CN219124594U - Triaxial manual adjustment platform - Google Patents

Abstract

The utility model discloses a three-axis manual adjustment platform, which relates to the field of three-dimensional adjustment platform structures and comprises a Z-axis base, Z-axis crossed roller guide rails arranged on two sides of the Z-axis base, a Z-axis sliding plate slidably arranged on the Z-axis crossed roller guide rails, a Z-axis adjusting device, an L-shaped Y-axis base arranged on the Z-axis sliding plate, a Y-axis crossed roller guide rail arranged on the Y-axis base, a Y-axis sliding plate slidably arranged on the Y-axis crossed roller guide rails, a Y-axis adjusting device, an X-axis base arranged on the Y-axis sliding plate, an X-axis crossed roller guide rail arranged on the X-axis base, an X-axis sliding plate slidably arranged on the X-axis crossed roller guide rail and an X-axis adjusting device. By installing an adjusting device in each axial direction of X, Y, Z, the vertical error of the X, Y, Z shaft in installation can be flexibly adjusted to meet the operation condition; the utility model has the advantages of convenient installation, low mechanical energy consumption, high speed, high bearing capacity and stable operation.

Description

Triaxial manual adjustment platform

Technical Field

The utility model relates to the field of three-dimensional adjusting platform structures, in particular to a three-axis manual adjusting platform.

Background

The three-axis platform is widely applied to the 3C industry, the medical instrument industry, the mobile phone flat-panel equipment, the optical detection equipment, the 3D printing industry, the laser cutting and other automation industries due to the three-dimensional adjustability.

However, the existing triaxial platform is usually formed by directly processing and superposing aluminum profiles of X axis, Y axis and Z axis. Therefore, the error of verticality between the three axes is large, and the method cannot be applied to occasions with low requirement errors. And after the service life of the aluminum profiles of the X axis, the Y axis and the Z axis is prolonged, each structure has a certain variable, thereby causing the whole operation fault of the equipment. And the integral precision of the equipment can only be improved by the precision of each structure, and the processing difficulty and the cost are high.

Disclosure of Invention

The utility model aims to solve the technical problems of large error, further improvement of precision and the like of the existing triaxial platform by providing the triaxial manual adjustment platform.

In order to solve the technical problems, the technical scheme of the utility model is as follows:

the utility model provides a manual adjustment platform of triaxial, includes Z axle base, installs the Z axle cross roller guide rail in Z axle base both sides, install with sliding the Z axle slide on the Z axle cross roller guide rail, connect Z axle adjusting device between Z axle base and the Z axle slide, install the Y axle base that is L type on the Z axle slide, install Y axle cross roller guide rail on the Y axle base, install with sliding the Y axle slide on the Y axle cross roller guide rail, connect Y axle adjusting device between Y axle base and the Y axle slide, install X axle base on the Y axle slide, install X axle cross roller guide rail on the X axle base, install with sliding the X axle slide on the X axle cross roller guide rail and connect X axle adjusting device between X axle base and the X axle slide.

When the Z-axis base is used, the Z-axis base can be processed into the size and the shape corresponding to a lathe and the like according to the requirements of clients; the workpiece is formed by processing the aluminum profile, and the surface of the aluminum profile is subjected to oxidation treatment, so that the use strength and the service life are ensured; the Z-axis adjusting device can drive the Z-axis base and the Z-axis sliding plate to generate relative displacement, so that the displacement in the Z-axis direction can be accurately adjusted; the Y-axis adjusting device can drive the Y-axis base and the Y-axis sliding block to perform relative displacement, so that the displacement in the Y-axis direction can be accurately adjusted; the X-axis adjusting device can drive the X-axis base and the X-axis sliding block to perform relative displacement, so that the displacement in the X-axis direction can be accurately adjusted.

Preferably, the Z-axis adjusting device comprises a Z-axis fixed bearing seat fixedly installed on the Z-axis sliding plate, a Z-axis screw rod rotatably installed on the Z-axis fixed bearing seat and a Z-axis sliding block sleeved on the Z-axis screw rod through threads, the Z-axis sliding block is fixedly connected with the side surface of the Z-axis base, in the practical use process, the side surface of the Z-axis sliding block and the side surface of the Z-axis base can be connected through a fixed bolt, and when in use, a worker can adjust the relative position of the Z-axis sliding block on the Z-axis screw rod by rotating and adjusting the Z-axis screw rod, so that under the sliding support of a Z-axis cross roller guide rail, the Z-axis base and the Z-axis sliding plate are driven to relatively displace, and therefore the displacement in the Z-axis direction can be accurately adjusted.

Preferably, the Y-axis adjusting device comprises a Y-axis fixed bearing seat fixedly installed on a Y-axis sliding plate, a Y-axis screw rod rotatably installed on the Y-axis fixed bearing seat and a Y-axis sliding block sleeved on the Y-axis screw rod through threads, wherein the Y-axis sliding block is fixedly connected with the side surface of the Y-axis base, in the actual use process, the side surface of the Y-axis sliding block and the side surface of the Y-axis base can be connected through a fixed bolt, and when in use, a worker can adjust the relative position of the Y-axis sliding block on the Y-axis screw rod by rotating and adjusting the Y-axis screw rod, so that under the sliding support of a Y-axis crossed roller guide rail, the relative displacement between the Y-axis base and the Y-axis sliding block is driven, and the displacement in the Y-axis direction can be accurately adjusted.

Preferably, the X-axis adjusting device comprises an X-axis fixed bearing seat fixedly installed on the X-axis sliding plate, an X-axis screw rod rotatably installed on the X-axis fixed bearing seat and an X-axis sliding block sleeved on the X-axis screw rod through threads, the X-axis sliding block is fixedly connected with the side surface of the X-axis base, in the actual use process, the side surface of the X-axis sliding block and the side surface of the X-axis base can be connected through a fixed bolt, and when in use, a worker can adjust the relative position of the X-axis sliding block on the X-axis screw rod by rotating and adjusting the X-axis screw rod, so that under the sliding support of an X-axis crossed roller guide rail, the X-axis base and the X-axis sliding block are driven to perform relative displacement, and therefore the displacement in the X-axis direction can be accurately adjusted.

Preferably, in order to facilitate manual accurate adjustment of staff, adjusting handwheels are respectively arranged at the ends of the Z-axis screw rod, the Y-axis screw rod and the X-axis screw rod.

Preferably, in order to be convenient for the installation of spare parts such as anchor clamps or suction nozzle that need to fix a position, the fixed V type locating piece that is provided with on the X axle slide and detachable is the last clamp block of L type, V type locating piece is the indent V type structure with last clamp block opposite side, go up clamp block and the indent arc structure of V type locating piece opposite side, go up clamp block side and base and seted up the installation through-hole respectively, be convenient for pass clamp block side and base's installation through-hole with installing bolt etc. and will go up clamp block and be fixed mutually with V type locating piece and X axle slide, through V type locating piece indent V type structure and last clamp block indent arc structure, can be convenient for the clamp fixing to the spare part of different shapes.

By adopting the technical scheme, the three-axis stable and flexible adjustment can be realized by utilizing the advantages of small rolling friction force, good stability, large contact area, small elastic deformation, more effective moving bodies, easiness in realizing high rigidity and high load movement, flexible structural design, convenience in installation and use, long service life, small mechanical energy consumption, high precision, high speed, large bearing capacity and the like of the crossed roller guide rail; by installing an adjusting device in each axial direction of X, Y, Z, the vertical error of the X, Y, Z shaft in installation can be flexibly adjusted to meet the operation condition; the utility model has the advantages of convenient installation, small mechanical energy consumption, high speed, large bearing capacity and stable operation, and is particularly suitable for the fields of precise calibration, precise cutting, precise displacement movement and the like.

Drawings

FIG. 1 is a schematic view of a structure of the present utility model in one direction;

fig. 2 is a schematic view of another direction of the present utility model.

In the figure, the device comprises a 1-Z axis base, a 2-Z axis crossed roller guide rail, a 3-Z axis sliding plate, a 4-Z axis fixed bearing seat, a 5-Z axis screw rod, a 6-Z axis sliding block, a 7-adjusting hand wheel, an 8-Y axis base, a 9-Y axis crossed roller guide rail, a 10-Y axis sliding plate, an 11-Y axis fixed bearing seat, a 12-Y axis screw rod, a 13-Y axis sliding block, a 14-X axis base, a 15-X axis crossed roller guide rail, a 16-X axis sliding plate, a 17-X axis fixed bearing seat, a 18-X axis screw rod, a 19-X axis sliding block, a 20-V type positioning block and a 21-upper clamping block.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings. The description of these embodiments is provided to assist understanding of the present utility model, but is not intended to limit the present utility model. In addition, the technical features of the embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

Example 1

As shown in fig. 1 and 2, a three-axis manual adjustment platform includes a Z-axis base 1, Z-axis cross roller rails 2 mounted on both sides of the Z-axis base 1, a Z-axis slide plate 3 slidably mounted on the Z-axis cross roller rails 2, a Z-axis adjustment device connected between the Z-axis base 1 and the Z-axis slide plate 3, a Y-axis base 8 in the form of an L mounted on the Z-axis slide plate 3, a Y-axis cross roller rail 9 mounted on the Y-axis base 8, a Y-axis slide plate 10 slidably mounted on the Y-axis cross roller rail 9, a Y-axis adjustment device connected between the Y-axis base 8 and the Y-axis slide plate 10, an X-axis base 14 mounted on the Y-axis slide plate 10, an X-axis cross roller rail 15 mounted on the X-axis cross roller rail 15, and an X-axis adjustment device connected between the X-axis base 14 and the X-axis slide plate 16.

When in use, the Z-axis base 1 can be processed into the size and shape corresponding to a lathe and the like according to the requirements of customers; the workpiece is formed by processing the aluminum profile, and the surface of the aluminum profile is subjected to oxidation treatment, so that the use strength and the service life are ensured; the Z-axis adjusting device can drive the Z-axis base 1 and the Z-axis sliding plate 3 to perform relative displacement, so that the displacement in the Z-axis direction can be accurately adjusted; the Y-axis adjusting device can drive the Y-axis base 8 and the Y-axis sliding block 13 to perform relative displacement, so that the displacement in the Y-axis direction can be accurately adjusted; the X-axis adjusting device can drive the X-axis base 14 and the X-axis sliding block 19 to perform relative displacement, so that the displacement in the X-axis direction can be accurately adjusted.

Example 2

As shown in fig. 1 and 2, a three-axis manual adjustment platform comprises a Z-axis base 1, Z-axis crossed roller guide rails 2 installed at both sides of the Z-axis base 1, a Z-axis sliding plate 3 slidably installed on the Z-axis crossed roller guide rails 2, a Z-axis adjustment device connected between the Z-axis base 1 and the Z-axis sliding plate 3, a Y-axis base 8 installed on the Z-axis sliding plate 3, a Y-axis crossed roller guide rail 9 installed on the Y-axis base 8, a Y-axis sliding plate 10 slidably installed on the Y-axis crossed roller guide rail 9, a Y-axis adjustment device connected between the Y-axis base 8 and the Y-axis sliding plate 10, an X-axis base 14 installed on the Y-axis sliding plate 10, an X-axis crossed roller guide rail 15 installed on the X-axis crossed roller guide rail 15, an X-axis sliding plate 16 slidably installed on the X-axis crossed roller guide rail 15, and an X-axis adjustment device connected between the X-axis base 14 and the X-axis sliding plate 16; the X-axis sliding plate 16 is fixedly provided with a V-shaped positioning block 20 and a detachable L-shaped upper clamping block 21, one side of the V-shaped positioning block 20 opposite to the upper clamping block 21 is of a concave V-shaped structure, the other side of the upper clamping block 21 opposite to the V-shaped positioning block 20 is of a concave arc-shaped structure, and the side and the bottom edge of the upper clamping block 21 are respectively provided with a mounting through hole;

as further shown in fig. 1 and 2, the Z-axis adjusting device comprises a Z-axis fixed bearing seat 4 fixedly installed on the Z-axis sliding plate 3, a Z-axis screw rod 5 rotatably installed on the Z-axis fixed bearing seat 4, and a Z-axis sliding block 6 screwed on the Z-axis screw rod 5, wherein the Z-axis sliding block 6 is connected with the side surface of the Z-axis base 1 through a fixed bolt, and an adjusting hand wheel 7 is installed at the end part of the Z-axis screw rod 5;

as further shown in fig. 1 and 2, the Y-axis adjusting device comprises a Y-axis fixed bearing seat 11 fixedly installed on a Y-axis sliding plate 10, a Y-axis screw rod 12 rotatably installed on the Y-axis fixed bearing seat 11, and a Y-axis sliding block 13 screwed on the Y-axis screw rod 12, wherein the Y-axis sliding block 13 is connected with the side surface of the Y-axis base 8 through a fixed bolt, and an adjusting hand wheel 7 is installed at the end part of the Y-axis screw rod 12;

as further shown in fig. 1 and 2, the X-axis adjusting device comprises an X-axis fixed bearing seat 17 fixedly mounted on the X-axis sliding plate 16, an X-axis screw rod 18 rotatably mounted on the X-axis fixed bearing seat 17, and an X-axis slide block 19 screwed on the X-axis screw rod 18, wherein the X-axis slide block 19 is connected with the side surface of the X-axis base 14 through a fixing bolt, and an adjusting hand wheel 7 is mounted at the end of the X-axis screw rod 18.

When in use, the Z-axis base 1 can be processed into the size and shape corresponding to a lathe and the like according to the requirements of customers; the workpiece is formed by processing the aluminum profile, and the surface of the aluminum profile is subjected to oxidation treatment, so that the use strength and the service life are ensured; parts such as a clamp or a suction nozzle to be positioned are clamped between the upper clamping block 21 and the V-shaped positioning block 20, the clamping and fixing of parts with different shapes can be facilitated through the V-shaped structure of the concave of the V-shaped positioning block 20 and the arc-shaped structure of the concave of the upper clamping block 21, and mounting bolts and the like penetrate through mounting through holes on the side edge and the bottom edge of the upper clamping block 21 to fix the upper clamping block 21 with the V-shaped positioning block 20 and the X-axis sliding plate 16; the relative position of the Z-axis sliding block 6 on the Z-axis screw rod 5 can be adjusted by a worker through rotating the Z-axis screw rod 5, so that the Z-axis base 1 and the Z-axis sliding plate 3 are driven to generate relative displacement under the sliding support of the Z-axis crossed roller guide rail 2, and the displacement in the Z-axis direction can be accurately adjusted; the relative position of the Y-axis sliding block 13 on the Y-axis screw rod 12 can be adjusted by rotating the Y-axis screw rod 12, so that the Y-axis base 8 and the Y-axis sliding block 13 are driven to perform relative displacement under the sliding support of the Y-axis crossed roller guide rail 9, and the displacement in the Y-axis direction can be accurately adjusted; the relative position of the X-axis sliding block 19 on the X-axis screw rod 18 can be adjusted by rotating the X-axis screw rod 18, so that the X-axis base 14 and the X-axis sliding block 19 are driven to relatively displace under the sliding support of the X-axis crossed roller guide rail 15, and the displacement in the X-axis direction can be accurately adjusted.

The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings, but the present utility model is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the utility model, and yet fall within the scope of the utility model.

Claims (6)

1. A manual adjustment platform of triaxial, its characterized in that: the X-axis sliding plate comprises a Z-axis base (1), Z-axis crossed roller guide rails (2) arranged on two sides of the Z-axis base (1), a Z-axis sliding plate (3) slidably arranged on the Z-axis crossed roller guide rails (2), a Z-axis adjusting device connected between the Z-axis base (1) and the Z-axis sliding plate (3), an L-shaped Y-axis base (8) arranged on the Z-axis sliding plate (3), Y-axis crossed roller guide rails (9) arranged on the Y-axis base (8), Y-axis sliding plates (10) slidably arranged on the Y-axis crossed roller guide rails (9), Y-axis adjusting devices connected between the Y-axis base (8) and the Y-axis sliding plates (10), X-axis base (14) arranged on the Y-axis sliding plates (10), X-axis crossed roller guide rails (15) slidably arranged on the X-axis sliding plates (16) and X-axis adjusting devices connected between the X-axis base (14) and the X-axis sliding plates (16).

2. The three-axis manual adjustment platform of claim 1, wherein: the Z-axis adjusting device comprises a Z-axis fixed bearing seat (4) fixedly arranged on a Z-axis sliding plate (3), a Z-axis screw rod (5) rotatably arranged on the Z-axis fixed bearing seat (4) and a Z-axis sliding block (6) sleeved on the Z-axis screw rod (5) through threads, and the Z-axis sliding block (6) is fixedly connected with the side face of the Z-axis base (1).

3. The three-axis manual adjustment platform of claim 2, wherein: the Y-axis adjusting device comprises a Y-axis fixed bearing seat (11) fixedly arranged on a Y-axis sliding plate (10), a Y-axis screw rod (12) rotatably arranged on the Y-axis fixed bearing seat (11) and a Y-axis sliding block (13) sleeved on the Y-axis screw rod (12) in a threaded manner, wherein the Y-axis sliding block (13) is fixedly connected with the side face of the Y-axis base (8).

4. A triaxial manual adjustment platform according to claim 3, characterised in that: the X-axis adjusting device comprises an X-axis fixed bearing seat (17) fixedly arranged on an X-axis sliding plate (16), an X-axis screw rod (18) rotatably arranged on the X-axis fixed bearing seat (17) and an X-axis sliding block (19) sleeved on the X-axis screw rod (18) in a threaded manner, wherein the X-axis sliding block (19) is fixedly connected with the side face of the X-axis base (14).

5. The three-axis manual adjustment platform according to claim 4, wherein: and adjusting handwheels (7) are respectively arranged at the ends of the Z-axis screw rod (5), the Y-axis screw rod (12) and the X-axis screw rod (18).

6. The three-axis manual adjustment platform of claim 1, wherein: the X-axis sliding plate (16) is fixedly provided with a V-shaped positioning block (20) and a detachable L-shaped upper clamping block (21), one side of the V-shaped positioning block (20) opposite to the upper clamping block (21) is of a concave V-shaped structure, one side of the upper clamping block (21) opposite to the V-shaped positioning block (20) is of a concave arc-shaped structure, and the side edge and the bottom edge of the upper clamping block (21) are respectively provided with an installation through hole.

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