CN215881931U - Two-axis translation mechanism for numerical control engraving machine - Google Patents

Abstract

The utility model discloses a two-axis translation mechanism for a numerical control engraving machine, which comprises a workbench, an X-axis movement mechanism, a Y-axis movement mechanism and an engraving knife processing device, wherein the Y-axis movement mechanism comprises a Y-axis track, a Y-axis driving device and a movement connecting plate; the X-axis moving mechanism comprises an X-axis track and an X-axis driving device; y-axis rails are arranged on two sides of the workbench, and the Y-axis driving device is assembled on the Y-axis rails and can slide on the Y-axis rails; the Y-axis driving devices on the two sides are fixedly connected with one end of the movable connecting plate, and the other ends of the movable connecting plates on the two sides are respectively fixedly connected with the two ends of the X-axis track; the X-axis driving device is assembled on the X-axis track and can slide on the X-axis track; the X-axis driving device is fixedly connected with the graver machining device. The utility model is provided with the Y-axis track, the X-axis track, the Y-axis driving device, the X-axis driving device and the movable connecting plate, has simple structure, is easy to maintain equipment when problems occur, and can reduce the maintenance cost.

Description

Two-axis translation mechanism for numerical control engraving machine

Technical Field

The utility model relates to the technical field of numerical control engraving, in particular to a two-axis translation mechanism for a numerical control engraving machine.

Background

With the continuous development of modern mechanical industry, the numerical control engraving machine is also improved step by step as an automatic engraving device, materials are engraved by a nicking tool, but the XY-axis moving mechanism of many engraving machines at present is complex in structure, so that the maintenance cost of the device is high, and the device is not stable enough during moving.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model aims to provide a two-axis translation mechanism for a numerical control engraving machine.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a two-axis translation mechanism for a numerical control engraving machine comprises a workbench, an X-axis moving mechanism, a Y-axis moving mechanism and an engraving knife processing device, wherein the Y-axis moving mechanism comprises a Y-axis track, a Y-axis driving device and a moving connecting plate; the X-axis moving mechanism comprises an X-axis track and an X-axis driving device; the Y-axis rails are arranged on two sides of the workbench, and the Y-axis driving device is assembled on the Y-axis rails and can slide on the Y-axis rails; the Y-axis driving devices on the two sides are fixedly connected with one end of the movable connecting plate, and the other ends of the movable connecting plates on the two sides are respectively fixedly connected with the two ends of the X-axis track; the X-axis driving device is assembled on the X-axis track and can slide on the X-axis track; and the X-axis driving device is fixedly connected with the graver machining device.

It should be noted that the top and the bottom of the Y-axis track are both provided with a first strip chute, and the top and the bottom of the X-axis track are both provided with a second strip chute.

It should be noted that the Y-axis driving device includes a first motor, a plurality of first rollers, a plurality of first roller shafts, and a fixing plate; the fixed plate is positioned on the inner side of the Y-axis track, and the movable connecting plate is positioned on the outer side of the Y-axis track; the first roller shaft is arranged between the fixed plate and the movable connecting plate and is respectively positioned above and below the Y-axis track, the first roller is arranged on the first roller shaft, and the first roller is embedded into the first strip-shaped sliding groove; the first motor drives the first roller to rotate through a belt, and when the first roller rotates, the first motor can drive the X-axis track and the X-axis driving device to move.

The X-axis driving device includes a second motor, a plurality of second rollers, a plurality of second roller shafts, a first connecting plate and a second connecting plate, where the first connecting plate and the second connecting plate are respectively disposed at two sides of the X-axis track; the second roller shaft is arranged between the first connecting plate and the second connecting plate and is respectively positioned above and below the X-axis track; the second roller is arranged on the second roller shaft and is embedded into the second long-strip sliding groove; the second motor drives the second roller to rotate through a belt, and the second roller can drive the graver machining device to move when rotating.

The utility model has the beneficial effects that: the Y-axis track, the X-axis track, the Y-axis driving device, the X-axis driving device and the movable connecting plate are arranged, the structure is simple, equipment is easy to maintain when problems occur, and the maintenance cost can be reduced; meanwhile, the motor drives the roller to rotate through the belt, impact can be relieved when the roller moves, vibration is reduced, and transmission is more stable.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure A in FIG. 1;

fig. 3 is a schematic structural diagram of B in fig. 1.

Detailed Description

The present invention will be further described with reference to the accompanying drawings, and it should be noted that the present embodiment is based on the technical solution, and the detailed implementation and the specific operation process are provided, but the protection scope of the present invention is not limited to the present embodiment.

The embodiment provides a two-axis translation mechanism for a numerical control engraving machine, as shown in fig. 1-3, comprising a worktable 1, an X-axis moving mechanism 2, a Y-axis moving mechanism 3 and an engraving knife processing device 4, wherein the Y-axis moving mechanism 3 comprises a Y-axis track 303, a Y-axis driving device 305 and a moving connecting plate 307; the X-axis moving mechanism 2 comprises an X-axis track 304 and an X-axis driving device 306; the Y-axis rails 303 are arranged on both sides of the worktable 1, and the Y-axis driving device 305 is assembled on the Y-axis rails 303 and can slide on the Y-axis rails 303; the Y-axis driving devices 305 on both sides are fixedly connected to one end of the movable connecting plate 307, and the other ends of the movable connecting plates 307 on both sides are fixedly connected to both ends of the X-axis rail 304; the X-axis driving device 306 is mounted on the X-axis track 304 and can slide on the X-axis track 304; the X-axis driving device 306 is fixedly connected with the graver machining device 4.

In the above structure, the Y-axis driving device drives the X-axis moving mechanism to move on the Y-axis rail, and the X-axis driving device drives the graver machining device to move on the X-axis rail.

In this embodiment, as shown in fig. 1, the top and the bottom of the Y-axis track 303 are both provided with a first long sliding slot, and the top and the bottom of the X-axis track 304 are both provided with a second long sliding slot.

In this embodiment, as shown in fig. 2, the Y-axis driving device 305 includes a first motor 3051, a plurality of first rollers 3052, a plurality of first roller shafts 3053, and a fixing plate 3054; the fixed plate 3054 is located at the inner side of the Y-axis rail 303, and the moving connecting plate 307 is located at the outer side of the Y-axis rail 303; the first roller axle 3053 is disposed between the fixed plate 3054 and the moving connecting plate 307 and located above and below the Y-axis track 303, respectively, the first roller 3052 is disposed on the first roller axle 3053, and the first roller 3052 is inserted into the first elongated sliding groove; the first motor 3051 drives the first roller 3052 to rotate through a belt, and when the first roller 3052 rotates, the X-axis rail 304 and the X-axis driving device 306 can be driven to move.

In the above structure, the first motor drives the first roller to rotate after rotating, so that the Y-axis driving device moves.

In this embodiment, as shown in fig. 1 and fig. 3, the X-axis driving device 306 includes a second motor 3061, a plurality of second rollers 3062, a plurality of second roller shafts 3063, a first connecting plate 3064, and a second connecting plate 3065, and the first connecting plate 3064 and the second connecting plate 3065 are respectively disposed on two sides of the X-axis track 304; the second roller shaft 3063 is disposed between the first link plate 3064 and the second link plate 3065, above and below the X-axis track 304, respectively; the second roller 3062 is disposed on the second roller shaft 3063, and the second roller 3062 is embedded in the second elongated runner; the second motor 3061 drives the second roller 3062 to rotate through a belt, and when the second roller 3062 rotates, the graver processing device 4 can be driven to move.

The working principle of the two-axis translation mechanism for the numerical control engraving machine is as follows: a first motor on the Y-axis driving device drives the first roller to rotate on the Y-axis track through positive rotation and negative rotation, and when the first roller rotates, the first roller drives the X-axis track fixedly connected with the movable connecting plate to move, so that Y-axis translation can be realized; and the second electrode on the X driving device also rotates forwards and reversely to drive the second roller to rotate on the X-axis track, and when the first roller rotates, the first roller drives the graver machining device to move on the X-axis track, so that X-axis translation can be realized.

Various corresponding changes and modifications can be made by those skilled in the art based on the above technical solutions and concepts, and all such changes and modifications should be included in the protection scope of the present invention.

Claims (4)

1. A two-axis translation mechanism for a numerical control engraving machine comprises a workbench (1), an X-axis moving mechanism (2), a Y-axis moving mechanism (3) and an engraving knife processing device (4), and is characterized in that the Y-axis moving mechanism (3) comprises a Y-axis track (303), a Y-axis driving device (305) and a moving connecting plate (307); the X-axis moving mechanism (2) comprises an X-axis track (304) and an X-axis driving device (306); the Y-axis rails (303) are arranged on two sides of the workbench (1), and the Y-axis driving device (305) is assembled on the Y-axis rails (303) and can slide on the Y-axis rails (303); the Y-axis driving devices (305) on the two sides are fixedly connected with one end of the movable connecting plate (307), and the other ends of the movable connecting plates (307) on the two sides are fixedly connected with the two ends of the X-axis track (304) respectively; the X-axis driving device (306) is assembled on the X-axis track (304) and can slide on the X-axis track (304); the X-axis driving device (306) is fixedly connected with the graver machining device (4).

2. Two-axis translation mechanism for a numerically controlled engraving machine according to claim 1, characterized in that the top and bottom of the Y-axis track (303) are provided with a first elongated runner, and the top and bottom of the X-axis track (304) are provided with a second elongated runner.

3. Two-axis translation mechanism for a numerically controlled engraving machine according to claim 2, characterized in that said Y-axis driving means (305) comprise a first motor (3051), a plurality of first rollers (3052), a plurality of first roller shafts (3053) and a fixed plate (3054); the fixed plate (3054) is located on the inner side of the Y-axis rail (303), and the moving connecting plate (307) is located on the outer side of the Y-axis rail (303); the first roller shaft (3053) is arranged between the fixed plate (3054) and the moving connecting plate (307) and is respectively positioned above and below the Y-axis track (303), the first roller (3052) is arranged on the first roller shaft (3053), and the first roller (3052) is embedded in the first long sliding groove; the first motor (3051) drives the first roller (3052) to rotate through a belt, and when the first roller (3052) rotates, the X-axis track (304) and the X-axis driving device (306) can be driven to move.

4. Two-axis translation mechanism for a numerically controlled engraving machine according to claim 3, characterized in that said X-axis driving means (306) comprises a second motor (3061), a plurality of second rollers (3062), a plurality of second roller shafts (3063), a first connecting plate (3064) and a second connecting plate (3065), said first connecting plate (3064) and said second connecting plate (3065) being respectively arranged on both sides of said X-axis track (304); the second roller shaft (3063) is disposed between the first connection plate (3064) and the second connection plate (3065), and above and below the X-axis track (304), respectively; the second roller (3062) is disposed on the second roller shaft (3063), and the second roller (3062) is embedded in the second elongate runner; the second motor (3061) drives the second roller (3062) to rotate through a belt, and when the second roller (3062) rotates, the graver machining device (4) can be driven to move.

Images