bamboo fiber gradually falls from the connecting frame 14 to the sliding frame 6 below under the combined action of gravity and pushing force. When all the bamboo fiber has fallen... After the material has been completely discharged and there is no residual material on the connecting frame 14, the second electric push rod 13 moves the connecting frame 14 to the left to reset it to its initial position. Then, the second electric push rod 13 is turned off, and the first electric push rod 9 is started again. The first electric push rod 9 moves the second sliding seat 10 to the right, which in turn moves the connecting frame 11, the second electric push rod 13, and the connecting frame 14 to the right simultaneously until the second sliding seat 10 returns to its initial position. Then, the first electric push rod 9 is turned off, completing the entire automatic feeding process. Afterward, the operator holds the handle 51 and... The support frame 5, sliding frame 6, and first sliding seat 4 are pushed inward along the support seat 3 to reset the support frame 5 to its original position. After confirming that the reset is complete, the handle 51 is released and the pull handle 21 is pulled to rotate the furnace cover 2 in the opposite direction to close it, sealing the carbonization furnace 1. Finally, the carbonization furnace 1 is started, and the carbonization furnace 1 begins to carbonize the bamboo fiber on the sliding frame 6 under high temperature, high humidity, or high pressure to remove perishable components such as sugar, starch, and protein, thereby improving the stability, durability, and antibacterial properties of the bamboo fiber and completing the entire carbonization process.
[0023] It should be understood that the above description is for illustrative purposes only and is not intended to limit the present invention. Those skilled in the art will understand that variations of the present invention will be included within the scope of the claims herein.
Claims
1. A biodegradable bamboo fiber processing carbonization device, characterized by: The furnace includes a carbonization furnace (1), an exhaust pipe (101), a furnace cover (2), a support base (3), a stop block (31), a first sliding seat (4), a support frame (5), a connecting plate (7), a guide plate (8), a first electric push rod (9), a second sliding seat (10), a connecting frame (11), a mounting bracket (12), a second electric push rod (13), and a connecting bracket (14). An exhaust pipe (101) is connected to the carbonization furnace (1). A furnace cover (2) is rotatably connected to the front left side of the carbonization furnace (1). A support base (3) is fixedly connected to the lower inner side of the carbonization furnace (1). Stop blocks (31) are symmetrically fixedly connected to the left and right sides of the front side of the support base (3). A first sliding seat (4) is slidably connected to the support base (3). 4) A support frame (5) is fixedly connected to the upper side, a connecting plate (7) is fixedly connected to the lower right side of the carbonization furnace (1), a guide plate (8) is fixedly connected to the front side of the connecting plate (7), a second sliding seat (10) is slidably connected to the guide plate (8), a first electric push rod (9) is installed on the right side of the guide plate (8), the left end of the first electric push rod (9) is fixedly connected to the second sliding seat (10), a connecting frame (11) is fixedly connected to the upper side of the second sliding seat (10), an mounting bracket (12) is installed on the right side of the second sliding seat (10), a second electric push rod (13) is installed inside the mounting bracket (12), a connecting frame (14) is connected to the left end of the second electric push rod (13), and the connecting frame (14) and the connecting frame (11) slide together.
2. The device for processing and carbonizing of biodegradable bamboo fiber according to claim 1, characterized in that: It also includes a sliding frame (6), which is slidably connected to the support frame (5).
3. The device for processing and carbonizing of biodegradable bamboo fiber according to claim 2, characterized in that: It also includes a flange (102), and the left end of the vent pipe (101) is provided with a flange (102).
4. The biodegradable bamboo fiber processing carbonization device as described in claim 3, characterized in that: It also includes a handle (21), and the front side of the furnace cover (2) is symmetrically equipped with handles (21) on the upper and lower sides.
5. The biodegradable bamboo fiber processing carbonization device as described in claim 4, characterized in that: It also includes handles (51), and the left and right sides of the support frame (5) are symmetrically fixedly connected with handles (51).
6. The biodegradable bamboo fiber processing carbonization device as described in claim 5, characterized in that: It also includes wheels (1001), with wheels (1001) symmetrically installed on the outer side of the second sliding seat (10).