Modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure

Abstract

A modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure includes a plurality of folding units and a manipulator base. The modular design idea is adopted for the manipulator; which is formed by combining multiple folding units. the driving motors installed on each folding unit drive the folding units to stretch out, draw back and fold over, so that the manipulator can stretch out and draw back flexibly and bend in any direction to complete the work tasks in a variety of complex environments. For the manipulator, the flexible materials are added to the links of the folding units, and deformation can be effectively compensated, the mechanism is simplified, and impact is relieved. The torsional spring is additionally arranged in the folding units to play a supporting role, so that the manipulator can be placed in forward or in inverted direction to match with various bases. The angle sensor is fixedly connected to the rotating pair formed by the chassis and the folding unit, and the rotating speed of the manipulator is monitored to avoid large impact or damage.

Claims

1. Modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure comprising: a plurality of telescopic folding units (1) and a base (2); a manipulator with plurality telescopic folding units (1) is arranged on the base (2); wherein: the folding unit (1) includes chassis (1-7) and six groups of links in the middle, and the six groups of links are respectively link group I (1-1), link group II (1-2), link group III (1-3), link group IV (1-4), link group V (1-5) and link group VI (1-6); connection of the six groups of links is as follows: link group I (1-1) and link group II (1-2) are connected through Hooke hinge 1 (1-8), link group I (1-3) and link group II (1-2) are connected through Hooke hinge 1 (1-8), link group IV (1-4) and link group III (1-3) are connected by Hook hinge 1 (1-8), link group V (1-5) and link group IV (1-4) are connected through Hook hinge 1 (1-8), link group VI (1-6) and link group V (1-5) are connected by Hooke hinge 1 (1-8), link group I (1-1) and link group VI (1-6) are connected by Hooke hinge 1 (1-8); link group I (1-1), link group III (1-3) and link group V (1-5) have the same structure, and link group II (1-2), link group IV (1-4) and link group VI (1-6) have the same structure; the structure of link group I (1-1) and link group II (1-2) and their connection relationship are as follows: link group I (1-1) includes: lower link 1 (1-1-2), angle sensor (1-1-1), upper link (1-1-5), intermediate link 1 (1-1-7), intermediate link 2 (1-1-4), torsion spring (1-1-8); the connection relationship of link group I (1-1) is: lower link 1 (1-1-2) is connected with the chassis (1-7) to forms a rotating pair, and the angle sensor (1-1-1) is fixedly connected with the shaft of the lower link 1 (1-1-2) to monitor the rotation speed of lower link 1 (1-1-2); the upper link (1-1-5) and the chassis (1-7) forms a rotating pair, the angle sensor (1-1-1) fixedly connected with the rotating shaft of upper link (1-1-5) to monitor the rotation speed of the upper link (1-1-5); the lower link 1 (1-1-2) and the upper link (1-1-5) forms a rotating pair, and the torsion spring (1-1-8) is fixed on the shaft of the upper link (1-1-5) to support the folding unit; the intermediate link 1 (1-1-7) connects with the upper link (1-1-5) through the hook hinge 3 (1-1-6); the lower link 1 (1-1-2) connects with the intermediate link 2 (1-1-4) through the Hooke hinge 2 (1-1-3) connected; link group II (1-2) includes lower link 2 (1-2-2), intermediate link 2 (1-1-4), upper link (1-1-5), intermediate link 1 (1-1-7), driving gear (1-2-6), driven gear (1-2-5), motor (1-2-1) and angle sensor (1-1-1); connection relationship of link group II (1-2) is as follows: the lower link 2 (1-2-2) and the chassis (1-7) forms a rotating pair; the motor (1-2-1) is fixed on the chassis (1-7), the rotating shaft of the motor is fixedly connected with the driving gear (1-2-6), and the driven gear (1-2-5) is fixedly connected with the rotating shaft of the lower link 2 (1-2-2), motion and power is transmitted through the meshing of the two gears; the upper link (1-1-5) and the chassis (1-7) forms a rotating pair. The angle sensor (1-1-1) is fixedly connected to the rotating shaft of the upper link (1-1-5) to monitor the rotation speed of the upper link (1-1-5); the lower link 2 (1-2-2) and the upper link (1-1-5) forms a rotating pair; the intermediate link 1 (1-1-7) is connected with the upper link (1-1-5) through the Hook hinge 5 (1-2-4); the intermediate link 2 (1-1-4) is connected with the lower link 2 (1-2-2) through the Hook hinge 4 (1-2-3); the link (1-2-1) includes a rigid part (1-2-1-2) and a flexible material part (1-2-1-1) near the end of the rotating shaft. The flexible material is used to compensate for deformation and simplify the mechanism; link (1-1-5) includes a rigid part (1-1-5-2) and a flexible material part (1-1-5-1) near the end of the rotating shaft; the flexible material also plays the role of compensating for deformation and simplifying the mechanism.

2. The modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure according to claim 1, wherein the manipulator can be folded in multiple directions, adapt to different environments and works in small and irregular spaces.

3. The modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure according to claim 1, wherein the folding units used in the manipulator can be stacked or reduced as required to adjust the length of the manipulator.

4. The modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure according to claim 1, wherein flexible material is added to the link of the folding unit.

5. The modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure according to claim 1, wherein the manipulator has multi-degree-of-freedom, and its movement is controlled by three motors of the lower chassis of each folding unit.

6. The modular multi-hinge retractable rigid-flexible coupling space manipulator based on origami structure according to claim 1, wherein the folding unit of the manipulator is provided with a torsion spring on the link, which plays a supporting role, the manipulator can be placed forward and inverted to match with a variety of bases; each folding unit of the manipulator is connected by bolts (3-2) and nuts (3-2); the manipulator can fit a variety of bases including forward base (2-1) and inverted base (2-2); manipulator and base are connected by screws (3-1).

Description

DESCRIPTION OF DRAWINGS

[0023] FIG. 1 is the general schematic diagram of folding unit of the present invention;

[0024] FIG. 2 is a schematic diagram of the connection of two sets of links group of the present invention;

[0025] FIG. 3 is a schematic diagram of the structure of a group of links of the present invention;

[0026] FIG. 4 is a schematic diagram of the structure of another group of links in the present invention;

[0027] FIG. 5 is the schematic diagrams of links with flexible materials in the folding unit of the present invention;

[0028] FIG. 6 is the schematic diagrams of links with flexible materials in the folding unit of the present invention;

[0029] FIG. 7 is the schematic diagram of the link of the folding unit of the present invention;

[0030] FIG. 8 is the schematic diagram of the link of the folding unit of the present invention;

[0031] FIG. 9 is the schematic diagram of the link of the folding unit of the present invention;

[0032] FIG. 10 is a schematic diagram of the chassis of the folding unit of the present invention;

[0033] FIG. 11 is the compression diagram of the folding unit of the present invention;

[0034] FIG. 12 is the folding diagram of folding unit of the present invention;

[0035] FIG. 13 is the schematic diagram of the manipulator of the present invention;

[0036] FIG. 14 is the application scenarios of the manipulator of the present invention;

[0037] FIG. 15 is the application scenarios of the manipulator of the present invention.

[0038] Wherein, 1—folding unit; 2—manipulator base; 1-1 link group I; 1-2 link group II; 1-3 link group III; 1-4 link group IV; 1-5 link group V; 1-6 link group VI; 1-7 chassis; 1-8 Hook hinge 1; 2-1 forward base; 2-2 inverted base; 3-1 screw; 3-2 bolt; 3-3 side opening narrow space environment; 3-4 upper opening narrow space environment; 1-1-1 angle sensor; 1-1-2 lower link 1; 1-1-3 Hook hinge 2; 1-1-4 intermediate link 2; 1-1-5 upper link; 1-1-6 Hook hinge 3; 1-1-7 intermediate link 1; 1-1-8 torsion spring; 1-2-1 motor; 1-2-2 lower link 2; 1-2-3 Hook hinge 4; 1-2-4 Hook hinge 5; 1-2-5 driven gear; 1-2-6 driving gear; 1-2-1-1 flexible material part of the lower link 2; 1-2-1-2 rigid part of the lower link 2; 1-5-1 flexible material part of the upper link; 1-1-5-2 the rigid part of the upper link.

PREFERRED EMBODIMENTS

[0039] The present invention will be described below with reference to the accompanying drawings and embodiments, but the present invention is not limited to the following embodiments.

Embodiment 1

[0040] Referring to FIG. 1 and FIG. 13, the present invention disclosed a modular multi-hinge rigid-flexible coupling manipulator with multi-degree-of-freedom based on an origami structure. It is composed of a plurality of telescopic folding units (1) and a base (2).

[0041] Referring to FIG. 2, FIG. 11 and FIG. 12, the folding unit (1) of the manipulator can flexibly realize the extension and turning by adjusting the rotational speed or rotation angle of the drive motor (1-2-1).

[0042] Referring to FIG. 13, FIG. 14 and FIG. 15, plurality of folding units are fixed through the screw holes on the chassis with bolts (3-3) and nuts (3-2). Manipulator and base are connected by screws (3-1).

[0043] The manipulator works in a narrow environment, and an appropriate number of folding units (1) are connected to it. Driven by multiple drive motors (1-2-1), the manipulator can be bent in any direction. Therefore, it can be easily extended into small gaps and holes in any direction and stretched to its designated position for work.