A kind of die cutting indentation integrated machine anti-deviation alignment mechanism
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FOSHAN HENGCHANG HAODA SAFETY PRINTING CO LTD
- Filing Date
- 2025-08-12
- Publication Date
- 2026-06-26
Smart Images

Figure CN224407780U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of indentation processing technology, and in particular relates to an anti-offset alignment mechanism for an integrated die-cutting and indentation machine. Background Technology
[0002] In the prior art, a search revealed a Chinese patent that discloses "a positioning mechanism for an embossing machine", with publication number "CN214873102U". This patent mainly includes a worktable, with a material rack for placing business cards set on the upper surface of the worktable near the right end, and a pushing mechanism for pushing business cards set on the right end of the material rack. A fixing frame fixed to the worktable is set on the left side of the material rack, and a first pneumatic rod is fixed at the upper end of the fixing frame. The top rod of the first pneumatic rod passes through the top of the fixing frame and is fixedly connected to an embossing plate for embossing business cards.
[0003] Currently, the integrated die-cutting and creasing machine has obvious shortcomings in actual use. Its alignment mechanism has a narrow range of adaptability. When faced with diversified production tasks, it is not easy to meet the processing requirements of different specifications, which leads to a reduction in the versatility and flexibility of the device. Utility Model Content
[0004] The purpose of this utility model is to provide an anti-offset alignment mechanism for an integrated die-cutting and creasing machine. By setting an alignment part, the problem of its narrow adaptation range and inconvenience in meeting the processing requirements of different specifications when facing diverse production tasks is solved, which leads to a reduction in the versatility and flexibility of the device.
[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0006] This utility model relates to an anti-offset alignment mechanism for an integrated die-cutting and creasing machine, comprising a machine body, and further comprising: an alignment part disposed on the machine body; and a processing part disposed on the machine body. The alignment part includes an alignment assembly mounted on the machine body. The alignment assembly includes L-shaped plates fixedly connected to both sides of the machine body. Two slide rods are fixedly connected to the side of the two L-shaped plates that are close to each other. Two sliding plates are slidably connected to the outer walls of the two slide rods. Alignment clamps are fixedly connected to the bottom of each of the two sliding plates. Racks are fixedly connected to the top of each of the two sliding plates. Slide rails are fixedly connected to the bottom of each of the two racks. The two racks and their slide rails are respectively mounted on the top of the two sliding plates and are staggered.
[0007] Furthermore, a driving assembly is mounted on the alignment assembly; wherein the driving assembly is mounted on top of the alignment assembly, the driving assembly includes a fixing plate sleeved on the outer wall of two slide rods, the fixing plate having two slide rail grooves, both slide rails extending outside the two slide rail grooves and slidably connected to the two slide rail grooves, a motor is provided on the fixing plate, the output shaft of the motor is fixedly connected to a rotating shaft through a coupling, and a gear is sleeved on the outer wall of the rotating shaft; wherein, two upper indentation dies drive gears to be staggered and mesh with gears.
[0008] Furthermore, the processing unit includes an indentation assembly, which is mounted on the machine body. The indentation assembly includes a second motor fixedly connected to the right side of the machine body. The output shaft of the second motor is fixedly connected to a first rotating rod via a coupling. The outer wall of the first rotating rod is fitted with several lower indentation molds. A second rotating rod is rotatably connected to the machine body, with both ends of the second rotating rod extending outside the machine body. The outer wall of the second rotating rod is fitted with several upper indentation molds, each of which is adapted to the several lower indentation molds. The left outer wall of both the first and second rotating rods is fitted with a second gear, which meshes with each other. The first rotating rod penetrates the machine body and is rotatably connected to it.
[0009] Furthermore, a vertical cutting assembly is mounted on the machine body. The vertical cutting assembly includes a rotating rod three rotatably connected to the machine body, with both ends of the rotating rod three extending outside the machine body. A plurality of lower vertical cutting blades are fitted onto the outer wall of the rotating rod three. A rotating rod four is rotatably connected to the machine body, with both ends of the rotating rod four extending outside the machine body. A plurality of upper vertical cutting blades are fitted onto the outer wall of the rotating rod four, and each of the upper vertical cutting blades is adapted to a plurality of lower vertical cutting blades. A transmission component is provided on the rotating rod four. There are three pairs of upper and lower vertical cutting blades, which are equally divided into eight pairs of indentation components. The transmission component includes gear three, each fitted onto the outer wall of the rotating rod four and rotating rod two. Two of the gear three have toothed belts wound around their outer walls. Both gear three are fitted onto the right outer wall of the rotating rod four and rotating rod two.
[0010] Furthermore, a cross-cutting assembly is installed on the machine body; wherein, eight pairs of indentation assemblies are provided, with four pairs symmetrically distributed on each side, and the cross-cutting assembly includes a hydraulic push rod fixedly connected to the top of the machine body, the output end of the hydraulic push rod extending outside the machine body and slidably connected to the machine body, a flat die cutter fixedly connected to the output end of the hydraulic push rod, and two balance bars fixedly connected to the top of the flat die cutter; wherein, the top ends of both balance bars extend outside the machine body and are slidably connected to the machine body.
[0011] This utility model has the following beneficial effects:
[0012] 1. By setting up an alignment section, when in use, the cardboard to be processed is first placed on the worktable of the machine body, and then the first motor is started. The first motor will drive the first gear to rotate through the rotating shaft. Since the first gear is meshed with the two racks, when the first gear rotates, the two racks can drive their upper slide plates to slide closer to each other on the outer wall of the two slide rods. The alignment clamps on the slide plates also move closer to each other and position the cardboard on the machine body. During the positioning process, the guide rollers on the two alignment clamps can effectively reduce the friction generated when the cardboard moves, and avoid scratches or displacement on the cardboard surface. At the same time, when the two racks slide, the slide rails installed on them will slide synchronously in the slide rail grooves of the fixed plate. The cooperation between the slide rails and the slide rail grooves can enhance the stability of the racks when sliding. Through this design, the device can adapt to the processing needs of cardboard of different specifications, significantly improving the versatility and operational flexibility of the equipment.
[0013] 2. After positioning is completed by setting up the processing section, the cardboard will enter the processing section for subsequent processing. At this time, motor two is started, which will drive the rotating rod one to rotate. During the rotation of rotating rod one, gear two installed on it meshes with gear two on rotating rod two. Utilizing the characteristics of gear transmission, rotating rod one and rotating rod two can synchronously drive the lower and upper creasing dies installed on their surfaces to rotate relative to each other. While realizing the cardboard conveying, it can also perform equidistant creasing processing on the cardboard. At the same time, during the rotation of rotating rod two... The gear three installed on it will also be connected to the gear three on the rotating rod four through the toothed belt, so that the rotating rod four and the rotating rod two will rotate synchronously. When the rotating rod four rotates, the multiple upper vertical cutters distributed on it will mesh with the multiple lower vertical cutters on the rotating rod three to cut the cardboard vertically at equal intervals. After the cardboard has completed the creasing and vertical cutting process, it will move to the flat die position. At this time, the hydraulic push rod is activated. With the assistance of the two balance rods, the hydraulic push rod enables the flat die to complete the die cutting through the vertical pressure of the plane.
[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 alignment portion of this utility model;
[0018] Figure 3 This is a partial cross-sectional view of the processing part of this utility model;
[0019] Figure 4 This utility model Figure 2 A magnified structural diagram of A in the middle;
[0020] Figure 5 This utility model Figure 3 A magnified structural diagram of B in the diagram.
[0021] The attached diagram lists the components represented by each number as follows:
[0022] 1. Body; 2. Alignment section; 21. Alignment assembly; 211. L-shaped plate; 212. Slide rod; 213. Slide plate; 214. Alignment fixture; 215. Rack; 216. Slide rail; 22. Drive assembly; 221. Fixing plate; 222. Slide rail groove; 223. Motor 1; 224. Rotating shaft; 225. Gear 1; 3. Machining section; 31. Indentation assembly; 311. Motor 2; 3 12. Rotating rod one; 313. Lower indentation die; 314. Rotating rod two; 315. Upper indentation die; 316. Gear two; 32. Vertical cutting assembly; 321. Rotating rod three; 322. Lower vertical cutter; 323. Rotating rod four; 324. Upper vertical cutter; 325. Gear three; 326. Toothed belt; 33. Cross-cutting assembly; 331. Hydraulic push rod; 332. Flat die cutter; 333. Balance bar. 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 an anti-offset alignment mechanism for an integrated die-cutting and creasing machine, including a machine body 1, and further including: an alignment part 2, which is disposed on the machine body 1; and a processing part 3, which is disposed on the machine body 1.
[0025] The alignment section 2 includes an alignment assembly 21 mounted on the body 1; and a drive assembly 22 mounted on the alignment assembly 21. The drive assembly 22 is mounted on top of the alignment assembly 21. The alignment assembly 21 includes L-shaped plates 211 fixedly connected to both sides of the body 1. Two slide rods 212 are fixedly connected to the side of the two L-shaped plates 211 that are close to each other. Two sliding plates 213 are slidably connected to the outer walls of the two slide rods 212. Alignment clamps 214 are fixedly connected to the bottom of each sliding plate 213, and racks 215 are fixedly connected to the top of each sliding plate 213. The bottom of each of the two racks 215 is fixedly connected to a slide rail 216; the two racks 215 and their slide rails 216 are respectively mounted on the top of the two slide plates 213 and are staggered. The drive assembly 22 includes a fixing plate 221 sleeved on the outer wall of the two slide rods 212. The fixing plate 221 has two slide rail grooves 222. The two slide rails 216 extend outside the two slide rail grooves 222 and are slidably connected to the two slide rail grooves 222. A motor 223 is provided on the fixing plate 221. The output shaft of the motor 223 is fixedly connected to a rotating shaft 224 through a coupling. The outer wall of the rotating shaft 224 A gear 225 is fitted in place; two upper embossing dies 315 drive gears 316 in a staggered arrangement, meshing with gear 225. By setting an alignment part 2, in use, the cardboard to be processed is first placed on the worktable of the machine body 1, then motor 223 is started. Motor 223 drives gear 225 to rotate via shaft 224. Since gear 225 meshes with two racks 215, when gear 225 rotates, the two racks 215 can respectively drive their upper slide plates 213 to slide closer to each other on the outer walls of the two slide rods 212. The alignment clamps 214 also move closer to each other and position the cardboard on the machine body 1. During the positioning process, the guide rollers on the two alignment clamps 214 can effectively reduce the friction generated when the cardboard moves, and avoid scratches or displacement on the cardboard surface. At the same time, when the two racks 215 slide, the slide rails 216 installed on them will slide synchronously in the slide rail grooves 222 of the fixed plate 221. The cooperation between the slide rails and the slide rail grooves can enhance the stability of the racks 215 when sliding. Through this design, the device can adapt to the processing needs of cardboard of different specifications, and significantly improve the versatility and operational flexibility of the equipment.
[0026] Processing unit 3 includes an indentation assembly 31 mounted on the machine body 1; a vertical cutting assembly 32 mounted on the machine body 1; and a horizontal cutting assembly 33 mounted on the machine body 1. The indentation assembly 31 comprises eight pairs, symmetrically distributed with four pairs on each side. Each indentation assembly 31 includes a second motor 311 fixedly connected to the right side of the machine body 1. The output shaft of the second motor 311 is fixedly connected to a first rotating rod 312 via a coupling. The outer wall of the first rotating rod 312 is fitted with several lower indentation dies 313. A rotating rod 314 is rotatably connected to the upper part of the machine body 1. Both ends of the rotating rod 314 extend outside the machine body 1. Several upper indentation molds 315 are fitted on the outer wall of the rotating rod 314. The several upper indentation molds 315 are adapted to several lower indentation molds 313. Gears 316 are fitted on the outer wall of the left end of both the rotating rod 312 and the rotating rod 314. The two gears 316 mesh with each other. The rotating rod 312 passes through the machine body 1 and is rotatably connected to the machine body 1. The vertical cutting assembly 32 includes a rotating rod 321 rotatably connected to the machine body 1. Both ends of 21 extend outside the machine body 1. Several lower vertical cutters 322 are fitted on the outer wall of the rotating rod 321. A rotating rod 4 323 is rotatably connected to the machine body 1. Both ends of the rotating rod 4 323 extend outside the machine body 1. Several upper vertical cutters 324 are fitted on the outer wall of the rotating rod 4 323. Each upper vertical cutter 324 is adapted to a number of lower vertical cutters 322. A transmission component is provided on the rotating rod 4 323. There are three pairs of upper vertical cutters 324 and lower vertical cutters 322, equally dividing eight pairs of indentation assemblies 31. The transverse cutting assembly 33 includes a fixed... A hydraulic push rod 331 is connected to the top of the machine body 1. The output end of the hydraulic push rod 331 extends to the outside of the machine body 1 and is slidably connected to the machine body 1. A flat die 332 is fixedly connected to the output end of the hydraulic push rod 331. Two balance bars 333 are fixedly connected to the top of the flat die 332. The top ends of the two balance bars 333 extend to the outside of the machine body 1 and are slidably connected to the machine body 1. The transmission components include gears 325 that are sleeved on the outer walls of the four rotating rods 323 and the two rotating rods 314. Toothed belts 326 are wound around the outer walls of the two gears 325.Two gears 325 are fitted onto the right outer wall of rotating rod 323 and rotating rod 314. After positioning is completed by the processing section 3, the cardboard will enter the processing section 3 for subsequent processing. At this time, motor 2 311 is started, which will drive rotating rod 1 312 to start rotating. During the rotation of rotating rod 1 312, gear 2 316 installed on it meshes with gear 2 316 on rotating rod 2 314. Utilizing the characteristics of gear transmission, rotating rod 1 312 and rotating rod 2 314 can synchronously drive the lower creasing mold 313 and upper creasing mold 315 installed on their surfaces to rotate relative to each other. While realizing the cardboard conveying, it can also perform equidistant creasing on the cardboard. During the rotation of rotating rod 2 314, the gear 325 mounted on it is also connected to the gear 325 on rotating rod 4 323 via toothed belt 326, thus ensuring that rotating rod 4 323 rotates synchronously with rotating rod 2 314. When rotating rod 4 323 rotates, the multiple upper vertical cutters 324 distributed on it mesh with the multiple lower vertical cutters 322 on rotating rod 3 321, performing vertical equidistant cuts on the cardboard. After the cardboard has completed the creasing and vertical cutting processes, it moves to the position of flat die-cutting knife 332. At this time, the hydraulic push rod 331 is activated. With the assistance of two balance rods 333, the hydraulic push rod 331 enables the flat die-cutting knife 332 to complete the die-cutting through the vertical pressure of the plane.
[0027] A specific application of this embodiment is as follows: In use, the cardboard to be processed is first placed on the worktable of the machine body 1, and then the motor 223 is started. The motor 223 drives the gear 225 to rotate through the rotating shaft 224. Since the gear 225 meshes with the two racks 215, when the gear 225 rotates, the two racks 215 can drive their upper slide plates 213 to slide closer to each other on the outer wall of the two slide rods 212. The alignment clamps 214 on the slide plates 213 also move closer to each other and position the cardboard on the machine body 1. During the positioning process, the two alignment clamps... The guide rollers on rack 214 effectively reduce the friction generated during cardboard movement, preventing scratches or displacement on the cardboard surface. Simultaneously, as the two racks 215 slide, the slide rails 216 mounted on them slide synchronously within the slide rail grooves 222 of the fixed plate 221. The cooperation between the slide rails and the slide rail grooves enhances the stability of the racks 215 during sliding. Through this design, the device can adapt to the processing needs of cardboard of different specifications, significantly improving the versatility and operational flexibility of the equipment. After positioning, the cardboard enters the processing section 3 for further processing. At this time, motor 31 is started. 1. Motor 2 311 drives rotating rod 1 312 to start rotating. During the rotation of rotating rod 1 312, gear 2 316 mounted on it meshes with gear 2 316 on rotating rod 2 314. Utilizing the characteristics of gear transmission, rotating rod 1 312 and rotating rod 2 314 can synchronously drive the lower creasing die 313 and upper creasing die 315 mounted on their surfaces to rotate relative to each other. This achieves both paperboard conveying and equidistant creasing of the paperboard. Simultaneously, during the rotation of rotating rod 2 314, gear 3 325 mounted on it will also interact with rotating rod 4 3 via toothed belt 326. The gear 325 on 23 is connected to the drive, so that the rotating rod 323 and the rotating rod 314 rotate synchronously. When the rotating rod 323 rotates, the multiple upper vertical cutters 324 distributed on it will mesh with the multiple lower vertical cutters 322 on the rotating rod 321 to cut the cardboard vertically at equal intervals. After the cardboard has completed the creasing and vertical cutting process, it will move to the position of the flat die 332. At this time, the hydraulic push rod 331 is activated. With the assistance of the two balance rods 333, the hydraulic push rod 331 enables the flat die 332 to complete the die cutting through the vertical pressure of the plane.
[0028] 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.
[0029] 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 kind of die cutting indentation integrated machine anti-deviation alignment mechanism, including machine body (1), it is characterized in that, Also includes: Alignment part (2), which is provided on the body (1); as well as Processing unit (3), which is disposed on the machine body (1); The alignment part (2) includes an alignment component (21), which is mounted on the body (1); and A drive component (22) is mounted on an alignment component (21); The alignment component (21) includes L-shaped plates (211) fixedly connected to both sides of the body (1). Two slide rods (212) are fixedly connected to the side of the two L-shaped plates (211) that are close to each other. Two slide plates (213) are slidably connected to the outer walls of the two slide rods (212). Alignment clamps (214) are fixedly connected to the bottom of the two slide plates (213). Racks (215) are fixedly connected to the top of the two slide plates (213). Slide rails (216) are fixedly connected to the bottom of the two racks (215). Two racks (215) and their slide rails (216) are respectively installed on the top of two slides (213) and are staggered.
2. The anti-offset alignment mechanism for a die-cutting and creasing integrated machine according to claim 1, characterized in that, The processing unit (3) includes an indentation assembly (31), which is mounted on the machine body (1); as well as Vertical cutting assembly (32), which is mounted on the body (1); A cross-cutting assembly (33) is mounted on the body (1); The indentation assembly (31) has eight pairs, which are symmetrically distributed with four pairs on each side.
3. The anti-offset alignment mechanism for an integrated die-cutting and creasing machine according to claim 2, characterized in that, The drive assembly (22) includes a fixing plate (221) sleeved on the outer wall of two slide rods (212). The fixing plate (221) has two slide rail grooves (222). The two slide rails (216) extend outside the two slide rail grooves (222) and are slidably connected to the two slide rail grooves (222). A motor (223) is provided on the fixing plate (221). The output shaft of the motor (223) is fixedly connected to a rotating shaft (224) through a coupling. A gear (225) is sleeved on the outer wall of the rotating shaft (224). Among them, the two upper indentation dies (315) drive the second gear (316) to be staggered and mesh with the first gear (225).
4. The anti-offset alignment mechanism for an integrated die-cutting and creasing machine according to claim 3, characterized in that, The indentation assembly (31) includes a motor two (311) fixedly connected to the right side of the machine body (1). The output shaft of the motor two (311) is fixedly connected to a rotating rod one (312) via a coupling. The outer wall of the rotating rod one (312) is fitted with several lower indentation molds (313). The machine body (1) is rotatably connected to a rotating rod two (314). Both ends of the rotating rod two (314) extend outside the machine body (1). The outer wall of the rotating rod two (314) is fitted with several upper indentation molds (315). The several upper indentation molds (315) are adapted to the several lower indentation molds (313). The outer wall of the left end of the rotating rod one (312) and the rotating rod two (314) is fitted with a gear two (316). The two gear two (316) mesh with each other. Among them, the rotating rod (312) passes through the body (1) and is rotatably connected to the body (1).
5. The anti-offset alignment mechanism for an integrated die-cutting and creasing machine according to claim 4, characterized in that, The vertical cutting assembly (32) includes a rotating rod three (321) rotatably connected to the machine body (1), both ends of the rotating rod three (321) extending outside the machine body (1), and a plurality of lower vertical cutting blades (322) sleeved on the outer wall of the rotating rod three (321). A rotating rod four (323) is rotatably connected to the machine body (1), both ends of the rotating rod four (323) extending outside the machine body (1), and a plurality of upper vertical cutting blades (324) sleeved on the outer wall of the rotating rod four (323). The plurality of upper vertical cutting blades (324) are adapted to the plurality of lower vertical cutting blades (322). A transmission component is provided on the rotating rod four (323). Among them, there are three pairs of upper vertical cutters (324) and lower vertical cutters (322), which are divided into eight pairs of indentation components (31).
6. The anti-offset alignment mechanism for an integrated die-cutting and creasing machine according to claim 5, characterized in that, The cross-cutting assembly (33) includes a hydraulic push rod (331) fixedly connected to the top of the machine body (1). The output end of the hydraulic push rod (331) extends to the outside of the machine body (1) and is slidably connected to the machine body (1). A flat die cutter (332) is fixedly connected to the output end of the hydraulic push rod (331). Two balance bars (333) are fixedly connected to the top of the flat die cutter (332). The tops of the two balance bars (333) extend to the outside of the body (1) and are slidably connected to the body (1).
7. The anti-offset alignment mechanism for a die-cutting and creasing integrated machine according to claim 6, characterized in that, The transmission component includes gear three (325) which are both sleeved on the outer walls of rotating rod four (323) and rotating rod two (314), and toothed belts (326) are wound around the outer walls of the two gear three (325); Among them, the two gears three (325) are both sleeved on the right outer wall of the rotating rod four (323) and the rotating rod two (314).