RU2751781C1 - Platform docking manipulator - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: invention relates to mechanical engineering, in particular to robotics, and can be used in automatic lines for assembling parts of units and assembling units. The platform docking manipulator has a support base, a movable platform and a self-aligning three-articulated platform. The support base and the movable platform are made in form of quadrangles, the tops of which are connected in pairs by four driven rod movable supports by means of crosses with perpendicularly located rotational kinematic pairs. The self-aligning three-articulated platform is kinematically connected to the movable platform by means of three intermediate rod movable supports and articulated joints.

EFFECT: simplification of the design and control of the manipulator, as well as increased accuracy and reliability.

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Description

The invention relates to platform manipulators of a parallel structure with an increased number of degrees of freedom and can be used in automatic lines for assembling assemblies and assembling units in docking devices of spacecraft, as well as in technologies where self-installation of the working body is required.

Known platform manipulator with three degrees of freedom of movement of the working body, containing a support base, pivotally connected through three multi-link parallelogram mechanisms with a movable platform of the working body - an analogue (Gavel, B. 1990. United States Patent No. 4.975, 582).

The disadvantages of the well-known platform manipulator are:

1. The complex design of the manipulator contains a large number of kinematic pairs for the movable connection of many links.

2. Limited working area due to only three degrees of freedom of the working body at the exit of the manipulator.

The closest in technical essence and the achieved effect to the proposed invention is a platform docking manipulator in the form of a Stewart platform, used as a docking device for spacecraft, containing a support base and a movable platform, hingedly connected to each other by means of six rod movable supports and 12 complex spherical hinges forming a closed kinematic chain with 6 drive motors - a prototype (book II Wolfson et al. "Mechanics of Machines", M: Higher School, 1996. P. 28, Fig. 1. 20 with the "Stewart Platform" ).

The disadvantages of this platform docking manipulator are:

1. Complex design due to the large number of drive motors, moving links and 12 complex spherical joints with high labor intensity of their manufacture and assembly (due to the need to intersect all axes of the inner and outer spherical surfaces at one point).

2. A complex control system that requires simultaneous dependent kinematics of all six drive motors to implement the movement of the working body in each given direction of movement.

The invention is based on a technical problem, which consists in simplifying the design, reducing the labor intensity of manufacturing and assembly, as well as simplifying the control system due to the separate kinematics of the drive motors when moving the working body in a given direction of movement.

Obtaining the technical result is achieved due to the fact that in the proposed platform docking VIP-manipulator containing a support base, a movable platform and rod movable supports installed between them as part of a closed multi-circuit kinematic chain, the support base and the movable platform are made in the form of two quadrangles, the vertices of which are connected in pairs by four driven rod movable supports by means of crosses with rotational kinematic pairs located perpendicularly to each other, and the manipulator is equipped with an additional mechanism of a self-aligning three-articulated platform, which is kinematically connected to the movable platform through three intermediate rod movable supports and articulated joints.

The essence of the invention is illustrated by drawings in Fig. 1, fig. 2, fig. 3, fig. 4 and FIG. five.

FIG. 1 shows a general view of a platform docking VIP-manipulator containing a support base 1 and a movable platform 2, made in the form of two four-link ABCD and EGNM, the tops of which are connected in pairs to each other in a closed circuit by four driven rod movable supports 3, 4, 5 and 6 by means of crosses 7 with perpendicularly spaced rotational kinematic pairs 8 and 9, and the manipulator is equipped with an additional mechanism of a self-aligning three-articulated platform 10, which is kinematically connected to the movable platform 2 through three intermediate rod movable supports 11, 12, 13 and articulated joints, for example, in the form rotary kinematic pairs with parallel axes of angular rotation. Rod driven movable supports 3, 4, 5 and 6 are equipped with linear motors, made, for example, in the form of movable drive hydraulic cylinders 14, 15, 16 and 17.

FIG. 2 shows a variant of the symmetrical assembly of the links of the mechanism of the self-aligning platform 10 with parallel axes of rotational kinematic pairs.

FIG. 3 shows a variant of a symmetrical assembly of a platform docking manipulator with the installation of intermediate rod supports 11, 12 and 13 of a self-aligning platform 10 parallel to each other in a horizontal plane when assembled with a movable platform 2.

FIG. 4 shows a variant of the symmetrical assembly of the links of the mechanism of the self-aligning platform 10 with the arrangement of parallel axes of rotation of all hinges in the horizontal plane.

FIG. 5 shows a variant of the symmetrical assembly of the links of the mechanism of the self-aligning platform 10 using two-movable kinematic connected, consisting of hinges with mutually perpendicular axes O ₁ O ₂ and O ₃ O _{4 of} their angular rotation.

FIG. 6 shows a variant of the symmetrical assembly of the links of the mechanism of the self-aligning platform 10 with the implementation of the articulated connection between the platforms 10 and 2 in the form of pairwise arranged on each of the three intermediate rod movable supports 11, 12, 13 in combination with a spherical hinge 0 ₅ installed at one end of each support, and a rotational kinematic pair 0 ₆ installed at the other end of each support.

The work of the presented platform docking VIP-manipulator is as follows.

With the separate supply of the working fluid to each of the driven movable hydraulic cylinders, a controlled change in the length of the driven movable rod supports 3 or 4 or 5 or 6 occurs, which provides separate kinematics of the movement of the movable platform along each of the four degrees of freedom of the manipulator, which is complemented by the fifth degree of freedom of the working body ( for example, in the form of a docking unit) due to the floating movement of the self-aligning platform 10. As a result, the required five degrees of freedom of movement of the working member of the manipulator are achieved by simple separate control of only four linear motors 14, 15, 16 and 17.

The positive effect achieved in the proposed platform docking VIP-manipulator is as follows:

1. The design is simplified and the control system of the manipulator with five degrees of freedom is simplified due to the separate kinematics of only four drive motors.

2. The accuracy and reliability of joining the objects assembled into a single unit is increased due to the additional floating degree of freedom of the mechanism of the self-aligning platform, which is determined by the configuration of the joined objects.

Claims (8)

1. A platform docking manipulator containing a support base and a movable platform, pivotally connected to each other by means of rod movable supports installed between them, forming a closed multi-circuit kinematic chain with the support base and the movable platform, characterized in that it is equipped with a self-aligning three-articulated platform, a support base and the movable platform is made in the form of quadrangles, the tops of which are connected in pairs by four driving rod movable supports by means of crosses with perpendicularly located rotational kinematic pairs, and the self-aligning three-articulated platform is kinematically connected to the movable platform by means of three intermediate rod movable supports and articulated joints. 2. The manipulator according to claim 1, characterized in that the articulated joints are made in the form of rotational kinematic pairs with parallel axes of angular rotation. 3. A manipulator according to claim 1, characterized in that the intermediate rod movable supports of the caster platform are made of the same length and are installed parallel to each other in the same direction to form a double hinged parallelogram with the caster platform. 4. The manipulator according to claim 1, characterized in that the intermediate rod movable supports of the self-aligning platform are installed parallel to each other in the horizontal plane in the assembly with the movable platform of the manipulator. 5. The manipulator according to claim 1, characterized in that the hinge joints are made in the form of two-movable kinematic joints, consisting of hinges with mutually perpendicular axes of their angular rotation. 6. The manipulator of claim. 1, characterized in that the pivot joints are made in the form of a spherical hinge located at one end of each of the intermediate rod movable supports, and a rotational kinematic pair located at the other end of each of the intermediate rod movable supports. 7. The manipulator according to claim 1, characterized in that the intermediate rod movable supports are made in the form of curved flexible plates, pivotally connected at the ends with a self-aligning platform on one side and with a movable platform on the other side. 8. The manipulator according to claim. 1, characterized in that the drive rod movable supports are equipped with linear motors, for example, in the form of movable drive hydraulic cylinders.

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