A deburring device for carbon fiber heating element production
By designing a deburring device with a support section, a rejection section, and a guide section, the problem of incomplete burr removal in the production of carbon fiber heating elements by traditional equipment has been solved, improving product quality and production efficiency, and ensuring the stability of welding and assembly.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANDONG KAIWEN COLLEGE OF SCI & TECH
- Filing Date
- 2025-06-16
- Publication Date
- 2026-06-19
AI Technical Summary
Traditional carbon fiber heating element production equipment struggles to effectively remove burrs during the shaping process, leading to decreased product quality and safety hazards. Furthermore, existing equipment is ill-suited for carbon fiber heating elements of different specifications, affecting subsequent welding and assembly.
A deburring device comprising a support section, a rejection section, and a guide section was designed. The guide section guides the carbon fiber heating element, and the rejection section removes burrs, ensuring the accuracy and stability of burr removal during the shaping process.
This improved the product quality of carbon fiber heating elements, ensured the stability of subsequent welding and assembly, avoided safety hazards caused by burrs, and improved production efficiency and product consistency.
Smart Images

Figure CN224374642U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of carbon fiber heating element production technology, and in particular relates to a deburring device for the production of carbon fiber heating elements. Background Technology
[0002] Traditional techniques struggle to effectively remove burrs during the shaping process of carbon fiber heating elements. These burrs not only affect the product's appearance but can also lead to decreased assembly precision and, during use, even cause safety hazards such as partial discharge and short circuits, severely restricting product quality and performance. Currently, traditional manual deburring methods are inefficient, labor-intensive, and have poor quality stability; while mechanical grinding improves efficiency, it easily damages the surface of the carbon fiber heating element. With the increasing market demand for carbon fiber heating elements and the rising quality requirements, there is a need for efficient, precise, and non-damaging deburring equipment to meet the needs of industrial production. Residual burrs can easily cause safety hazards such as short circuits and point discharges.
[0003] However, existing deburring equipment used in the production of carbon fiber heating elements is difficult to remove burrs from carbon fiber heating elements of different specifications while shaping them. The presence of burrs may lead to weak welding and improper assembly, affecting the subsequent processing. Utility Model Content
[0004] The purpose of this utility model is to provide a deburring device for the production of carbon fiber heating elements. By setting up a rejection section, it solves the problem that existing deburring devices for the production of carbon fiber heating elements are difficult to remove burrs while shaping carbon fiber heating elements of different specifications. The presence of burrs may lead to weak welding and improper assembly, affecting the subsequent processing.
[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 deburring device for the production of carbon fiber heating elements, comprising a processing box, and further comprising: a support part disposed at the bottom of the processing box, wherein the carbon fiber heating element is disposed on the processing box; a rejection part mounted on the processing box for removing burrs from the carbon fiber heating element; and a guide part disposed on the processing box for limiting the carbon fiber heating element; wherein the support part supports the rejection part and the guide part, and when removing burrs from the carbon fiber heating element, the guide part is activated first to guide the carbon fiber heating element, and then the rejection part is activated to complete the burr removal work.
[0007] Furthermore, the support includes several fixed plates fixedly connected to the top of the processing box, a base plate fixedly connected to the front side of the processing box, a limit plate fixedly connected to the right side of the fixed plate on the right side, a motor fixedly connected to the right side of the limit plate, a rotating shaft provided on the processing box, the output shaft of the motor fixedly connected to the rotating shaft through a coupling, and a fixed block fixedly connected to the left side of the rotating shaft; wherein, the rotating shaft passes through the fixed plate on the right side, the outer wall of the rotating shaft is rotatably connected to the fixed plate, the rotating shaft passes through the limit plate, the outer wall of the rotating shaft is rotatably connected to the limit plate, and the carbon fiber heating element is placed inside the fixed block.
[0008] Furthermore, the rejection section includes a fixing component disposed on the processing box; and a removal component mounted on the fixing component; wherein the fixing component is used to fix the carbon fiber heating element, and the removal component is used to remove burrs from the carbon fiber heating element.
[0009] Furthermore, the guide portion includes a transmission assembly disposed on the processing box; and a limiting assembly mounted on the transmission assembly; wherein the transmission assembly provides a moving force to the limiting assembly, and the limiting assembly is used to provide a limiting direction.
[0010] Furthermore, the fixing assembly includes several brackets mounted on the processing box, each bracket being fixedly connected to a fixing plate located at the rear. The processing box has several connecting blocks, each connecting block being fixedly connected to a fixing plate. The processing box has two long rods that pass through several connecting blocks. Connecting rods are fixedly connected between each connecting block. The processing box has a second straight connecting rod that passes through several brackets. The processing box also has several connecting components. The fixing assembly connects the removal assembly and the fixing plate, and the connecting rods support the carbon fiber heating element.
[0011] Furthermore, the removal assembly includes a cylinder fixedly connected to the top of the base plate, the output shaft of the cylinder being fixedly connected to a straight connecting rod, two hinge blocks being provided on the processing box, the straight connecting rod passing through the two hinge blocks, and a pressing member being provided on the processing box; wherein, the straight connecting rod passes through the two hinge blocks, both hinge blocks are rotatably connected to the outer wall of the straight connecting rod, and the straight connecting rod is hinged to the two hinge blocks.
[0012] Furthermore, the transmission assembly includes a processing block fixedly connected to the top of the processing box, an electric telescopic rod fixedly connected to the processing block, and a transmission component provided on the electric telescopic rod; wherein, the processing block is used to support the electric telescopic rod, and the electric telescopic rod provides power to the transmission component.
[0013] Furthermore, the limiting component includes a guide block fixedly connected to the inner wall of the bottom of the processing block, a bidirectional threaded rod is provided inside the processing block, and two guide plates are provided inside the processing block, with the bidirectional threaded rod passing through the two guide plates; wherein, the bidirectional threaded rod passes through the processing block, both guide plates are slidably engaged with the guide block, and both guide plates are threadedly connected to the bidirectional threaded rod.
[0014] Furthermore, the connecting component includes several positioning rollers disposed on the processing box, with the two long rods passing through the several positioning rollers respectively; the pressing component includes a connecting rod disposed on the processing box, with several cleaning rollers fixedly connected to the connecting rod, and hinge blocks two are hingedly disposed on the two supports located on the left and right sides respectively; several springs are disposed on the processing box, with the side of the two hinge blocks two near the connecting rod respectively fixedly connected to two springs, and the side of the two hinge blocks one near the connecting rod respectively fixedly connected to two springs; wherein, the straight connecting rod two passes through the two hinge blocks two, and the side of the two hinge blocks two near the connecting rod is fixedly connected to the connecting rod.
[0015] Furthermore, the transmission component includes a rack slidably connected to the processing block, and a gear is provided on the front side of the processing block; wherein, the output shaft of the electric telescopic rod is fixedly connected to the rack, the rack meshes with the gear, and the rack is fixedly connected to the outer wall of the bidirectional threaded rod.
[0016] This utility model has the following beneficial effects:
[0017] 1. By setting up a rejection section, when in use, the cylinder is activated, which drives the first connecting rod to move upward. The first and second hinge blocks cooperate with each other. Under the action of the first connecting rod, the connecting rod and the cleaning roller move around the second connecting rod towards the positioning roller until the cleaning roller contacts the surface of the carbon fiber heating element. This causes the carbon fiber heating element to rotate on the connecting rod, thus completing the removal of burrs from the carbon fiber heating element. When the carbon fiber heating element rotates, the spring provides shock absorption and buffering for the cleaning roller, so that the cleaning roller can make stable contact with the carbon fiber heating element. When removing burrs from the carbon fiber heating element, the adjustment between the rollers provides a more accurate punching pressure. The carbon fiber heating element shaping tube can remove surface burrs while being punched by rollers, which improves the product quality of the carbon fiber heating element and provides a strong technical guarantee for the subsequent welding and assembly of the carbon fiber heating element.
[0018] 2. By setting a guide section, the carbon fiber heating element is placed in the fixed block. The electric telescopic rod is then activated, causing the rack to move. The rack and gear work together to rotate the bidirectional threaded rod. As the bidirectional threaded rod rotates, it causes two guide plates to move closer together along the guide block until they contact the carbon fiber heating element. The motor is then activated, causing the rotating shaft to rotate and the fixed block to rotate. This guide section guides the carbon fiber heating element during burr removal, preventing significant displacement during stamping and adjustment, which could lead to uneven stress on the heating element and improve the product quality.
[0019] 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
[0020] 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.
[0021] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0022] Figure 2 This is a cross-sectional view of the overall structure of the fixing block of this utility model;
[0023] Figure 3 This is a schematic diagram of the overall structure of the fixing component of this utility model;
[0024] Figure 4 This is a partial cross-sectional view of the removal component of this utility model;
[0025] Figure 5 This is a partial cross-sectional view of the cleaning roller of this utility model;
[0026] Figure 6 This is a cross-sectional schematic diagram of the overall structure of the transmission component of this utility model;
[0027] Figure 7 This is a partial cross-sectional view of the limiting component of this utility model.
[0028] The attached diagram lists the components represented by each number as follows:
[0029] 1. Support unit; 111. Processing box; 112. Fixing plate; 113. Base plate; 114. Limiting plate; 115. Motor; 116. Rotating shaft; 117. Fixing block; 2. Removal unit; 21. Fixing assembly; 211. Bracket; 212. Connecting block; 213. Long rod; 214. Connecting rod; 215. Straight connecting rod two; 216. Positioning roller; 22. Removal assembly; 221. Cylinder; 222. Straight connecting rod one; 223. Hinge block one; 224. Connecting rod; 225. Cleaning roller; 226. Hinge block two; 227. Spring; 3. Guide unit; 31. Transmission assembly; 311. Processing block; 312. Electric telescopic rod; 313. Rack; 314. Gear; 32. Limiting assembly; 321. Guide block; 322. Bidirectional threaded rod; 323. Guide plate. Detailed Implementation
[0030] 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.
[0031] Please see Figure 1-7 As shown, this utility model is a deburring device for producing carbon fiber heating elements, including a processing box 111 and a support part 1. The support part 1 is disposed at the bottom of the processing box 111, and the carbon fiber heating element is disposed on the processing box 111. The support part 1 includes several fixing plates 112 fixedly connected to the top of the processing box 111. A bottom plate 113 is fixedly connected to the front side of the processing box 111. A limiting plate 114 is fixedly connected to the right side of the fixing plate 112 on the right side. A motor 115 is fixedly connected to the right side of the limiting plate 114. A rotating shaft 116 is disposed on the processing box 111, and the output shaft of the motor 115 is connected via a coupling. The shaft is fixedly connected to the rotating shaft 116, and a fixing block 117 is fixedly connected to the left side of the rotating shaft 116. The rotating shaft 116 passes through the fixing plate 112 located on the right side, and the outer wall of the rotating shaft 116 is rotatably connected to the fixing plate 112. The rotating shaft 116 passes through the limiting plate 114, and the outer wall of the rotating shaft 116 is rotatably connected to the limiting plate 114. The carbon fiber heating element is placed inside the fixing block 117. The support part 1 is used to support the removal part 2 and the guide part 3. When removing burrs from the carbon fiber heating element, the guide part 3 is activated first to guide the carbon fiber heating element, and then the removal part 2 is activated to complete the burr removal work.
[0032] The removal unit 2 is mounted on the processing box 111 and is used to remove burrs from the carbon fiber heating element. The removal unit 2 includes a fixing component 21 mounted on the processing box 111 and a removal component 22 mounted on the fixing component 21. The fixing component 21 is used to fix the carbon fiber heating element, and the removal component 22 is used to remove burrs from the carbon fiber heating element. The fixing component 21 includes several brackets 211 mounted on the processing box 111, each bracket 211 being fixedly connected to a fixing plate 112 located at the rear. The processing box 111 is provided with several connecting blocks 212, each connecting block 212 being fixedly connected to several fixing plates 112. The processing box 111 is equipped with two long rods 213, each of which passes through several connecting blocks 212. Connecting rods 214 are fixedly connected between the connecting blocks 212. A second straight connecting rod 215 is provided on the processing box 111, passing through several supports 211. Several connecting parts are provided on the processing box 111. The fixing assembly 21 connects the removal assembly 22 and the fixing plate 112. The connecting rods 214 support the carbon fiber heating element. The removal assembly 22 includes a cylinder 221 fixedly connected to the top of the base plate 113. The output shaft of the cylinder 221 is fixedly connected to a first straight connecting rod 222. Two hinge blocks 223 are provided on the processing box 111, with the first straight connecting rod 222 passing through both. The processing box 111 is equipped with a pressing component and a hinge block 223. A straight connecting rod 215 passes through both hinge blocks 223, and both hinge blocks 223 are rotatably connected to the outer wall of the straight connecting rod 215. A straight connecting rod 222 is hinged to both hinge blocks 223. The connecting component includes several positioning rollers 216 mounted on the processing box 111, and two long rods 213 pass through the positioning rollers 216 respectively. The pressing component includes a connecting rod 224 mounted on the processing box 111, with several cleaning rollers 225 fixedly connected to the connecting rod 224. Two hinge blocks 226 are hinged to the two supports 211 located on the left and right sides. Several springs 227 are mounted on the processing box 111. The second connecting block 226 is fixedly connected to two springs 227 on the side near the connecting rod 224, and the two first hinge blocks 223 are fixedly connected to two springs 227 on the side near the connecting rod 224. The second straight connecting rod 215 passes through the two second hinge blocks 226, and the two second hinge blocks 226 are fixedly connected to the connecting rod 224 on the side near the connecting rod 224. By setting the removal part 2, when removing burrs from the carbon fiber heating element, a more accurate stamping pressure is provided by adjusting the rollers. The carbon fiber heating element shaping tube can remove surface burrs while being stamped by rollers, which improves the product quality of the carbon fiber heating element and provides a strong technical guarantee for the subsequent welding and assembly of the carbon fiber heating element.
[0033] A guide section 3 is mounted on the processing box 111 and is used to limit the carbon fiber heating element. The guide section 3 includes a transmission assembly 31 mounted on the processing box 111 and a limiting assembly 32 mounted on the transmission assembly 31. The transmission assembly 31 provides the motion force to the limiting assembly 32, and the limiting assembly 32 provides the limiting direction. The transmission assembly 31 includes a processing block 311 fixedly connected to the top of the processing box 111. An electric telescopic rod 312 is fixedly connected to the processing block 311, and a transmission component is provided on the electric telescopic rod 312. The processing block 311 supports the electric telescopic rod 312, and the electric telescopic rod 312 provides power to the transmission component. The limiting assembly 32 includes a guide block 321 fixedly connected to the inner wall of the bottom of the processing block 311. A bidirectional threaded rod 322 is provided inside the processing block 311. There are two guide plates 323, and a bidirectional threaded rod 322 passes through the two guide plates 323. The bidirectional threaded rod 322 passes through the processing block 311. Both guide plates 323 are slidably engaged with the guide block 321, and both guide plates 323 are threadedly connected to the bidirectional threaded rod 322. The transmission component includes a rack 313 slidably connected to the processing block 311, and a gear 314 is provided on the front side of the processing block 311. The output shaft of the electric telescopic rod 312 is fixedly connected to the rack 313, the rack 313 meshes with the gear 314, and the rack 313 is fixedly connected to the outer wall of the bidirectional threaded rod 322. By setting the guide part 3, the carbon fiber heating element is guided during the removal of burrs, avoiding large displacement of the carbon fiber heating element during stamping adjustment, which would lead to uneven force on the carbon fiber heating element and improve the product quality of the carbon fiber heating element.
[0034] A specific application of this embodiment is as follows: During use, cylinder 221 is activated, causing the first connecting rod 222 to move upwards. Hinged block 223 and hinged block 226 cooperate with each other. Under the action of the first connecting rod 222, the connecting rod 224 and the cleaning roller 225 move around the second connecting rod 215 towards the positioning roller 216 until the cleaning roller 225 contacts the surface of the carbon fiber heating element. At this point, the carbon fiber heating element is placed in the fixing block 117. The electric telescopic rod 312 is activated, causing the rack 313 to move. The rack 313 and gear 31... 4. The two guide plates 323 move closer to each other along the guide block 321 when they rotate, until they come into contact with the carbon fiber heating element. Then the motor 115 is started. The motor 115 drives the rotating shaft 116 to rotate, which in turn drives the fixed block 117 to rotate, so that the carbon fiber heating element rotates on the connecting rod 214, thus completing the removal of burrs from the carbon fiber heating element. When the carbon fiber heating element rotates, the spring 227 dampens and buffers the cleaning roller 225, so that the cleaning roller 225 can make stable contact with the carbon fiber heating element.
[0035] 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.
[0036] 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 deburring apparatus for producing a carbon fiber heating element, comprising a processing box (111), characterized in that, Also includes: Support part (1), the support part (1) is disposed at the bottom of the processing box (111), and a carbon fiber heating element is disposed on the processing box (111); The removal section (2), mounted on the processing box (111), is used to remove burrs from the carbon fiber heating element; and The guide part (3) is provided on the processing box (111) and is used to limit the carbon fiber heating element; Among them, the support part (1) is used to support the removal part (2) and the guide part (3). When removing burrs from the carbon fiber heating element, the guide part (3) is started first to guide the carbon fiber heating element, and then the removal part (2) is started to complete the burr removal work.
2. The burring apparatus for producing a carbon fiber heating element according to claim 1, characterized by The support part (1) includes several fixed plates (112) fixedly connected to the top of the processing box (111). A bottom plate (113) is fixedly connected to the front side of the processing box (111). A limit plate (114) is fixedly connected to the right side of the fixed plate (112) located on the right side. A motor (115) is fixedly connected to the right side of the limit plate (114). A rotating shaft (116) is provided on the processing box (111). The output shaft of the motor (115) is fixedly connected to the rotating shaft (116) through a coupling. A fixing block (117) is fixedly connected to the left side of the rotating shaft (116). Among them, the rotating shaft (116) passes through the fixed plate (112) located on the right side, the outer wall of the rotating shaft (116) is rotatably connected to the fixed plate (112), the rotating shaft (116) passes through the limiting plate (114), the outer wall of the rotating shaft (116) is rotatably connected to the limiting plate (114), and the carbon fiber heating element is placed in the fixed block (117).
3. The burring apparatus for producing a carbon fiber heating element according to claim 2, characterized by The rejection section (2) includes a fixing component (21) disposed on the processing box (111); and Remove component (22), which is mounted on fixed component (21); The fixing component (21) is used to fix the carbon fiber heating element, and the removal component (22) is used to remove burrs from the carbon fiber heating element.
4. The deburring equipment for producing carbon fiber heating elements according to claim 3, characterized in that, The guide section (3) includes a transmission assembly (31) disposed on the processing box (111); and A limiting component (32) is mounted on the transmission component (31); The transmission component (31) provides motion force to the limiting component (32), and the limiting component (32) is used to provide the limiting direction.
5. The deburring equipment for producing carbon fiber heating elements according to claim 4, characterized in that, The fixing component (21) includes several brackets (211) set on the processing box (111), the several brackets (211) being fixedly connected to the fixing plate (112) located on the rear side, the processing box (111) being provided with several connecting blocks (212), the several connecting blocks (212) being fixedly connected to several fixing plates (112), the processing box (111) being provided with two long rods (213), the two long rods (213) passing through several connecting blocks (212), the several connecting blocks (212) being fixedly connected with connecting rods (214), the processing box (111) being provided with a second straight connecting rod (215), the second straight connecting rod (215) passing through several brackets (211), and the processing box (111) being provided with several connectors; The fixing component (21) is used to connect the removal component (22) and the fixing plate (112), and the connecting rod (214) is used to support the carbon fiber heating element.
6. The burring apparatus for producing a carbon fiber heating element according to claim 5, characterized by The removal assembly (22) includes a cylinder (221) fixedly connected to the top of the base plate (113). The output shaft of the cylinder (221) is fixedly connected to a straight connecting rod (222). The processing box (111) is provided with two hinge blocks (223). The straight connecting rod (222) passes through the two hinge blocks (223). The processing box (111) is provided with a pressing component. Among them, the second straight connecting rod (215) passes through the two hinge blocks (223), and the two hinge blocks (223) are rotatably connected to the outer wall of the second straight connecting rod (215). The first straight connecting rod (222) is hinged to the two hinge blocks (223).
7. The deburring apparatus for a carbon fiber heating element production according to claim 6, characterized by, The transmission assembly (31) includes a processing block (311) fixedly connected to the top of the processing box (111), an electric telescopic rod (312) fixedly connected to the processing block (311), and a transmission component provided on the electric telescopic rod (312). The processing block (311) is used to support the electric telescopic rod (312), which provides power to the transmission component.
8. The burring apparatus for producing a carbon fiber heating element according to claim 7, characterized by The limiting component (32) includes a guide block (321) fixedly connected to the bottom inner wall of the processing block (311), a bidirectional threaded rod (322) is provided in the processing block (311), and two guide plates (323) are provided in the processing block (311), with the bidirectional threaded rod (322) passing through the two guide plates (323). Among them, the bidirectional threaded rod (322) passes through the treatment block (311), and the two guide plates (323) are slidably engaged with the guide block (321). The two guide plates (323) are threadedly connected to the bidirectional threaded rod (322).
9. The deburring apparatus for a carbon fiber heating element production according to claim 8, characterized by, The connector includes a plurality of positioning rollers (216) disposed on the processing box (111), and the two long rods (213) respectively pass through the plurality of positioning rollers (216). The pressing component includes a connecting rod (224) disposed on the processing box (111), a plurality of cleaning rollers (225) are fixedly connected to the connecting rod (224), and two hinge blocks (226) are hingedly disposed on the left and right sides of the two brackets (211). A plurality of springs (227) are disposed on the processing box (111). The two hinge blocks (226) are fixedly connected to the two springs (227) on the side near the connecting rod (224) respectively, and the two hinge blocks (223) are fixedly connected to the two springs (227) on the side near the connecting rod (224) respectively. Among them, the straight connecting rod 2 (215) passes through the two hinge blocks 2 (226), and the two hinge blocks 2 (226) are fixedly connected to the connecting rod (224) on the side near the connecting rod (224).
10. The burring apparatus for producing a carbon fiber heating element according to claim 9, wherein The transmission component includes a rack (313) slidably connected to the processing block (311), and a gear (314) is provided on the front side of the processing block (311). Among them, the output shaft of the electric telescopic rod (312) is fixedly connected to the rack (313), the rack (313) meshes with the gear (314), and the rack (313) is fixedly connected to the outer wall of the bidirectional threaded rod (322).