Integrated work platform
By designing an integrated work platform, combined with a sinking drive device and a detachable cover plate, unified processing of planar and cylindrical objects is achieved, solving the problem of complex adaptation in existing technologies and improving work efficiency and adaptability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHEJIANG GONGZHENG INTELLIGENT EQUIPMENT CO LTD
- Filing Date
- 2026-06-05
- Publication Date
- 2026-07-14
AI Technical Summary
Existing work platforms are unable to meet the processing needs of both planar and cylindrical objects on the same platform, resulting in complex adaptation steps for additional worktables and difficulty in controlling the degree of adaptation.
An integrated work platform was designed, which includes a sunken second work area with a built-in drive unit for driving the rotation of cylindrical objects. The drive unit is detachably connected to the platform via a cover plate, realizing the integration of planar and cylindrical object processing. The support and drive unit are used to stabilize the rotation.
It reduces the need for additional workbench setup, improves work efficiency and adaptability, and enhances the ease of switching between different processing modes and processing accuracy.
Smart Images

Figure CN224489049U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a workbench, specifically an integrated work platform. Background Technology
[0002] Some work platforms have specific requirements for the work area. For example, in printing equipment, a flat platform is generally required to provide a work area for printing flat materials such as paper, film, and cardboard. If there are additional requirements, such as printing cylindrical objects, another worktable needs to be placed on the flat worktable for printing. This method requires the two worktables to be adapted, which increases the debugging steps and difficulty, and the compatibility is also difficult to control. Utility Model Content
[0003] In view of the shortcomings of the existing technology, the purpose of this utility model is to provide an integrated work platform that can meet the integrated needs of planar machining and cylindrical object machining, and can reduce the adaptation steps of additional worktables and improve the compatibility.
[0004] To achieve the above objectives, the present invention provides the following technical solution: An integrated work platform, comprising a first work area and a second work area, wherein the second work area is in a sunken state relative to the first work area, and a driving device is provided in the second work area for driving the object to be processed to rotate.
[0005] As a further improvement of this utility model, a cover plate is provided on the second working area, and the cover plate is detachably connected to the platform body.
[0006] As a further improvement of this utility model, the surface of the cover plate is flush with or slightly lower than the surface of the platform body.
[0007] As a further improvement of this utility model, the cover plate is provided with a through hole, which can at least allow a tool or finger to be inserted.
[0008] As a further improvement of this utility model, the driving device includes a support part and a driver. The support part is used to support the object to be processed, and the driver drives the support part to move, thereby causing the object to be processed to rotate.
[0009] As a further improvement of this utility model, the support includes two rotating shafts, forming a space between the two rotating shafts for placing the object to be processed, and the rotating shafts drive the object to be processed to rotate; at least one of the rotating shafts is connected to a driver, and the driver drives the rotation.
[0010] As a further improvement of this utility model, each of the two rotating shafts is provided with several rollers, and the rollers on the two rotating shafts cooperate with each other to form a space for placing the object to be processed, and the object to be processed is placed on the rollers of the two rotating shafts.
[0011] As a further improvement of this utility model, the driver is a motor, which drives the two rotating shafts to rotate synchronously via a timing belt.
[0012] The beneficial effects of this utility model are that by setting up a sunken second working area and configuring a driving device therein, the planar working area and the cylindrical object processing area are integrated on the same platform, which reduces the debugging steps of the additional adaptation worktable, improves the adaptability, and increases work efficiency. Attached Figure Description
[0013] Figure 1 This is a three-dimensional schematic diagram of the overall structure of this utility model;
[0014] Figure 2 This is a three-dimensional schematic diagram of the working platform structure of this utility model (with the cover plate removed).
[0015] Figure 3 This is a top view of the working platform structure of this utility model (with the cover plate removed).
[0016] Figure 4 This is a front view schematic diagram of the working platform structure of this utility model (with the cover plate removed).
[0017] Reference numerals in the attached figures: 1. First working area; 2. Second working area; 3. Drive device; 31. Support part; 311. Rotating shaft; 312. Roller; 32. Driver; 4. Cover plate; 41. Through hole. Detailed Implementation
[0018] The present invention will now be described in further detail with reference to the embodiments shown in the accompanying drawings.
[0019] Reference Figure 1-4 As shown, an integrated work platform in this embodiment includes a first work area 1 and a second work area 2, wherein the second work area 2 is in a sunken state relative to the first work area 1, and a drive device 3 is provided in the second work area 2 for driving the object to be processed to rotate.
[0020] The first working area 1 serves as a planar processing area, accommodating flat materials such as paper, film, and cardboard for processing. The second working area 2 is recessed relative to the first working area 1, forming a concave space where a drive device 3 can be installed. When processing cylindrical objects, the cylindrical object is placed on the drive device 3 in the second working area 2. The drive device 3 contacts the cylindrical object and provides rotational driving force, causing the cylindrical object to rotate around its axis. The processing equipment completes circumferential processing during the rotation of the cylindrical object. The first working area 1 and the second working area 2 are integrated on the same platform body, reducing the adaptation problems caused by placing an additional independent worktable, simplifying debugging steps, and improving the efficiency of switching between different working modes.
[0021] This integrated work platform achieves compatibility between two processing modes by integrating a planar working area and a sunken cylindrical object working area on the same platform body.
[0022] In order to facilitate the shielding and protection of the second working area 2, in one optional solution, a cover plate 4 is provided on the second working area 2, which is detachably connected to the platform body.
[0023] Cover plate 4 covers the opening of the second working area 2 and is detachably connected to the platform body via bolts. When planar machining is required, cover plate 4 is installed above the second working area 2 to shield it, reducing dust and foreign objects from entering the lowered area and minimizing interference when placing planar materials. When machining cylindrical objects, cover plate 4 is removed from the platform body, exposing the second working area 2 and its internal drive unit 3, allowing cylindrical objects to be placed for machining. The detachable connection between cover plate 4 and the platform body improves the convenience of switching between the two working modes.
[0024] The cover plate 4 effectively shields the second working area 2 in planar machining mode, improving the platform's protective performance.
[0025] Further optimization can be achieved by selecting the following method: the surface of cover plate 4 is flush with or slightly lower than the surface of the platform body.
[0026] When the cover plate 4 is installed in the second working area 2, the upper surface of the cover plate 4 is on the same plane as or slightly lower than the surface surrounding the first working area 1 in the platform body. This arrangement ensures that there is no significant height difference or step between the cover plate 4 and the first working area 1 in the planar machining mode. Planar material can smoothly transition from the first working area 1 to the cover plate 4, reducing material warping or jamming caused by uneven surfaces and improving the continuity and stability of planar machining.
[0027] The flush design of the cover plate 4 surface with the platform body surface improves the stability of planar machining.
[0028] In some options, the cover plate 4 is provided with a through hole 41, which allows at least a tool or finger to be inserted.
[0029] A through-hole 41 is formed on the surface of the cover plate 4, and its size is designed to allow fingers or tools to be inserted. When it is necessary to remove the cover plate 4 from the platform body, the operator can insert fingers or tools into the through-hole 41 and apply an upward pulling force or prying force to the cover plate 4, thereby loosening or separating the connection structure between the cover plate 4 and the platform body, making it easier to remove the cover plate 4. The through-hole 41 improves the ease of operation for removing the cover plate 4 and reduces the difficulty of removal.
[0030] The opening of the through hole 41 improves the ease of disassembly and assembly of the cover plate 4.
[0031] To illustrate the structure of the drive device 3 in more detail, the drive device 3 includes a support part 31 and a driver 32. The support part 31 is used to support the object to be processed, and the driver 32 drives the support part 31 to move, thereby causing the object to be processed to rotate.
[0032] The support part 31 is installed at the bottom or side wall of the second working area 2, and its upper part is in direct contact with the object to be processed, providing support. The driver 32 is fixed in the internal space of the second working area 2 and is connected to the support part 31 through a transmission mechanism. When the driver 32 is started, its output rotational motion is transmitted to the support part 31. During rotation, the support part 31 drives the object to be processed to rotate around its own axis through friction or meshing force with the object to be processed. The support part 31 and the driver 32 can be directly connected or connected through an intermediate transmission component. This structure enables the drive device 3 to stably support and drive the object to be processed to rotate, improving the reliability of cylindrical object processing.
[0033] To further refine the structure of the support part 31, the support part 31 includes two rotating shafts 311, and a space for placing the object to be processed is formed between the two rotating shafts 311. The object to be processed is rotated by rotating the rotating shafts 311. At least one of the rotating shafts 311 is connected to the driver 32 and is driven to rotate by the driver 32.
[0034] Two rotating shafts 311 are arranged parallel to each other within the second working area 2, maintaining a certain distance between them to form a space for placing the object to be processed. The object to be processed is placed between the two rotating shafts 311, with its outer circumferential surface in contact with both shafts 311 simultaneously. At least one end of the rotating shaft 311 is connected to a driver 32, which drives the rotating shaft 311 to rotate. The rotating shaft 311 drives the object to rotate through friction with the object to be processed, while the object to be processed drives the other rotating shaft 311 to rotate accordingly. The two rotating shafts 311 can also be connected to their respective drivers 32 to achieve synchronous driving. The rotating shafts 311 are mounted on the side wall or bracket of the second working area 2 via bearings. This dual-rotating-shaft 311 support structure keeps the object to be processed stable during rotation, reducing wobbling and offset, and improving processing accuracy.
[0035] In some options, each of the two rotating shafts 311 is provided with a number of rollers 312, and the rollers 312 on the two rotating shafts 311 cooperate with each other to form a space for placing the object to be processed, and the object to be processed is placed on the rollers 312 of the two rotating shafts 311.
[0036] Each rotating shaft 311 is provided with several rollers 312 spaced axially. The rollers 312 can be fixedly or rotatably connected to the rotating shaft 311. The rollers 312 on two rotating shafts 311 correspond to each other in axial position, forming multiple sets of support points, which together constitute a space for placing the object to be processed. The object to be processed is placed between two sets of rollers 312, with its outer circumference in contact with the rollers 312. When the rotating shaft 311 rotates, the rollers 312 rotate accordingly, driving the object to be processed to rotate through the friction between them. The rollers 312 can be made of elastic material to increase the friction between them and the object to be processed. The arrangement of the rollers 312 improves the support and transmission effect of the object to be processed.
[0037] Further optimization can be achieved by selecting the following method: the driver 32 is a motor that synchronously drives the two rotating shafts 311 to rotate via a synchronous belt.
[0038] The motor is fixedly installed inside the second working area 2. A drive pulley is mounted on the motor's output shaft, and driven pulleys are mounted on the ends of the two rotating shafts 311. A synchronous belt wraps around the drive pulley and the two driven pulleys. When the motor starts, the drive pulley transmits power to the two driven pulleys simultaneously via the synchronous belt, causing the two rotating shafts 311 to rotate synchronously at the same speed. The synchronous belt can be a toothed belt, and the pulleys can have a corresponding toothed structure to maintain an accurate transmission ratio. When the two rotating shafts 311 rotate synchronously, the workpiece placed on them receives a uniform driving force, reducing the possibility of the workpiece skewing or slipping due to differences in rotational speed on both sides, thus improving the synchronicity of rotation and the consistency of processing quality.
[0039] The above-mentioned processing can be printing, such as printing on paper, film, cardboard, or printing on the surface of cylindrical bottles and cups.
[0040] In actual operation, when planar printing is required, the cover plate 4 is installed above the second working area 2. The surface of the cover plate 4 is flush with or slightly lower than the surface of the platform body. The first working area 1 and the cover plate 4 together form a continuous planar support surface, on which planar materials such as paper and film are placed for printing. When printing cylindrical objects, the cover plate 4 is removed from the platform body through the through hole 41, exposing the sunken second working area 2. The cylindrical object to be processed is placed between the rollers 312 of the two rotating shafts 311. The motor drives the two rotating shafts 311 to rotate synchronously via a synchronous belt. The rollers 312 on the rotating shafts 311 rotate the object around its axis through friction with the object. The printing device completes circumferential printing during the rotation of the object. The first working area 1 and the second working area 2 are integrated into the same platform. The switching between planar printing mode and cylindrical object printing mode is achieved by removing and installing the cover plate 4, reducing the need for additional worktable adaptation and debugging, and improving the integration and ease of use of the work platform.
[0041] The above description is merely a preferred embodiment of this utility model. The protection scope of this utility model is not limited to the above embodiments. All technical solutions falling within the scope of this utility model's concept are protected. It should be noted that for those skilled in the art, any improvements and modifications made without departing from the principle of this utility model should also be considered within the protection scope of this utility model.
Claims
1. An integrated work platform, characterized in that, It includes a first working area and a second working area, wherein the second working area is in a sunken state relative to the first working area, and a driving device is provided in the second working area to drive the object to be processed to rotate.
2. The integrated work platform according to claim 1, characterized in that, The second working area is provided with a cover plate, which is detachably connected to the platform body.
3. The integrated work platform according to claim 2, characterized in that, The surface of the cover plate is flush with or slightly lower than the surface of the platform body.
4. The integrated work platform according to claim 2, characterized in that, The cover plate is provided with a through hole, which is at least large enough for a tool or finger to be inserted.
5. The integrated work platform according to any one of claims 1 to 4, characterized in that, The driving device includes a support and a driver. The support is used to support the object to be processed, and the driver drives the support to move, thereby causing the object to be processed to rotate.
6. The integrated work platform according to claim 5, characterized in that, The support includes two rotating shafts, forming a space between the two rotating shafts for placing the object to be processed, and the rotating shafts drive the object to be processed to rotate; at least one of the rotating shafts is connected to a driver, and the driver drives the rotation.
7. The integrated work platform according to claim 6, characterized in that, Each of the two rotating shafts is equipped with several rollers, and the rollers on the two rotating shafts cooperate with each other to form a space for placing the object to be processed. The object to be processed is placed on the rollers of the two rotating shafts.
8. The integrated work platform according to claim 7, characterized in that, The driver is a motor, which drives the two rotating shafts to rotate synchronously via a timing belt.