Feeding structure of heavy full-automatic high-speed edge banding machine
By designing a feeding structure with guide and auxiliary parts in the heavy-duty fully automatic high-speed edge banding machine, the problems of jamming and friction caused by material deviation are solved, achieving a stable and continuous feeding process, and improving production efficiency and equipment life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGMEN DAKES SMART HOME CO LTD
- Filing Date
- 2025-09-25
- Publication Date
- 2026-06-05
AI Technical Summary
The existing feeding structure of heavy-duty fully automatic high-speed edge banding machines is prone to material deviation during use, leading to jamming, friction and collision, which affects production efficiency and stability and increases the workload of manual intervention and adjustment.
A feeding structure including a guiding section and an auxiliary section is designed. The guiding section adjusts the spacing between the guide plates through a guiding component and a driving component, while the auxiliary section corrects material deviation through an elastic component to ensure stable conveying. The guiding section consists of a support frame, a cylindrical rod, guide plates, and a driving component, while the auxiliary section consists of a support component and an elastic component. The spacing between the guide plates and the guide wheels are adjusted by a motor drive and a spring to reduce friction.
It achieves stability and continuity in the feeding process, reduces material jamming and friction collisions, improves production efficiency and product quality, and reduces equipment maintenance frequency and costs.
Smart Images

Figure CN224324664U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of edge banding machine technology, and in particular relates to a feeding structure for a heavy-duty fully automatic high-speed edge banding machine. Background Technology
[0002] With the rapid development of industries such as furniture manufacturing and board processing, the requirements for the quality and efficiency of board edge banding are increasing. As the core equipment for achieving efficient and high-quality edge banding of boards, heavy-duty fully automatic high-speed edge banding machines are being used more and more widely. In the operation of heavy-duty fully automatic high-speed edge banding machines, the feeding structure is a key link connecting board conveying and edge banding operations. Its feeding stability and accuracy directly affect the edge banding effect, operating efficiency and board processing quality. Therefore, a high-performance feeding structure for heavy-duty fully automatic high-speed edge banding machines is needed to ensure stable board conveying.
[0003] However, in the existing feeding structure, the material is prone to deviation during use. The deviated material may get stuck in the feeding path, causing feeding interruption and reducing production efficiency. It may also cause abnormal friction and collision between the material and equipment parts due to material deviation, increasing the workload of manual intervention to adjust the material position, and affecting the stability and continuity of the overall production process. Utility Model Content
[0004] The purpose of this utility model is to provide a feeding structure for a heavy-duty fully automatic high-speed edge banding machine. By setting a guide part, the problem of material deviation during use is solved. The deviated material may get stuck in the feeding path, causing feeding interruption and reducing production efficiency. It may also cause abnormal friction and collision between the material and the equipment parts, increasing the workload of manual intervention to adjust the material position, and affecting the stability and continuity of the overall production process.
[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0006] This utility model relates to a feeding structure for a heavy-duty fully automatic high-speed edge banding machine, comprising a conveying assembly, and further comprising: a guide part, the guide part being mounted on top of the conveying assembly; an auxiliary part, the auxiliary part being mounted on the guide part; the guide part comprising a guide component, the guide component being mounted on top of the conveying assembly; a drive component, the drive component being mounted on the guide component; the guide component comprising a support frame fixedly connected to the top of the conveying assembly, wherein two cylindrical rods are provided on both the front and rear sides of the support frame, and the sides of several cylindrical rods extending close to each other extend into the support frame. Each of the cylindrical rods is slidably connected to a support frame. Each of the support frames has a fixed plate fixedly connected to one of its opposite sides. Two guide plates are installed inside each support frame. The two guide plates are fixedly connected to each of the cylindrical rods. A connecting member is installed between the fixed plates. One guide plate is fixedly connected to two cylindrical rods, and the two guide plates are located between the cylindrical rods. The connecting member includes two cylindrical rods fixedly connected to the fixed plates. One cylindrical rod is fixedly connected to two fixed plates, ensuring that the opening and closing range of the guide plates on both sides is consistent and preventing unilateral offset.
[0007] Furthermore, the auxiliary part includes a support assembly mounted on two guide plates and an elastic assembly mounted on the support assembly.
[0008] Furthermore, the drive assembly includes two support rods fixedly connected to the top of the support frame. A hexagonal plate is fixedly connected to the top of each support rod, and a motor is fixedly connected to the top of each hexagonal plate. A cross-shaped drive plate is slidably connected to the outer walls of the two support rods. The output shaft of the motor is fixedly connected to a threaded rod via a coupling. The threaded rod passes through the hexagonal plate and extends outwards on the side away from the motor. The threaded rod is rotatably connected to the hexagonal plate, and its bottom is rotatably connected to the support frame. The threaded rod passes through the cross-shaped drive plate, and the cross-shaped drive plate is threadedly connected to the threaded rod. Next, a transmission component is provided on the support frame; a threaded rod is located between two support rods, and the transmission component includes hinged rods fixedly connected to the front and rear sides of the support frame respectively. A drive rod is hinged on each of the two hinged rods, and two slotted plates are opened on each of the two drive rods; the two upper slotted plates are located on the cross drive plate, and the front and rear sides of the cross drive plate are in contact with the two upper slotted plates respectively. The two cylindrical rods are in contact with the inner walls of the two lower slotted plates respectively, realizing the adjustment of the guide plate spacing. This is a key structure for power transmission and motion conversion.
[0009] Furthermore, the support assembly includes several telescopic rods fixedly connected to the two guide plates on their respective sides close to each other. Each of the telescopic rods is fixedly connected to an inverted L-shaped bracket on the side away from the two guide plates. A rotating rod is rotatably connected to the inner top wall of each of the inverted L-shaped brackets. The telescopic rods and the inverted L-shaped brackets are arranged in a linear array to reduce the sliding friction between the material and the guide wheel, thereby reducing material wear and conveying resistance.
[0010] Furthermore, the elastic component includes guide wheels that are fixedly connected to the outer walls of several rotating rods, and springs that are sleeved on the outer walls of several telescopic rods. The sides of several springs that are close to each other are fixedly connected to several inverted L-shaped brackets, and the sides of several springs that are far apart from each other are fixedly connected to two guide plates. The several springs are arranged in a linear array, thereby pushing the material back to the correct conveying path, correcting the deviation, and ensuring stable conveying.
[0011] This utility model has the following beneficial effects:
[0012] 1. By setting up a guide section, the distance between the two guide plates is first adjusted according to the material size. After starting the motor, the motor drives the cross drive plate to slide on the support rod through the threaded rod. The parallel design of the support rod ensures its smooth movement. Then, the cross drive plate drives the drive rod to rotate on the hinge rod through the slotted plate. The drive rod then drives the cylindrical rod two to move closer or further away from each other through the lower slotted plate. In turn, the fixed plate and the cylindrical rod one drive the two guide plates to move closer or further away accordingly, thereby realizing the adjustment of the guide plate spacing. The stable guiding effect can ensure the continuous feeding process, reduce production stoppage caused by material jamming, ensure that production efficiency is not affected, reduce the frequency and cost of equipment maintenance, and extend the service life of the equipment.
[0013] 2. By setting up an auxiliary part, when adjusting the two guide plates, the two guide plates will drive the guide wheels on the rotating rod to move through the corresponding telescopic rods and inverted L-shaped brackets. After adjustment, the conveying assembly is started to transport materials. The rotation connection of the rotating rod can cause the guide wheels to rotate to reduce the friction on the materials. When the materials deviate, they will squeeze the telescopic rod and spring through the guide wheels, causing the spring to deform and generate elastic force. Under the action of elastic force, the materials will be reset, further reducing problems such as jamming and friction collision caused by material deviation, reducing manual intervention, ensuring stable and continuous feeding, and improving production efficiency and product quality.
[0014] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description
[0015] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments 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.
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0017] Figure 2 This is a partial cross-sectional view of the guide section of this utility model;
[0018] Figure 3 This is a partial cross-sectional view of the drive component of this utility model;
[0019] Figure 4 This is a partial cross-sectional view of the connection structure of the guide part of this utility model;
[0020] Figure 5 This is a partial cross-sectional view of the auxiliary part of this utility model.
[0021] The attached diagram lists the components represented by each number as follows:
[0022] 111. Conveying assembly; 2. Guide section; 21. Guide assembly; 211. Support frame; 212. Cylindrical rod one; 213. Fixing plate; 214. Guide plate; 215. Cylindrical rod two; 22. Drive assembly; 221. Support rod; 222. Hexagonal plate; 223. Motor; 224. Cross drive plate; 225. Threaded rod; 226. Hinge rod; 227. Drive rod; 228. Channel plate; 3. Auxiliary section; 31. Support assembly; 311. Telescopic rod; 312. Inverted L-shaped bracket; 313. Rotating rod; 32. Elastic assembly; 321. Guide wheel; 322. Spring. Detailed Implementation
[0023] 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.
[0024] Please see Figure 1-5 As shown, this utility model is a feeding structure for a heavy-duty fully automatic high-speed edge banding machine, including a conveying assembly 111, and further including: a guide part 2, which is installed on the top of the conveying assembly 111; and an auxiliary part 3, which is installed on the guide part 2.
[0025] The guide section 2 includes a guide assembly 21, which is mounted on top of the conveying assembly 111; and a drive assembly 22, which is mounted on the guide assembly 21. The guide assembly 21 includes a support frame 211 fixedly connected to the top of the conveying assembly 111. Two cylindrical rods 212 are provided on both the front and rear sides of the support frame 211. The sides of the cylindrical rods 212 that are close to each other extend into the support frame 211, and the cylindrical rods 212 are slidably connected to the support frame 211. A fixing plate 213 is fixedly connected to the sides of the support frame 211 that are far apart from each other. Two guide plates 214 are provided inside the support frame 211. Guide plate 214 is fixedly connected to several cylindrical rods 212, and connecting members are provided between several fixed plates 213; one guide plate 214 is fixedly connected to two cylindrical rods 212, and the two guide plates 214 are located between several cylindrical rods 212; the connecting members include two cylindrical rods 215 fixedly connected to several fixed plates 213; one cylindrical rod 215 is fixedly connected to two fixed plates 213; the drive assembly 22 includes two support rods 221 fixedly connected to the top of the support frame 211; a hexagonal plate 222 is fixedly connected to the top of the two support rods 221; a motor 223 is fixedly connected to the top of the hexagonal plate 222; and two... A cross drive plate 224 is slidably connected to the outer wall of the support rod 221. The output shaft of the motor 223 is fixedly connected to a threaded rod 225 via a coupling. The side of the threaded rod 225 away from the motor 223 passes through the hexagonal plate 222 and extends outward. The threaded rod 225 is rotatably connected to the hexagonal plate 222. The bottom of the threaded rod 225 is rotatably connected to the support frame 211. The threaded rod 225 passes through the cross drive plate 224, and the cross drive plate 224 is threadedly connected to the threaded rod 225. A transmission component is provided on the support frame 211. The threaded rod 225 is located between the two support rods 221. The transmission component includes hinged rods fixedly connected to the front and rear sides of the support frame 211, respectively. 226, each of the two hinged rods 226 is hinged with a drive rod 227, and each of the two drive rods 227 has two slotted plates 228. The two upper slotted plates 228 are located on the cross drive plate 224, and the front and rear sides of the cross drive plate 224 are in contact with the two upper slotted plates 228 respectively. The two cylindrical rods 215 are in contact with the inner walls of the two lower slotted plates 228 respectively. By setting the guide part 2, the stable guiding effect can ensure the continuous feeding process, reduce production stoppage caused by material jamming, ensure that production efficiency is not affected, reduce the frequency and cost of equipment maintenance, and extend the service life of the equipment.
[0026] The auxiliary part 3 includes a support assembly 31, which is mounted on two guide plates 214; and an elastic assembly 32, which is mounted on the support assembly 31. The support assembly 31 includes a plurality of telescopic rods 311 fixedly connected to the sides of the two guide plates 214 that are close to each other. Each telescopic rod 311 has an inverted L-shaped bracket 312 fixedly connected to the side of each inverted L-shaped bracket 312 away from the two guide plates 214. A rotating rod 313 is rotatably connected to the inner top wall of each inverted L-shaped bracket 312. The telescopic rods 311 and the inverted L-shaped brackets 312 are arranged in a linear array, providing elasticity. Component 32 includes guide wheels 321 fixedly connected to the outer walls of several rotating rods 313, and springs 322 sleeved on the outer walls of several telescopic rods 311. The sides of several springs 322 that are close to each other are fixedly connected to several inverted L-shaped brackets 312, and the sides of several springs 322 that are far apart from each other are fixedly connected to two guide plates 214. The several springs 322 are arranged in a linear array. By setting the auxiliary part 3, the problems of jamming, friction and collision caused by material deviation are further reduced, manual intervention is reduced, the feeding is stable and continuous, and the production efficiency and product quality are improved.
[0027] It should be noted that the control of motor 223 in this application can be achieved by using a program set in the control panel and inputting relevant parameters as needed for automated control. This control method can be implemented using existing technologies, such as PLC.
[0028] A specific application of this embodiment is as follows: In use, the distance between the two guide plates 214 is adjusted according to the size of the material. The motor 223 is then started. The motor 223 drives the cross drive plate 224 to slide upwards on the two support rods 221 via the threaded rod 225. The parallel design of the two support rods 221 ensures smooth movement of the cross drive plate 224. The cross drive plate 224 then drives two drive rods 227 to rotate on the two hinge rods 226 via corresponding slotted plates 228. The two drive rods 227 then drive two cylindrical rods 215 closer together via the two slotted plates 228 located on the lower side. The two cylindrical rods 215 then drive several cylindrical rods 212 closer together via corresponding fixed plates 213, thereby driving the two guide plates 214... 4. By moving closer together and through the reverse operation process described above, the two guide plates 214 are moved further apart, thereby adjusting the distance between the two guide plates 214. When adjusting the two guide plates 214, the two guide plates 214 move through a number of corresponding telescopic rods 311 and a number of inverted L-shaped brackets 312, thereby driving a number of guide wheels 321 on a number of rotating rods 313 to move. After the adjustment is completed, the conveying assembly 111 is started to transport materials. Under the action of the rotating rods 313, the guide wheels 321 are rotated, reducing the friction on the materials. When the materials deviate, the guide wheels 321 will squeeze the telescopic rods 311 and the springs 322, causing the springs 322 to deform and generate elastic force. Under the action of the elastic force of the springs 322, the materials are reset, thereby conveying the materials.
[0029] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.
[0030] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A feeding structure for a heavy-duty fully automatic high-speed edge banding machine, comprising a conveying assembly (111), characterized in that, Also includes: Guide section (2), said guide section (2) is mounted on top of conveying assembly (111); Auxiliary part (3), said auxiliary part (3) is mounted on guide part (2); The guide section (2) includes a guide assembly (21) mounted on top of the conveying assembly (111); and A drive assembly (22) is mounted on a guide assembly (21); The guide assembly (21) includes a support frame (211) fixedly connected to the top of the conveying assembly (111). Two cylindrical rods (212) are provided on the front and rear sides of the support frame (211). The sides of several cylindrical rods (212) that are close to each other extend into the support frame (211). Several cylindrical rods (212) are slidably connected to the support frame (211). Fixed plates (213) are fixedly connected to the sides of several support frames (211) that are far apart from each other. Two guide plates (214) are provided inside the support frame (211). The two guide plates (214) are fixedly connected to several cylindrical rods (212). Connectors are provided between several fixed plates (213). One guide plate (214) is fixedly connected to two cylindrical rods (212), and the two guide plates (214) are located between several cylindrical rods (212).
2. The feeding structure of a heavy-duty fully automatic high-speed edge banding machine according to claim 1, characterized in that, The auxiliary part (3) includes a support assembly (31) mounted on two guide plates (214); and An elastic component (32) is mounted on a support component (31).
3. The feeding structure of a heavy-duty fully automatic high-speed edge banding machine according to claim 2, characterized in that, The drive assembly (22) includes two support rods (221) fixedly connected to the top of the support frame (211). A hexagonal plate (222) is fixedly connected to the top of the two support rods (221). A motor (223) is fixedly connected to the top of the hexagonal plate (222). A cross drive plate (224) is slidably connected to the outer wall of the two support rods (221). A threaded rod (225) is fixedly connected to the output shaft of the motor (223) through a coupling. The threaded rod (225) extends outward through the hexagonal plate (222) on the side away from the motor (223). The threaded rod (225) is rotatably connected to the hexagonal plate (222). The bottom of the threaded rod (225) is rotatably connected to the support frame (211). The threaded rod (225) extends through the cross drive plate (224). The cross drive plate (224) is threadedly connected to the threaded rod (225). A transmission component is provided on the support frame (211). Among them, the threaded rod (225) is located between the two support rods (221).
4. The feeding structure of a heavy-duty fully automatic high-speed edge banding machine according to claim 3, characterized in that, The support assembly (31) includes a plurality of telescopic rods (311) fixedly connected to the two guide plates (214) on the side close to each other. Each of the telescopic rods (311) is fixedly connected to an inverted L-shaped bracket (312) on the side away from the two guide plates (214). Each of the inverted L-shaped brackets (312) is rotatably connected to a rotating rod (313) on the top inner wall of the top. Among them, several telescopic rods (311) and inverted L-shaped brackets (312) are arranged in a linear array.
5. The feeding structure of a heavy-duty fully automatic high-speed edge banding machine according to claim 4, characterized in that, The elastic component (32) includes guide wheels (321) that are fixedly connected to the outer walls of a plurality of rotating rods (313), and springs (322) are sleeved on the outer walls of the plurality of telescopic rods (311). The sides of the plurality of springs (322) that are close to each other are fixedly connected to a plurality of inverted L-shaped brackets (312), and the sides of the plurality of springs (322) that are far apart from each other are fixedly connected to two guide plates (214). Among them, several springs (322) are arranged in a linear array.
6. The feeding structure of a heavy-duty fully automatic high-speed edge banding machine according to claim 5, characterized in that, The connector includes two cylindrical rods (215) that are fixedly connected to several fixed plates (213); One cylindrical rod (215) is fixedly connected to two fixed plates (213).
7. The feeding structure of a heavy-duty fully automatic high-speed edge banding machine according to claim 6, characterized in that, The transmission component includes hinge rods (226) that are fixedly connected to the front and rear sides of the support frame (211) respectively. Each of the two hinge rods (226) is hinged with a drive rod (227), and each of the two drive rods (227) has two slotted plates (228). Among them, the two upper slotted plates (228) are located on the cross drive plate (224), and the front and rear sides of the cross drive plate (224) are in contact with the two upper slotted plates (228) respectively. The two cylindrical rods (215) are in contact with the inner walls of the two lower slotted plates (228) respectively.