A multifunctional cutting machine

By integrating scanning, cutting, and printing functions into one multi-functional cutting machine, the problems of single function and insufficient coordination of traditional cutting equipment have been solved. This has enabled the miniaturization of the equipment and efficient collaborative operation, thereby improving processing accuracy and efficiency.

CN224374264UActive Publication Date: 2026-06-19GUANGZHOU XIHEXI PRECISION TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGZHOU XIHEXI PRECISION TECH CO LTD
Filing Date
2025-06-20
Publication Date
2026-06-19

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  • Figure CN224374264U_ABST
    Figure CN224374264U_ABST
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Abstract

A multifunctional cutting machine comprises a conveying device, a pressing device arranged in front of the pressing area in the conveying direction of the conveying device, and a cutting device arranged in the working area behind the conveying direction of the conveying device. The cutting device comprises a crossbeam across the conveying device, a first driving mechanism driving the crossbeam to move longitudinally, a sliding plate arranged on the crossbeam and sliding along the length direction of the crossbeam, a second driving mechanism driving the sliding plate, a cutter head mechanism arranged on the sliding plate, a printing mechanism arranged on the sliding plate, and a scanning mechanism arranged at the bottom of the crossbeam. The automatic equipment integrating the functions of scanning positioning, cutting and printing realizes the collaborative work of the three functions through the optimization of the structure, and improves the processing precision and efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of cutting machine technology, and in particular to a multi-functional cutting machine that integrates cutting, printing and scanning. Background Technology

[0002] Traditional cutting equipment has a single function, requiring multiple devices (such as scanners and printers) to complete material identification, marking, and cutting. This results in problems such as large footprint, low efficiency in process coordination, and poor positioning accuracy. While there are composite devices in existing technologies, they generally suffer from complex structures and insufficient coordination between functional modules. Therefore, there is an urgent need for a highly integrated, multi-process collaborative, all-in-one device. Summary of the Invention

[0003] The technical problem to be solved by this utility model is to provide a multi-functional cutting machine, an automated device that integrates scanning positioning, cutting and printing functions, and achieves coordinated operation of the three functions through structural optimization, thereby improving processing accuracy and efficiency.

[0004] To solve the above-mentioned technical problems, the technical solution of this utility model is: a multi-functional cutting machine, including a conveying device, a pressing device located in the pressing area in front of the conveying device in the conveying direction, and a cutting device located in the working area behind the conveying device in the conveying direction. The cutting device includes a crossbeam spanning the conveying device, a first driving mechanism for driving the crossbeam to move longitudinally, a sliding plate located on the crossbeam and sliding along its length, a second driving mechanism for driving the sliding plate, a cutting head mechanism located on the sliding plate, a printing mechanism located on the sliding plate, and a scanning mechanism located at the bottom of the crossbeam. The principle of this utility model is as follows: material is laid flat on the conveying device and conveyed from front to back. When the material reaches its position, the conveying device stops, and the pressing device starts to press and fix the material. The cutting head mechanism cuts the material according to the path. After the material is cut, the printing mechanism performs inkjet printing on the material, forming a mark on the material for subsequent processing. During the material conveying process, the surface of the material can be scanned to record the pattern on the surface, and the cutting head mechanism can cut according to this pattern.

[0005] As an improvement, the cutter head mechanism includes an electric vibrating blade and a third driving mechanism for driving the electric vibrating blade to move up and down. The third driving mechanism includes a third slide rail mounted on a sliding plate and vertically arranged, a third slider that slides with the third slide rail, a third lead screw that threads with the third slider, and a third motor that drives the third lead screw. The electric vibrating blade is mounted on the third slider.

[0006] As an improvement, the conveying device includes a frame, a conveyor belt mounted on the frame, and a fourth drive mechanism for driving the conveyor belt.

[0007] As an improvement, the clamping device includes a pressure bar spanning the conveying device and cylinders located at both ends of the pressure bar.

[0008] As an improvement, the first drive mechanism includes a first rack, a first gear meshing with the first rack, and a first motor driving the first gear, wherein the first motor is mounted on a crossbeam.

[0009] As an improvement, the second drive mechanism includes a second slide rail, a second slider that cooperates with the second slide rail and is connected to a sliding plate, a second nut seat that is connected to the sliding plate, a second lead screw that is threadedly engaged with the second nut seat, and a second motor that drives the second lead screw.

[0010] As an improvement, the printing mechanism includes a printing bracket, a print head mounted on the printing bracket, and an ink cartridge for supplying ink to the print head.

[0011] As an improvement, the scanning mechanism includes a scanning bracket and a scanning head assembly mounted on the scanning bracket.

[0012] The beneficial effects of this utility model compared with the prior art are:

[0013] This automated equipment integrates scanning, positioning, cutting, and printing functions. Through structural optimization, it enables the three functions to work together, thereby improving processing accuracy and efficiency. Attached Figure Description

[0014] Figure 1 This is a top view of the present invention.

[0015] Figure 2 This is a schematic diagram of the cutting device. Detailed Implementation

[0016] The present invention will be further described below with reference to the accompanying drawings.

[0017] like Figure 1 , 2As shown, a multi-functional cutting machine includes a conveying device 1, a clamping device 2 located in a clamping area in front of the conveying device 1 in the conveying direction, and a cutting device 3 located in a working area behind the conveying device 1 in the conveying direction. The conveying device 1 includes a frame, a conveyor belt mounted on the frame, and a fourth drive mechanism for driving the conveyor belt. The fourth drive mechanism includes a drive roller, a driven roller, and a fourth motor. The fourth motor drives the drive roller through a transmission assembly. The conveyor belt passes through the clamping area and the working area, and the material is laid flat on the conveyor belt for conveying. The clamping device 2 includes a pressure bar spanning the conveying device 1 and cylinders located at both ends of the pressure bar. The pressure bar is positioned above the conveyor belt. The cylinders drive the pressure bar to move up and down. When material needs to be clamped, the cylinders drive the pressure bar downwards, relying on the pressure of the pressure bar to fix the material and improve cutting accuracy. The cutting device 3 includes a crossbeam 31 spanning the conveying device 1, a first driving mechanism for driving the crossbeam 31 longitudinally, a sliding plate 32 mounted on the crossbeam 31 and sliding along its length, a second driving mechanism for driving the sliding plate 32, a cutting head mechanism 33 mounted on the sliding plate 32, a printing mechanism 34 mounted on the sliding plate 32, and a scanning mechanism 35 mounted at the bottom of the crossbeam 31; the first driving mechanism includes a first rack, a first gear meshing with the first rack, and a first motor driving the first gear, the first motor being mounted on the crossbeam 31; the second driving mechanism includes a cutting head mechanism 33 mounted on the sliding plate 32, a printing mechanism 34 mounted on the sliding plate 32, and a scanning mechanism 35 mounted at the bottom of the crossbeam 31; the first driving mechanism includes a first rack, a first gear meshing with the first rack, and a first motor driving the first gear, the second driving mechanism including a cutting head mechanism 33 mounted on the crossbeam 31; the second driving mechanism including a cutting head mechanism 34 mounted on the sliding plate 32, and a second driving mechanism including a cutting head mechanism 35 mounted on the sliding plate 31; the first driving mechanism including a cutting head mechanism 33 mounted on the sliding plate 32, a cutting head mechanism 33 mounted on the sliding plate 32, a cutting head mechanism 33 mounted on the sliding plate 32, and a printing mechanism 34 mounted on the sliding plate 32; the second driving mechanism including a cutting head mechanism 33 mounted on the sliding plate 32, and a printing mechanism 35 mounted on the sliding plate 32. The moving mechanism includes a second slide rail, a second slider that cooperates with the second slide rail and is connected to the sliding plate 32, a second nut seat connected to the sliding plate 32, a second lead screw that is threadedly engaged with the second nut seat, and a second motor that drives the second lead screw; the printing mechanism 34 is an inkjet printer, which includes a printing bracket, a print head mounted on the printing bracket, and an ink cartridge that supplies ink to the print head, with the print head facing downwards and the ink cartridge being replaceable; the scanning mechanism 35 includes a scanning bracket and a scanning head assembly mounted on the scanning bracket, and the scanning mechanism 35 moves with the crossbeam 31 to scan the material below.

[0018] The principle of this invention is as follows: the material is laid flat on the conveying device 1 and conveyed from front to back. When the material arrives, the conveying device 1 stops, and the pressing device 2 starts to press and fix the material. The cutting head mechanism 33 cuts the material according to the path. After the material is cut, the printing mechanism 34 prints ink on the material to form a mark on the material for subsequent processing. During the material conveying process, the surface of the material can be scanned to record the pattern on the surface of the material. The cutting head mechanism 33 can then cut according to the pattern.

Claims

1. A multi-functional cutting machine, comprising a conveying device, a clamping device located in a clamping area in front of the conveying device in the conveying direction, and a cutting device located in a working area behind the conveying device in the conveying direction, characterized in that: The cutting device includes a crossbeam spanning the conveying device, a first driving mechanism for driving the crossbeam to move longitudinally, a sliding plate disposed on the crossbeam and sliding along its length, a second driving mechanism for driving the sliding plate, a cutting head mechanism disposed on the sliding plate, a printing mechanism disposed on the sliding plate, and a scanning mechanism disposed at the bottom of the crossbeam.

2. The multi-functional cutting machine according to claim 1, characterized in that: The cutter head mechanism includes an electric vibrating cutter and a third driving mechanism for driving the electric vibrating cutter to move up and down. The third driving mechanism includes a third slide rail mounted on a sliding plate and vertically arranged, a third slider that slides with the third slide rail, a third lead screw that threads with the third slider, and a third motor that drives the third lead screw. The electric vibrating cutter is mounted on the third slider.

3. A multi-functional cutting machine according to claim 1, characterized in that: The conveying device includes a frame, a conveyor belt mounted on the frame, and a fourth drive mechanism for driving the conveyor belt.

4. A multi-functional cutting machine according to claim 1, characterized in that: The clamping device includes a pressure bar spanning the conveying device and cylinders located at both ends of the pressure bar.

5. A multi-functional cutting machine according to claim 1, characterized in that: The first drive mechanism includes a first rack, a first gear meshing with the first rack, and a first motor driving the first gear, wherein the first motor is mounted on a crossbeam.

6. A multi-functional cutting machine according to claim 1, characterized in that: The second drive mechanism includes a second slide rail, a second slider that cooperates with the second slide rail and is connected to a sliding plate, a second nut seat that is connected to the sliding plate, a second lead screw that is threadedly engaged with the second nut seat, and a second motor that drives the second lead screw.

7. A multi-functional cutting machine according to claim 1, characterized in that: The printing mechanism includes a printing bracket, a print head mounted on the printing bracket, and an ink cartridge that supplies ink to the print head.

8. A multi-functional cutting machine according to claim 1, characterized in that: The scanning mechanism includes a scanning bracket and a scanning head assembly mounted on the scanning bracket.