CN204414132U - A kind of flexible joint of stiffness variable - Google Patents

Abstract

The utility model discloses a kind of flexible joint of stiffness variable, comprise passive stiffness-shift mechanism and active flexible driving mechanism, it is characterized in that described passive stiffness-shift mechanism mainly comprises: joint output panel, joint first driving-disc, joint second driving-disc, first, second cam set and first, second cam set mount pad, optical axis and supporting seat thereof, the mounting disc of tune rigidity, linear bearing and spring, described joint first driving-disc is fixedly connected with joint second driving-disc; Joint second driving-disc and joint output panel have the cam path of same profile line, and this outline line can realize joint equivalent stiffness changes with flexibility of joint deformation angle, first, second cam set cam contacts with the second driving-disc, joint output panel simultaneously; Described active flexible driving mechanism mainly comprises: trapezoidal screw, leading screw supporting seat, feed screw nut, leading screw bearing, DC servo motor, motor mount, shaft coupling, variation rigidity adjusting seat, linear bearing and spring.

Description

A kind of flexible joint of stiffness variable

Technical field

The utility model relates to Robotics, is specially a kind of flexible joint of stiffness variable.

Background technology

Revolute robot is according to bionics principle design, and structure is simple, and flexibly movable, in various complex environment, worksheet reveals very strong adaptability, has been widely used in the fields such as industrial production, scientific research exploration, earthquake relief work.Cradle head is the most important part of robot, has great significance to the normal work of robot and stability, reliability, precision etc.Can operate steadily in the joint of conventional rigid robot in known environment, but under circumstances not known or fortuitous event, be very easy to be subject to impact and cause personnel or self-inflicted injury, particularly robot and human lives more and more closer, want to make robot universal in mankind's daily life, what preecedence requirement solved is exactly the poor stability in rigidity joint, the problem that adaptive capacity is not strong.

Passed through bionics Study in recent years; it is found that the muscle-tendon tissue in nature animal possesses compliant characteristic; not only can reduce the impulsive force that bone is subject to; protection ontological security; and flexible output can store portion of energy to apply in next action for animal; such as, in the kinergety circulation of mechanical energy for next step that canid muscle-tendon when running can store 35%.Meanwhile, for adapting to different situations, animal can adjust the rigidity of muscle-tendon tissue, improves kinetic stability and energy-optimised characteristic.

According to this principle, a scholar Pratt of the Massachusetts Institute of Technology, is applied to series elastic driver (Series Elastic Actuator, SEA) in the driving of walking robot first.Elastic element series after rigid driver, is reached by detecting the distortion of flexible member the object that power accurately exports by series elastic driver.

The existing flexible joint based on series driver, the realization that most or concern exports with flexibility, and complex structure, flexibility of joint deformation angle is limited, a kind of series elastic driver of drum type brake disclosed in CN102211622A patent, complex structure, and can only rectilinear motion be produced, rigidity is non-adjustable, is unfavorable for being applied on articulated robot; And for example anthropomorphic robot disclosed in CN101934525B patent has the design of stiffness variable flexible joint, although achieve the object that active variable stiffness exports, but same structure is complicated, and drive dependence flexible cable, can not adapt to rapid movement and percussion, the popularity be applied on various revolute robot is restricted.

Utility model content

For the deficiencies in the prior art, the technical problem that the utility model quasi-solution is determined is, provides a kind of flexible joint of stiffness variable.This flexible joint can not only realize soft drive and export, reduce to impact, rub, extend robot service life, improve robot safety, joint stiffness can be realized increase with flexibility of joint deformation angle and increase simultaneously, improve Robot Robust and operation stability, and drive active accommodation joint stiffness by self, better adapt to different external environment or different operating task.

The technical scheme that the utility model solve the technical problem is: the flexible joint designing a kind of stiffness variable, comprise passive stiffness-shift mechanism and active flexible driving mechanism, it is characterized in that described passive stiffness-shift mechanism mainly comprises: joint output panel, joint first driving-disc, joint second driving-disc, the first cam set, the second cam set, the first cam set mount pad, the second cam set mount pad, optical axis, optical axis supporting seat, the mounting disc of tune rigidity, linear bearing and spring, described joint first driving-disc is fixedly connected with joint second driving-disc; Described joint second driving-disc and joint output panel are processed with the cam path of same profile line, and this outline line can realize joint equivalent stiffness changes with flexibility of joint deformation angle, cam groove profile line is symmetrical about axle center; Described joint output panel is arranged on by thrust bearing, rolling bearing on the axle of the first driving-disc, can opposed articulation second drive shaft turns;

Described first cam set, the second cam set cam contact with the second driving-disc, joint output panel simultaneously, and contact with cam path outer contour all the time; Described first cam set and the second cam set respectively correspondence are fixed on the first cam set mount pad and the second cam set mount pad, described first cam set mount pad and the second cam set mount pad are fixed on optical axis respectively by linear bearing, enable cam set along optical axis translation; Described optical axis is fixed on by optical axis supporting seat to be adjusted in rigidity mounting disc, adjusts rigidity mounting disc to be arranged on the first driving-disc axle by thrust bearing and rolling bearing, and can around the axis rotation of the first driving-disc;

Described active flexible driving mechanism mainly comprises: trapezoidal screw, leading screw supporting seat, feed screw nut, leading screw bearing, DC servo motor, motor mount, shaft coupling, variation rigidity adjusting seat, linear bearing and Compress Spring, described DC servo motor is arranged on motor mount, and motor mount and the first cam set mount pad are fixed; Described trapezoidal screw is arranged in the first cam set mount pad by leading screw supporting seat, leading screw bearing, and DC servo motor is connected with trapezoidal screw by shaft coupling, drives trapezoidal screw to rotate; Described feed screw nut is fixed in variation rigidity adjusting seat, and variation rigidity adjusting seat is fixed on optical axis by two linear bearings, and DC servo motor drives trapezoidal screw to rotate, the distance between adjustment variation rigidity adjusting seat and the first cam set mount pad; Described Compress Spring is installed between variation rigidity adjusting seat and the second cam set mount pad.

Compared with prior art, the flexible joint of the utility model design has following innovative point:

1, the flexible joint of stiffness variable combines cam mechanism and screw-nut body dexterously, can realize passive stiffness-shift and the active variable stiffness in joint simultaneously;

2, the flexible joint volume compact of stiffness variable, all main passive stiffness-shift structures concentrate in joint configuration, are easy to Integrated predict model in all kinds of revolute robot;

3, the flexible joint system of stiffness variable is provided with spring, and the flexibility achieving driving force exports, more safe and reliable, causes personnel or robot body damage under preventing the fortuitous events such as impact, collision;

4, the flexible joint of stiffness variable is by DC servo motor active accommodation joint elasticity rigidity, makes robot can adapt to different external environments and work requirements, increases the range of application of revolute robot;

5, the flexible joint of the utility model design adopts cam-cam path mechanism to amplify spring force, reduce spring volume, screw-nut body is adopted to amplify DC servo motor output torque, with a low power DC servo motor, export and connect feed screw nut, carry out regulating spring decrement, reduce the power demand of DC servo motor.

The utility model flexible joint is suitable for the key position of the revolute robot such as various anthropomorphic robot arm joint, legged type robot leg joint, for the application of soft drive in articulated robot is laid a good foundation, has application prospect very widely.

Accompanying drawing explanation

Fig. 1 is the perspective view of a kind of embodiment of flexible joint of the utility model stiffness variable;

Fig. 2 is that the flexibility output of a kind of embodiment of flexible joint of the utility model stiffness variable realizes principle key diagram; Wherein,

Fig. 2-1 is the flexible joint inactive state structural representation of the utility model stiffness variable;

Fig. 2-2 is the flexible joint generation plastic deformation status architecture schematic diagram of the utility model stiffness variable;

Fig. 3 is the active flexible driving mechanism sectional structure schematic diagram of a kind of embodiment of flexible joint of the utility model stiffness variable;

Fig. 4 is the overall cross-sectional view of a kind of embodiment of flexible joint of the utility model stiffness variable.

Wherein,

Fig. 4-1 is that the ladder of a kind of embodiment of flexible joint of the utility model stiffness variable cuts open Facad structure schematic diagram;

Fig. 4-2 is the side structure schematic diagram of a kind of embodiment of flexible joint of the utility model stiffness variable;

Fig. 5 is the cross-sectional view of a kind of embodiment of flexible joint along axis of the utility model stiffness variable.

In figure: 1 joint output panel, 11 output panel cam paths, 2 joint first driving-discs, 21 first driving-disc cam paths, 3 joint second driving-discs, 4 articular branches support plates, 31 first cam set, 31 ' second cam set, 32 supports end cap, 33 optical axises, 34 optical axis supporting seats, 35 DC servo motors, 36 leading screw supporting seats, 37 first cam set mount pads, 38 feed screw nuts, 39 variation rigidity adjusting seats, 310 motor mounts, 311 second cam set mount pads, 312 linear bearings, 313 adjust rigidity mounting disc, 314 Compress Springs, 315 shaft couplings, 316 leading screw bearings, 317 trapezoidal screws, 41 first thrust bearings, 42 first rolling bearings, 43 second rolling bearing 44 second thrust bearings.

Detailed description of the invention

The utility model is described further below in conjunction with embodiment and accompanying drawing thereof.But the claims of the application is not limited to the description scope of described embodiment.

The flexible joint of a kind of stiffness variable of the utility model design (is called for short flexible joint, see Fig. 1-5), comprise passive stiffness-shift mechanism and active flexible driving mechanism, it is characterized in that described passive stiffness-shift mechanism mainly comprises: joint output panel 1, joint first driving-disc 2, joint second driving-disc 3, first cam set 31, second cam set 31 ', first cam set mount pad 37, second cam set mount pad 311, optical axis 33, optical axis supporting seat 34, adjust rigidity mounting disc 313, linear bearing 312 and Compress Spring 314, described joint first driving-disc 2 is fixedly connected with joint second driving-disc 3, described joint second driving-disc 3 and joint output panel 1 are processed with output panel cam path 11 and the first driving-disc cam path 21 of same profile line, and this outline line can realize joint equivalent stiffness changes with flexibility of joint deformation angle, cam groove profile line is symmetrical about axle center, described joint output panel 1 is arranged on the axle of the first driving-disc 2 by thrust bearing 41, rolling bearing 42, can rotate by opposed articulation second driving-disc 3,

Described first cam set 31, second cam set 31 ' cam contacts with the second driving-disc 3, joint output panel 1 simultaneously, and contacts with cam path outer contour all the time; Described first cam set 31 and the second cam set 31 ' respectively correspondence are fixed on the first cam set mount pad 37 and the second cam set mount pad 311, described first cam set mount pad 37 and the second cam set mount pad 311 are fixed on optical axis 33 respectively by linear bearing 312, make the first cam set 31, second cam set 31 ' can along optical axis 33 translation; Described optical axis 33 is fixed on by optical axis supporting seat 32 to be adjusted in rigidity mounting disc 313, adjusts rigidity mounting disc 313 to be arranged on the first driving-disc 2 axle by thrust bearing 44 and rolling bearing 43, and can around the axis rotation of the first driving-disc 2;

Described active flexible driving mechanism mainly comprises: trapezoidal screw 317, leading screw supporting seat 36, feed screw nut 38, leading screw bearing 316, DC servo motor 35, motor mount 310, shaft coupling 315, variation rigidity adjusting seat 39, linear bearing 312 and Compress Spring 314, described DC servo motor 35 is arranged on motor mount 310, and motor mount 310 and the first cam set mount pad 37 are fixed; Described trapezoidal screw 317 is arranged in the first cam set mount pad 37 by leading screw supporting seat 36, leading screw bearing 316, and DC servo motor 35 is connected with trapezoidal screw 317 by shaft coupling 315, drives trapezoidal screw 317 to rotate; Described feed screw nut 38 is fixed in variation rigidity adjusting seat 39, variation rigidity adjusting seat 39 is fixed on optical axis 33 by two linear bearings 312, DC servo motor 35 drives trapezoidal screw 317 to rotate, the distance between adjustment variation rigidity adjusting seat 39 and the first cam set mount pad 37; Described Compress Spring 314 is installed between variation rigidity adjusting seat 39 and the second cam set mount pad 311.

The operation principle design of the utility model flexible joint Main Basis cam mechanism, mainly comprises joint first driving-disc 2, joint second driving-disc 3, optical axis 33, joint output panel 1 and soft drive part; Joint first driving-disc 2 flange is connected with joint driver, be generally decelerator to export, first driving-disc 2 and the second driving-disc 3 are connected and fixed by screw, joint output panel 1 and the first driving-disc 2 are processed with output panel cam path 11 and the first driving-disc cam path 21 of same profile line, limit it by the first cam set 31, second cam set 31 ' and Compress Spring 314 between two dishes to relatively rotate, cam contacts with joint second driving-disc 3, joint output panel 1 simultaneously.

It is (see Fig. 2) that the flexible joint of the utility model stiffness variable realizes the flexible principle exported of variation rigidity, when joint second driving-disc 3 relatively rotates with joint output panel 1, i.e. joint elasticity distortion, cam path on two dishes relatively rotates, extrude two cam set 31,31 ', the distance L between two cam set is reduced, compressing by spring 314 is the flexible drive mechanism of flexible member, hinder joint second driving-disc 3 and joint output panel 1 to relatively rotate, the flexibility realizing joint exports; The cam groove profile line of design not rounded, make spring with the increase of two dish relative rotations, decrement is pushed the speed and is accelerated, make two dish relative rotation increments and amount of spring compression increment ratio in the trend reduced gradually (see in Fig. 2,3 and 1 relatively rotates when there is plastic deformation, cam path extruding cam, two groups of cam spacing L are reduced, different cam groove profile lines, " 3 from 1 in relative rotation angle step " are different with " variable quantity of spacing L " relation, if angle increase once, amount of spring compression had been changed to a constant, be then determine rigidity; If along with the increase of deformation angle, amount of spring compression is pushed the speed and is accelerated), namely achieve plastic deformation larger, the flexible joint passive stiffness-shift rule that elastic stiffness is larger.

Soft drive part body (see Fig. 3,4) designed by the utility model, mainly comprises and adjusts rigidity mounting disc 313, optical axis bearing 34, optical axis 33, first driving-disc 2, first cam set mount pad 37, first cam set 31, linear bearing 312, leading screw supporting seat 36, motor mount 310, DC servo motor 35, leading screw bearing 316, trapezoidal screw 317, DC servo motor 35, second cam set mount pad 311, second cam set 31 ', variation rigidity adjusting seat 39, Compress Spring 314.Adjust rigidity mounting disc 313, optical axis bearing 34, optical axis 33 to be screwed composition soft drive part mounting-fixing base, adjust rigidity mounting disc 313 to be installed on the first driving-disc 2 by rolling bearing, thrust bearing, can rotate relative to the first driving-disc 2; Optical axis is provided with the mechanism that three parts can be slided arbitrarily along optical axis: the first cam set mount pad 37 fixes the first cam set 31, and be arranged on optical axis 33 by two linear bearings 312, first cam set mount pad 37 is fixed with leading screw supporting seat 36, motor mount 310, DC servo motor 35, leading screw bearing 316 simultaneously, wherein be fixed with trapezoidal screw 317 between leading screw bearing 316 and leading screw supporting seat 36, trapezoidal screw 317 one end is connected with DC servo motor 35 by shaft coupling 315; Second cam set mount pad 311 fixes the second cam set 31 ', and is arranged on optical axis 33 by two linear bearings 312; Variation rigidity adjusting seat 39 is arranged on optical axis by two linear bearings 312, is fixed with feed screw nut 38 simultaneously, makes variation rigidity adjusting seat 39 under leading screw drives, can adjust the distance apart from the first cam set holder 37; Two Compress Springs 314 are arranged between variation rigidity adjusting seat 39 and the second cam set mount pad 311, and axis overlaps with optical axis 33; DC servo motor 35 rotates and drives the translation of variation rigidity adjusting seat 39, changes spring pre compressed magnitude, realizes active variable stiffness.

The utility model variation rigidity flexible joint section in the axial direction, see Fig. 5, mainly comprises second joint driving-disc 3, first rolling bearing 42, first thrust bearing 41, joint output shaft 1, adjusts rigidity mounting disc 313, supports end cap 32, articular branches support plate 4, second rolling bearing 43, second thrust bearing 44, joint first driving-disc 2; With second joint driving-disc 3 for axle, by the first rolling bearing 42, first thrust bearing 41, joint output shaft 1 be installed and adjust rigidity mounting disc 313, adjust rigidity mounting disc 313 and supports end cap 32 to be screwed to be integrated, supports end cap 32 is connected by the second rolling bearing 43, second thrust bearing 44 with articular branches support plate 4; Articular branches support plate 4 and joint upper limbs are fixed, and joint first driving-disc 2 exports with joint upper limbs actuate actuators and is connected, and joint axial restraint is fixed by upper limbs.

The flexible joint major parameter of the utility model embodiment Preliminary design is: overall dimension is diameter 160mm, high 50mm, plastic deformation maximum angle is 30 °, and cam path is designed to eccentric elliptic shape, and joint maximum flexibility exports as 70Nm, the first driving-disc diameter of axle is designed to 20mm, cam set selects industrial camshaft bearing follower, cam diameter 16mm, and camshaft bearing follower stiff end is external screw thread bolt, facilitate cam set mount pad to fix, intensity is reliable.DC servo motor external diameter 22mm, maximum rated torque 15mNm, join diameter 22mm planet wheel decelerator speed reducing ratio 1:100, decelerator maximum output torque is 1.2Nm, and trapezoidal screw elects 14mm, 30 degree of trapezoidal screws as, and leading screw is maximum allows that thrust is 3kN, Compress Spring selects the rectangle grinding tool spring of external diameter 27mm Inner footpath 13.5mm, spring free length 120mm, coefficient of elasticity is 70N/mm, and spring fitting pre compressed magnitude is 10mm.

In the knee joint that the utility model flexible joint can be applicable to bionical quadruped robot or hip joint, significantly improve the performance of knee joint or hip joint, significantly reduce installation volume.The embodiment main design parameters of the knee joint or hip joint of installing the utility model flexible joint is: apolegamy AC servo motor 400W, max. output torque is 1.27Nm, apolegamy 1:120 harmonic speed reducer, reducer output flange is directly connected with joint first driving-disc, and decelerator input is connected with AC servo motor by Timing Belt; Wherein AC servo motor 2kg, harmonic speed reducer 1.5kg, one leg quality is roughly about 12kg, and robot body quality is 20kg; When joint maximum output torque, can ensure that quadruped robot is advanced with diagonal gait.

The utility model is not addressed part and is applicable to prior art.

Claims (2)

1. the flexible joint of a stiffness variable, comprise passive stiffness-shift mechanism and active flexible driving mechanism, it is characterized in that described passive stiffness-shift mechanism mainly comprises: joint output panel, joint first driving-disc, joint second driving-disc, the first cam set, the second cam set, the first cam set mount pad, the second cam set mount pad, optical axis, optical axis supporting seat, the mounting disc of tune rigidity, linear bearing and spring, described joint first driving-disc is fixedly connected with joint second driving-disc; Described joint second driving-disc and joint output panel are processed with the cam path of same profile line, and this outline line can realize joint equivalent stiffness changes with flexibility of joint deformation angle, cam groove profile line is symmetrical about axle center; Described joint output panel is arranged on by thrust bearing, rolling bearing on the axle of the first driving-disc, can opposed articulation second drive shaft turns;

Described first cam set, the second cam set cam contact with the second driving-disc, joint output panel simultaneously, and contact with cam path outer contour all the time; Described first cam set and the second cam set respectively correspondence are fixed on the first cam set mount pad and the second cam set mount pad, described first cam set mount pad and the second cam set mount pad are fixed on optical axis respectively by linear bearing, enable cam set along optical axis translation; Described optical axis is fixed on by optical axis supporting seat to be adjusted in rigidity mounting disc, adjusts rigidity mounting disc to be arranged on the first driving-disc axle by thrust bearing and rolling bearing, and can around the axis rotation of the first driving-disc;

Described active flexible driving mechanism mainly comprises: trapezoidal screw, leading screw supporting seat, feed screw nut, leading screw bearing, DC servo motor, motor mount, shaft coupling, variation rigidity adjusting seat, linear bearing and Compress Spring, described DC servo motor is arranged on motor mount, and motor mount and the first cam set mount pad are fixed; Described trapezoidal screw is arranged in the first cam set mount pad by leading screw supporting seat, leading screw bearing, and DC servo motor is connected with trapezoidal screw by shaft coupling, drives trapezoidal screw to rotate; Described feed screw nut is fixed in variation rigidity adjusting seat, and variation rigidity adjusting seat is fixed on optical axis by two linear bearings, and DC servo motor drives trapezoidal screw to rotate, the distance between adjustment variation rigidity adjusting seat and the first cam set mount pad; Described Compress Spring is installed between variation rigidity adjusting seat and the second cam set mount pad.

2. the flexible joint of stiffness variable according to claim 1, it is characterized in that this flexible joint major parameter is: overall dimension diameter 160mm, high 50mm, plastic deformation maximum angle is 30 °, cam path is designed to eccentric elliptic shape, joint maximum flexibility exports as 70Nm, the first driving-disc diameter of axle is designed to 20mm, cam set selects industrial camshaft bearing follower, cam diameter 16mm, camshaft bearing follower stiff end is external screw thread bolt, DC servo motor external diameter 22mm, maximum rated torque 15mNm, join diameter 22mm planet wheel decelerator speed reducing ratio 1:100, decelerator maximum output torque is 1.2Nm, trapezoidal screw elects 14mm as, 30 degree of trapezoidal screws, leading screw is maximum allows that thrust is 3kN, Compress Spring selects external diameter 27mm, the rectangle grinding tool spring of Inner footpath 13.5mm, spring free length 120mm, coefficient of elasticity is 70N/mm, spring fitting pre compressed magnitude is 10mm.