阅读说明：本技术 利用高精度丝杆实现精密圆弧转动的机构 (Mechanism for realizing precise circular arc rotation by utilizing high-precision lead screw ) 是由 谢小浩 管维柱 樊毅 彭杰 刘二语 樊迪 于 2020-06-10 设计创作，主要内容包括：本发明公开了一种利用高精度丝杆实现精密圆弧转动的机构,包括部件、传动件和丝杆,部件能够沿中心轴转动,传动件滑动安装在部件上并与丝杆的螺母转动连接,且传动件的滑动方向与丝杆呈夹角；当丝杆转动时,带动螺母沿丝杆直线运动,螺母带动传动件在部件上滑动的同时带动部件沿中心轴转动,从而实现通过丝杆驱动部件转动。本发明的有益效果是：1、通过巧妙的传动装置,实现了利用丝杆驱动部件精密转动,从而大大提高了部件转动时的控制精度；2、力的损失小,传动效率高；3、能够用于任何需要精密控制转动角度的领域,尤其是需要远距离对准或校准的领域,使用范围广；4、结构稳定可靠,易于获得,成本低,适于工业成产。(The invention discloses a mechanism for realizing precise circular arc rotation by using a high-precision screw rod, which comprises a part, a transmission part and a screw rod, wherein the part can rotate along a central shaft; when the screw rod rotates, the nut is driven to move linearly along the screw rod, the nut drives the transmission piece to slide on the component and simultaneously drives the component to rotate along the central shaft, and therefore the component is driven to rotate through the screw rod. The invention has the beneficial effects that: 1. through a smart transmission device, the precise rotation of the part is driven by the lead screw, so that the control precision of the part in rotation is greatly improved; 2. the loss of force is small, and the transmission efficiency is high; 3. the device can be used in any field needing precise control of the rotation angle, especially the field needing remote alignment or calibration, and has wide application range; 4. stable and reliable structure, easy obtaining, low cost and being suitable for industrial production.)

1. The utility model provides an utilize high accuracy lead screw to realize accurate circular arc pivoted mechanism which characterized in that: the transmission mechanism comprises a component (1), a transmission piece (2) and a screw rod (3), wherein the component (1) can rotate along a central shaft, the transmission piece (2) is slidably mounted on the component (1) and is rotatably connected with a nut (301) of the screw rod (3), and the sliding direction of the transmission piece (2) forms an included angle with the screw rod (3);

when the screw rod (3) rotates, the nut (301) is driven to linearly move along the screw rod (3), the nut (301) drives the transmission piece (2) to slide on the component (1) and simultaneously drives the component (1) to rotate along the central shaft, and therefore the component (1) is driven to rotate through the screw rod (3).

2. The mechanism for realizing precise circular arc rotation by using the high-precision screw rod as claimed in claim 1, is characterized in that: the part (1) is arranged on an arc-shaped guide rail (6) of the base (5), the screw rod (3) is arranged on the base (5) and is positioned above the part (1), and the rotating plane of the part (1), the sliding plane between the transmission part (2) and the part (1) and the central axis of the screw rod (3) are parallel to each other.

3. The mechanism for realizing precise circular arc rotation by using the high-precision screw rod as claimed in claim 2, is characterized in that: arc guide rail (6), driving medium (2) and lead screw (3) all are close to the edge of part (1), just lead screw (3) are tangent with arc guide rail (6).

4. The mechanism for realizing precise circular arc rotation by using the high-precision screw rod as claimed in claim 1, is characterized in that: the nut (301) is provided with a connecting shaft (301a), the transmission piece (2) is provided with a mounting hole matched with the shaft hole of the connecting shaft (301a), and the nut (301) can be rotatably mounted in the mounting hole of the transmission piece (2) through the connecting shaft (301a) and is provided with a bearing.

5. The mechanism for realizing precise circular arc rotation by using the high-precision screw rod as claimed in claim 4, is characterized in that: the component (1) is provided with two parallel sliding rails (4), the mounting hole is located in the middle of the transmission piece (2), and two ends of the transmission piece (2) are respectively mounted on the corresponding sliding rails (4).

6. The mechanism for realizing precise circular arc rotation by using the high-precision screw rod as claimed in claim 1, is characterized in that: the screw rod (3) is a ball screw rod.

7. The mechanism for realizing precise circular arc rotation by using the high-precision screw rod as claimed in claim 1, is characterized in that: an equipment mounting seat (7) is arranged on the component (1).

Technical Field

The invention belongs to the field of transmission mechanisms, and particularly relates to a mechanism for realizing precise circular arc rotation by using a high-precision lead screw.

Background

The rotation of a certain part is usually directly driven by a motor, the driving mode has low precision and cannot meet the requirement of precise control of a rotation angle, and the ball screw is a precise instrument with high precision, reversibility and high efficiency, so how to drive the part by the ball screw so as to realize high-efficiency transmission and precise circular arc rotation, which is a problem which is not solved at present.

Disclosure of Invention

In view of the above technical problems, the present invention aims to provide a mechanism for realizing precise circular arc rotation by using a high-precision lead screw, which can realize high-efficiency transmission and precise circular arc rotation by using a lead screw driving part.

Therefore, the technical scheme adopted by the invention is as follows: a mechanism for realizing precise circular arc rotation by using a high-precision screw rod comprises a part, a transmission part and the screw rod, wherein the part can rotate along a central shaft, the transmission part is slidably mounted on the part and is rotationally connected with a nut of the screw rod, and the sliding direction of the transmission part forms an included angle with the screw rod;

when the screw rod rotates, the nut is driven to move linearly along the screw rod, the nut drives the transmission piece to slide on the component and simultaneously drives the component to rotate along the central shaft, and therefore the component is driven to rotate through the screw rod.

Preferably, the component is mounted on an arc-shaped guide rail of the base, the screw rod is arranged on the base and located above the component, and a rotating plane of the component, a sliding plane between the transmission part and the component, and a central axis of the screw rod are parallel to each other. By adopting the structure, the device is reasonable in arrangement, stable and reliable in mounting structure and beneficial to efficient force transmission.

Preferably, the arc-shaped guide rail, the transmission part and the screw rod are close to the edge of the part, and the screw rod is tangent to the arc-shaped guide rail. By adopting the structure, the arm of force is increased, the components are easier to rotate, the screw rod is tangent to the arc-shaped guide rail, the transmission efficiency is higher, and the force loss is reduced.

Preferably, the nut is provided with a connecting shaft, the transmission member is provided with a mounting hole matched with the shaft hole of the connecting shaft, and the nut is rotatably mounted in the mounting hole of the transmission member through the connecting shaft and is provided with a bearing. By adopting the structure, the mounting structure is stable and reliable, the friction force between the nut and the transmission part is reduced, and the transmission efficiency is improved.

Preferably, the component is provided with two parallel slide rails, the mounting hole is located in the middle of the transmission member, and two ends of the transmission member are respectively mounted on the corresponding slide rails. By adopting the structure, the transmission part slides smoothly and has small friction force.

Preferably, the screw is a ball screw. By adopting the structure, the roller screw rod has high precision and high efficiency.

Preferably, the component is provided with an equipment mounting seat. By adopting the structure, the equipment mounting base can be used for mounting equipment, so that the equipment can be calibrated, and the angle or the position can be accurately adjusted.

The invention has the beneficial effects that: 1. through a smart transmission device, the precise rotation of the part is driven by the lead screw, so that the control precision of the part in rotation is greatly improved; 2. the loss of force is small, and the transmission efficiency is high; 3. the device can be used in any field needing precise control of the rotation angle, especially the field needing remote alignment or calibration, and has wide application range; 4. stable and reliable structure, easy obtaining, low cost and being suitable for industrial production.

Drawings

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

FIG. 2 is a schematic structural view of a nut;

fig. 3 is a schematic view of a mounting structure of the ball hinge.

Detailed Description

The invention will be further illustrated by the following examples in conjunction with the accompanying drawings:

as shown in figure 1, the mechanism for realizing precise circular arc rotation by using the high-precision screw rod mainly comprises a component 1, a transmission piece 2, a screw rod 3, a slide rail 4, a base 5 and an arc-shaped guide rail 6.

As shown in fig. 1 and fig. 3, the component 1 is mounted on an arc-shaped guide rail 6 of the base 5 and can rotate along a central shaft, in this embodiment, the central shaft is a virtual shaft, the arc-shaped guide rail 6 is composed of two segments of branch guide rails arranged in bilateral symmetry, two ends of the component 1 are respectively mounted on the corresponding branch guide rails, a spherical hinge 10 is disposed at a rotation center of the component 1, a mounting shaft 9 for mounting the spherical hinge 10 is disposed on the base 5, a lower end of the mounting shaft 9 is fixed on the base 5, an upper end of the mounting shaft passes through a central hole of the component 1, an annular gap is formed between the component 1 and the mounting shaft 9, a ball head of the spherical hinge 10 is fixed at a top end of the mounting shaft 9, an outer cover 11 is disposed outside the spherical hinge 10, an upper end of the outer cover 11 is fixedly connected with a ball seat of the spherical hinge 10, a.

Furthermore, the component 1 is of a plate-shaped structure and serves as a platform, the device mounting seat 7 is arranged on the component 1, and the device mounting seat 7 is used for mounting devices needing to be accurately adjusted in angle or position, so that the application range of the mechanism is expanded.

As shown in fig. 1 and fig. 2, the screw rod 3 is disposed on the base 5 and located above the component 1, the transmission member 2 is slidably mounted on the component 1 and rotatably connected to the nut 301 of the screw rod 3, and the sliding direction of the transmission member 2 forms an included angle with the screw rod 3, in this embodiment, two parallel sliding rails 4 are disposed on the component 1, two ends of the transmission member 2 are respectively mounted on the corresponding sliding rails 4, the nut 301 is provided with a connecting shaft 301a, the middle portion of the transmission member 2 is provided with a mounting hole matched with the shaft hole of the connecting shaft 301a, and the nut 301 is rotatably mounted in the mounting hole of the transmission member 2 through the connecting shaft 301a and is equipped with a bearing. Further, lead screw 3 is the ball screw of high accuracy, and the rotation plane of part 1, the slip plane between driving medium 2 and the part 1, the axis three of lead screw 3 are parallel to each other, and arc guide 6, driving medium 2 and lead screw 3 all are close to the edge of part 1, and lead screw 3 is tangent with arc guide 6, effectively improves transmission efficiency, reduces the loss of power. When the screw rod 3 rotates, the nut 301 is driven to move linearly along the screw rod 3, the nut 301 drives the transmission piece 2 to slide on the component 1 and simultaneously drives the component 1 to rotate along the central shaft, and therefore the component 1 is driven to rotate through the screw rod 3. In the driving process, the resultant force received by the nut 301 is decomposed into three component forces, namely the rotating friction force between the nut 301 and the transmission piece 2, the sliding friction force for driving the transmission piece 2 to slide on the sliding rail 4 by the nut 301 and the driving force for driving the nut 301 to rotate through the driving part 1 of the transmission piece 2.