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US3901547A - Multiple prehension mechanism - Google Patents

️Tue Aug 26 1975

US3901547A - Multiple prehension mechanism - Google Patents

Multiple prehension mechanism Download PDF

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Publication number

US3901547A

US3901547A US448341A US44834174A US3901547A US 3901547 A US3901547 A US 3901547A US 448341 A US448341 A US 448341A US 44834174 A US44834174 A US 44834174A US 3901547 A US3901547 A US 3901547A Authority

United States

Prior art keywords

finger

base

tip

fingers

centerline

Prior art date

1973-05-14

Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Expired - Lifetime

Application number

US448341A

Inventor

Ii Frank R Skinner

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Individual

Original Assignee

Individual

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1973-05-14

Filing date

1974-03-05

Publication date

1975-08-26

1974-03-05 Application filed by Individual filed Critical Individual

1974-03-05 Priority to US448341A priority Critical patent/US3901547A/en

1975-08-26 Application granted granted Critical

1975-08-26 Publication of US3901547A publication Critical patent/US3901547A/en

1992-08-26 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

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Classifications

- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25J—MANIPULATORS; CHAMBERS PROVIDED WITH MANIPULATION DEVICES
- B25J15/00—Gripping heads and other end effectors
- B25J15/08—Gripping heads and other end effectors having finger members
- B25J15/10—Gripping heads and other end effectors having finger members with three or more finger members
- B25J15/103—Gripping heads and other end effectors having finger members with three or more finger members for gripping the object in three contact points
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S294/00—Handling: hand and hoist-line implements
- Y10S294/902—Gripping element

Definitions

ABSTRACT A multiple prehension mechanism including a base; a [52] j i l gf plurality of finger assemblies mounted on the base; l I I finger drive means for selectively opening and closing 294/1310 2 the fingers so that each finger moves in a single cur- [SI] Int. Cl H B25! 5/04 1 I d r d f l I Field of Search 214/] H 7 l mg ane, an posi ioning r ve means or se ec we y 5 2 positioning the finger assemblies so that different pre- H hensile modes can be achieved.
the disclosure also contemplates the method of operation of the mecha- [56] References Clted "ism.
the invention disclosed herein overcomes these and other problems associated with the prior art by provid ing a manipulator mechanism which has virtually all of the basic capabilities associated with the human hand.
the construction of the invention is relatively simple thereby reducing the manufacturing cost and maintenance cost.
the invention comprises generally a plurality of finger assemblies, each including a finger pivoted about at least one finger axis through a single plane normal to the finger axis, a base mounting the finger assemblies so that the plane of each finger can e rotated about a positioning axis through the plane and normal to the finger axes, finger drive means for pivoting the fingers about the respective finger axes, and positioning means for moving the finger assemblies so that at least two of the planes will be rotated about their respective positioning axes.
the finger drive means collectively pivots the fingers about their finger axis.
FIG. I is a perspective view of one embodiment of the invention.
FIG. 2 is an operating end view of the invention of FIG. 1;
FIG. 3 is a cross-sectional view taken along line 33 in FIG. 2 showing the finger assemblies in wrap-spread prehensile mode;
FIG. 4 is a cross-sectional view taken along line 4-4 in FIG. 3;
FIG. 5 is a side view illustrating a second embodi ment of the invention.
FIG. 6 is a longitudinal cross-sectional view of FIG. 5;
FIG. 7 is a cross-sectional view taken along line 77 in FIG. 5;
FIG. 7A is a cross-sectional view taken along line 7A7A in FIG. 5;
FIG. 8 is an enlarged side view of one of the tips of that embodiment of FIG. 5;
FIG. 9 is an edge view taken along line 9-9 in FIG.
FIG. 10 is a cross-sectional view taken along line 10-10 in FIG. 9;
FIGS. 11-18 illustrate the embodiment of FIG. 5 in operation.
the first embodiment of the manipulator is designated by the numeral 110.
the manipulator mechanism includes a base 1 l l, a plurality of finger assemblies 112 mounted on base 111, a firger driving mechanism 114 carried by the base 111, and a positioning mechanism 115 carried by base 111 for positioning the finger assemblies 112.
the manipulator mechanism is an assembly of drive and mechanisms intended for prehension. These mechanisms, called fingers, are attached to a base. Three fingers are considered necessary and sufficient in the construction of the manipulator. Fingers can approach, contact, or pass one another during prehensile operation.
the manipulator contains all of the drives below the palmar surface of base 111.
a multiple degree-of-freedom wrist mechanism (not shown) may be used to connect to and move the manipulator so that it can approach an object from any direction.
the objective of the manipulator mechanism is to produce a highly versatile hand with a minimum number of moving parts, a dependable drive system, and an optimum number of degrees of freedom.
the number of degrees of freedom is considered uptimum when it is estimated that the manipulator mechanism can grasp all of the basic geometrical shapes from any aspect with the minimum number of external control inputs. These basic shapes are rectangular and triangular prisms, spheres, and cylinders.
the human hand is generally accepted as being capable of the six basic prehensile patterns: lateral, hook, tip. palmar, spherical, and cylindrical. These six basic prehensile patterns, because of similarities, can be reduced to the three basic mechanical equivalents of wrap, three-jaw and tip prehension that very nearly duplicate the basic human hand prehensile patterns. Additionally, in order to grip large objects that the fingers can not surround, spread prehension is created which consists of inserting the fingers into an opening in the object and then bending them outward to engage the object within the opening. The manipulator mechanism 110 is able to generate all of the above four equivalent prehensile patterns.
the base 111 seen in FIGS. 1-4 includes generally a top palmar plate 121, which corresponds to the palm of the human hand, a base plate 122 and a plurality of spacer supports 124 which connect plates 121 and 122 so that they are generally parallel with palmar plate 12] providing a working surface 125.
Appropriate cutouts 126 are provided in palmar plate 121 for the finger assemblies 112 to operate as will become more apparent.
Three finger assemblies 112 designated 112,,1I2 are mounted between plates 121 and 122 at equally spaced points about the circle defined by radius R from the common centerline CL of plates 121 and 122.
Each assembly 112 includes a support arm 130 having a pair of spaced apart mounting ears 131.
the finger 134 is pivotally mounted between ears 131 through a base revolute joint 135 about a curl axis CA.
the arm 130 is attached to the back side of palmar plate 121.
the arm 130 of assemblies 112,, and 112 are connected to the plate 121 through revolute joint 136 so that the arm 130 pivots about a positioning axis PA which intersects the circle of radius R and is normal to the working sur face 125 of plate 121 whereas the curl axis CA is normal to axis PA and spaced outwardly therefrom a distance D.
the arm 130 of assembly 112 is fixed to the back of plate 121 so that it extends radially, however, the distance from the circle of radius R to axis CA is the distance D and the orientation of axis CA is like that described above for assemblies 112, and 112
the finger 134 is pivotal through a single curling plane CP as best seen in FIG.
the planes CP,, and CP of assemblies 112,, and 112 are pivoted about the positioning axis PA which is parallel to the curling plane CP.
the axis PA lies within the curling plane CP.
the fingers 134 may have multiple joints and links as fingers 34, however, those illustrated are single elongate members 140 pivoted at joint 135 and projecting out over the working surface 125 of plate 121.
a driving leg 141 is integral with member 130 and extends below arm 130 for use in driving finger 134 as will be explained. It will be noted that fingers 134 have a normal open position so that the longitudinal axis of finger 134 lies along a path P substantially perpendicular to working surface 125.
the finger 134 is designed to be double acting so that it can pivot both inwardly and outwardly from path P as will become more apparent.
Mechanism 114 includes a tubular drive rod 150 slidably journalled in base plate 122 for sliding movement along the centerline CL of base 111.
the operating end 151 of rod 150 projects into space 152 between plates 121 and 122 and its other end is connected to a drive unit 154 such as the fluid cylinder shown in FIG. 3.
a power adapter 155 is attached to the operating end 151 of rod 150 in space 152.
the outwardly extending power arms 156 156 are attached to adapter 155 so that they are aligned with the arm 130 each associated finger assembly 112,,112,..
a drive link 158 connects each arm 156 with its associated finger 134 so that as rod 150 moves adapter 155 and power arms 156 toward the back of palmar plate 121, the fingers 134 will be simultaneously closed and as rod 150 and adapter 155 moves toward base plate 122, the fingers 134 will be opened to their normal position. Further movement of rod 150 toward base plate 122 cause the fingers 134 to continue to spread outwardly past the paths P into the spread prehensile mode.
finger assem blies 112,, and l 12,. can be moved from a three-jaw prehcnsile mode shown in solid lines to a wrap prehensile mode shown in dashed lines. It will be noted that the spread prehensile mode can be achieved in either posi tion and that the tip prehensile mode could be easily provided for with very little modification. Stops 159 may be provided on plate 121 as seen in FIG. 4 to limit the movement of the finger assemblies about axes PA.
the mechanism includes a drive gear 160 on drive shaft 161 journalled for rotation about the centerline CL of base 111.
An appropriate power source 162 such as the motor shown in FIG. 3 is used to selectively rotate gear 160.
Shaft 161 passes through rod but is rotatable independently thereof.
gear 160 is rotated clockwise as seen in FIG. 9, the finger assemblies 112,, and 112,. will be simultaneously rotated toward the wrap mode position, and when gear 16 is rotated counterclockwise, assemblies 112,, and 112,. will be rotated toward their three' jaw mode position.
FIGS. 5-18 The second embodiment of the invention shown in FIGS. 5-18 is a refinement of the manipulator mechanism 110 and is designated generally 210 with finger assemblies 212 mounted on base 211 with finger driv ing mechanism 214 and positioning mechanism 215.
the base 211 seen in FIGS. 5-10 includes generally a top palmar plate 221, which corresponds to the palm of the human hand, a base plate 222 and a plurality of spacer supports 224 which connect plates 221 and 222 so that they are generally parallel with palmar plate 221 providing a working surface 225.
Appropriate cutouts 226 are provided in plates 221 and 222 for the finger assemblies 212 to operate as will become more appar ent.
Three finger assemblies 212 designated 212,,-212 are mounted between plates 221 and 222 at equally spaced points about the circle defined by radius R from the common centerline CL of plates 221 and 222 as seen in FIG. 7.
Each assembly 212 includes a support arm 230 having a pair of spaced apart mount ing ears 231.
the finger 234 is pivotally mounted between ears 231 through a base revolute joint 235 about a curl axis CA.
the arm 230 is attached to the back side of palmar plate 221. The arm 230 of assemblies 212,, and 212,.
each finger 234 is pivotal through a single curling plane (P about the curling axis CA perpendicular to the plane.
the planes CP,, and CP,. of assemblies 212,, and 212, are pivoted about the positioning axes PA which are parallel to the curling plane CP.
the axis PA lies within the curling plane CP.
the lingers 234 illustrated are single elongate members 240 pivoted at joint 235 and projecting out over the working surface 225 of plate 221.
a driving leg 241 is integral with member 240 and extends below arm 230 for use in driving finger 234 as will be explained.
fingers 234 have a normal open position so that the longitudinal axis of finger 234 lies along a path P substantially perpendicular to working surface 225.
the finger 234 is designed to be double acting so that it can pivot both inwardly and outwardly from path P as will become more apparent.
Each finger assembly 212 mounts a tip assembly 300 at the projecting end of member 240 as best seen in FIGS. 8-10.
Each tip assembly 300 includes a tip 301 and an initial positioner unit 302.
the projecting end 242 of member 240 defines a slot 244 therethrough oriented generally parallel to the curling plane C? of assembly 212.
the tip 301 is a generally rectilinear plate defining a Vshaped notch 304 at its inner and outer ends to define a pair of spaced apart contact points 305 at opposite ends of tip 301.
the points 305 define contact surfaces 307 thereon to engage the object to be grasped.
the tip 301 is pivoted at its center between the ears 245 in the end 242 of member 240 on opposite sides of slot 244 on a support pin 306 carried between ears 245.
the tip 301 is free to pivot about the axis TA of pin 305 within slot 244.
the initial positioner unit 302 serves to initially position tip 301 in a known pivotal position with respect to member 240 as will become more apparent. While different mechanisms may be used, the unit 302 illus- [rated includes a compression coil spring 310 and a plunger 3]]. An appropriate hole 246 is provided in the end 242 of member 240 at the bottom of slot 244 to slidably receive the spring 310 and plunger 31] therein, The hole 246 is located so that the spring 310 resiliently urges the tip 301 in a predetermined rotational direction, here shown as counterclockwise by the plunger 311 bearing against the tip 301. The rotational direction in which tip 301 is urged can easily be reversed simply by shifting the positioner unit 302 to the opposite side of the slot 244 as shown by dashed lines in FIG. 10.
Mechanism 314 includes a drive rod 250 slidably journalled in base plate 222 for sliding movement along the centerline CL of base 211.
the operating end 251 of rod 250 projects into space 252 between plates 221 and 222 and its other end is connected to a drive unit 254 such as the piston 255 of a double acting fluid cylinder 256 shown in FIG. 6.
a power adapter 258 is attached to the operating end 251 of rod 240 in space 252 so that adapter 258 can be reciprocated in space 252 along the centerline CL.
Adapter 258 includes a pair of spaced apart, generally circular, parallel carriage plates 259 joined at their cen tral portions by a boss 260 so that an annular arm mounting recess 26] is defined between plates 259.
Outwardly extending power arms 265 265, of finger drive linkages 263 are mounted within the annular recess 261 in alignment with support arms 230.
Each power arm 265 has a generally horizontal leg 266 and an upwardly and outwardly extending bifurcated leg 268.
Each leg 266 is slidably received between carriage plates 259 and is rotatably mounted on a pivot pin 269 extending between plates 259 about the positioning axes PA.
the leg 266 of positioning arm 265, is held in a fixed position in alignment with support arm 230,, by a second pin 270 extending through let 266 between carriage plates 259 as seen in FIGS, 6 and 7.
power arms 265,, and 265,. can pivot about axes PA while arm 265,, is held in a fixed position.
Drive links 271 connect each power arm 265 with the driving leg 241 of the finger 234 associated therewith so that fingers 234 will be driven open or closed as the power adapter 258 is moved within space 252 by drive unit 254.
Each link 271 has its outer end 272 pinned between the ends of bifurcated leg 268 of arm 265 while its bifurcated inner end 274 has the driving leg 24] of finger 234 pinned therebetween.
the mechanical advantage of the drive input to fingers 234 decreases as the fingers close. This is advantageous since the larger objects to be grasped by fingers 234 nonnally weigh more than smaller objects thereby requiring a greater holding force. Thus, a variation in holding force is provided without a change in the fluid pressure of cylinder 256.
the finger drive linkages 263 are slider crank mechanisms where the slider axis is parallel to the curling plane of the particular finger assembly 212 with which it is associated. This causes the movement of the linkage 263 to be coplanar with the curling plane of its associated finger assembly 212.
finger assemblies 212,, and 212,. can be moved from a three-jaw prehensile mode shown in dashed lines to a wrap prehen sile mode shown in solid lines. It will be noted that the spread prehensile mode can be achieved in either position and that the tip prehensile mode is provided in the three-jaw prehensile mode.
the positioning mechanism 215 is effective to position the assemblies 212,, and 212,. in their difi'erent modal positions.
the positioning mechanism 215 includes a pair of drive subassemblics 280 carried by the power arm 265 one of the sub-assemblies 280 is operatively connected to the power arm 265,, and one of the subassemblies 280 is operatively connected to power arm 265,
the subassemblies 280 are mirror images of each other so that only one subassembly will be described in detail while like reference numbers will be applied to the other assembly 280.
Subassembly 280 attached to power arm 265, includes a fluid cylinder 281 carried by a bracket 282 mounted on the side of the horizontal leg 266 of power arm 265
the cylinder 281 is positioned so that its centerline CL is generally parallel to the centerline of leg 266 of arm 265,, and generally parallel to the working surface 225 of palmar plate 221 and displaced laterally of leg 266 of arm 265,, a distance d,.
the piston rod 285 of cylinder 280 has its projecting end connected to the leg 266 of power arm 265,, through a connector 286.
One end of connector 286 is pinned to the projecting end of piston rod 285 and its other end is pinned to the leg 266 of arm 265,, in a slot 288 formed in the side of leg 266 by a drive pin 289.
Pin 289 is located from the positioning axis PA of arm 265,, a distance d
the positioning arm 265,, and finger assembly 212 will be pivoted toward their wrap modal position and toward their three-jaw modal position.
the distance d, and 41- are sufficient to insure a sufficient turning moment on arm 265,, and assembly 212, to position them.
the fluid cylinders 280 illustrated are single action cylinders with a spring return, however, it is to be understood that double acting cylinders may be used.
the cylinders 280 may be independently controlled or plumbed in parallel so that they operate sychronously.
the finger assemblies 212 can be selectively rotated to their three-jaw or wrap mode positions by a positioning mechanism 215.
the opening and closing of the fingers 234 is effected by the drive unit 254 with the fingers 234 being simultaneously opened and closed.
FIGS, 11-14 illustrate the mechanism 210 picking up a generally rectilinear object O,,.
the piston rods 285 of cylinders 281 are extended to position finger assemblies 212,, and 212,. so that the wrap mode is accomplished.
FIG. 11 that the fingers 234 have closed sufficiently for the innermost contact points 305 to just engage opposed edges of the object O,,.
An enlarged portion of FIG. 11 show ing the position of the tips 301 in this position is seen in FIG. 12.
the object 0, will be centered therebetween.
the object 0, is illustrated as initially adjacent the working surface 225 of the palmar plate 221.
FIGS. 15 and 16 illustrate the mechanism 210 grip ping a spherical object 0 between the tips 301. It will be noted that the fingers 234 center the object 0,, with respect to the base 211 and the tips 301 center the object 0 with respect to the tips. Thus, it will be seen that the tips 301 allow the mechanism 210 to grip relatively small objects, The finger assemblies 212,, and 212, are in their threejaw modal position in FIGS. 15 and 16.
FIGS. 17 and 18 illustrate the mechanism 210 gripping a large object 0, having an appropriate hole H, therein sufficient for the fingers 234 to be inserted into the hole H,
the finger assemblies 212,, and 212 are illustrated in their three-jaw position so that the fingers 234 can be extended into the hole 1-1, and opened be yond their normal open position into their spread position to grip the object 0, within the hole H
the inside and outside edges E, and E of each of members 240 of fingers 234 can be used to grip objects as illustrated in FIG. 1.
the finger assemblies 212,, and 212 are in their wrap prehensile mode and are gripping a cylindrical object as shown by dashed lines in FIG. 1.
the finger drive cylinder 256 is connected to an appropriate source fluid under pressure (not shown) so that the rod 250 can be selectively extended and re tracted.
the positioning cylinders 281 are also connected to an appropriate source of fluid under pressure (not shown) through appropriate valving (not shown) so that the rods 285 can be selectively extended and retracted.
the cylinders 281 may be connected in paral lel for simultaneous operation only or may be con nected so that they operate independently of each other.
the cylinders 281 operate independently of cylinder 256.
a multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising:
a palmar base defining a working surface thereon. said base having a centerline generally normal to said working surface;
each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface;
single finger drive means operatively connected to all of said fingers for simultaneously pivoting said fingers about the respective said curl revolute axis of said finger to engage the objects;
positioning drive means operatively connected to said support means for selectively positioning said support means so that said fingers close in inter secting curling planes in a first position and in substantially parallel and laterally spaced curling planes in a second position.
one of said support means is fixedly mounted on said base, wherein two of said support means are pivoted on said base at spaced apart positioning axes generally parallel to said centerline of said base, and wherein said positioning drive means is operatively connected to said two of said support means to selectively pivot said two of said support arms about said positioning axes to selectively move said two of said support arms between said first and second positions.
said finger drive means includes power means carried by said base, said power means comprising adapter means, a drive unit for selectively moving said adapter means along an operating path generally parallel to said centerline of said base. and connector means operatively connecting each of said fingers to said adapter unit for effecting simultaneous opening and closing of all of said fingers in response to movement of said adapter means.
said positioning drive means comprises at least one motor means carried by said adapter means and operatively connected to said two of said power arms to selectively pivot said two of said power arms and said two of said support means about said positioning axes.
said fluid cylinder means includes a first fluid cylinder carried by said adapter means having a first piston rod operatively connected to one of said two of said power arms to selectivcly pivot said one of said two of said power arms about its said positioning axis; and a second fluid cylinder carried by said adapter means having a second piston rod operatively connected to the other of said two of said power arms to selectively pivot said other of said two of said power arms about its said positioning axis.
each of said fingers of said finger assemblies further includes a projecting end extendable over said base and wherein each of said finger assemblies further includes tip means rotatably mounted in said projecting end of said finger about a tip axis generally parallel to said curl revolute axis of said finger, said tip means constructed and arranged to grasp objects.
said tip means defines at least two spaced apart contact surfaces thereon on the same side of said finger adapted to engage objects so that said tip means is rotated in re sponse to engagement with the object until said two contact surfaces both engage the object.
the mechanism of claim 8 further including initial positioner means construced and arranged to resiliently urge said tip means in a first predetermined rotational direction so that the rotation of said tip means in response to enngagement with the object is in a second predetermined rotational direction opposite to said first direction.
said finger drive mechanism includes a finger drive linkage operatively associated with each of said finger assemblies and operating substantially coplanar with the curling plane of said finger associated therewith.
each of said finger drive linkages defining a slider crank mechanism. the slider axis thereof substantially parallel to said finger curling plane.
each of said fingers includes a projecting end which opens and closes within said curling planes and a tip assembly carried by each of said projecting ends, each of said tip semblies comprising;
a tip member including contact means for engaging the object
pivot means for pivotally mounting said tip member on the projecting end of said finger member about a tip axis generally normal to the curling plane of said finger member for pivotal movement independent of said finger member movement.
each of said tip assemblies further includes limiting means for limiting the pivotal movement of said tip member in a first direction and in a second direction opposite to said first direction about said tip axis.
each of said tip assemblies further includes positioner means for resiliently urging said tip means in said first direction.
each of said tip members defines two spaced apart contact surfaces arranged to urge said tip member in said second direction against the urging of said positioner means as an incident to the engagement of one of said contact points with the object.
each of said tip members defines a plurality of spaced apart contact surfaces thereon constructed and arranged so that said tip member is inherently shifted to cause at least two of said contact surfaces to engage the object as it is being grasped.
a multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising:
a palmar base defining a working surface thereon, said base having a centerline generally normal to said working surface;
each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface; and,
said finger drive means including power means carried by said base.
said power means comprising adapter means. a drive unit for selectively moving said adapter means along an operating path generally parallel to said centerline of said base, and connector means operatively connecting each of said fingers to said adapter unit for effecting simultaneous opening and closing of all of said fingers in response to movement of said adapter means, said connector means including at least three power arms connected to said adapter means for movement there' with, one of said power arms fixed to said adapter means in alignment with said one of said support means and two of said power arms pivoted to said adapter means about arm positioning axes in alignment with said positioning axes of said two of said positioning means, and link means operatively connecting each of said power arms to said finger associated therewith.
said drive unit comprises a fluid cylinder carried by said base; said fluid cylinder including a piston rod selectively movable about a path generally parallel to the centerline of said base, said piston rod having a projecting end and said adapter means mounted on said projecting end of said piston rod.
a multiple prehension mechanism adapted to as sume different prehensile operational modes to grasp objects comprising:
a palmar base defining a working surface thereon, said base having a centerline generally normal to said working surfaces;
each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface, one of said support means fixedly mounted on said base, two of said support means pivoted on said base at spaced apart positioning axes generally parallel to said centerline of said base said two of said support means selectively movable from a first position in which said fingers move in intersecting curling planes to a second position in which said fingers move in parallel curling planes.
a multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising:
each of said finger assemblies including a support arm and a finger pivoted on said support arm about a curl revolute axis generally normal to said centerline, said support arms pinned to said base at three spaced points equally spaced about a circle lying in a plane generally perpendicular to said centerline, said support arm of one of said finger assemblies having a fixed position so that it extends generally radially of said circle and said support arms of the other two of said finger assemblies selectively pivotal about their associated points around positioning axes generally parallel to said centerline so that the curl revolute axes of said other two of said finger assemblies move about arcuate paths centered on said positioning axes.
the mechanism of claim 19 further including p0 sitioning means for selectively moving said other two of said finger assemblies to a first position in which said support arms extend from said circle in directions not parallel to each other and to a second position in which said support arms are all generally parallel and laterally spaced so that said fingers pivot generally parallel to each other.
the mechanism of claim 21 further including finger drive means for selectively pivoting said fingers about said curl revolute axes to grasp objects.

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Abstract

A multiple prehension mechanism including a base; a plurality of finger assemblies mounted on the base; finger drive means for selectively opening and closing the fingers so that each finger moves in a single curling plane; and positioning drive means for selectively positioning the finger assemblies so that different prehensile modes can be achieved. The disclosure also contemplates the method of operation of the mechanism.

Description

United States Patent Skinner," Aug. 26, 1975 [54] MULTIPLE PREHENSION MECHANISM 2,226,789 12/1940 Tupy U 294/DIG. 2

3 (ll 54 l H [76] lnventor: Frank R. Skinner,ll, 2248 Ann Dr., 10/1971 X St. Joseph. Mich. 49085 Primary Examiner-Robert J. Spar [22] Fllcd 1974 Assistant Examiner-George F. Abraham [2] 1 Appl No.: 448,341 Attorney, Agent, or FirmB J. Powell Related U.S. Application Data [63] Continuation-in-part of Scr. No. 3601122 May l4,

I973 abandoned. [57] ABSTRACT A multiple prehension mechanism including a base; a [52] j i l gf plurality of finger assemblies mounted on the base; l I I finger drive means for selectively opening and closing 294/1310 2 the fingers so that each finger moves in a single cur- [SI] Int. Cl H B25!) 5/04 1 I d r d f l I Field of

214/] H 7 l mg ane, an posi ioning r ve means or se ec we y 5 2 positioning the finger assemblies so that different pre- H hensile modes can be achieved. The disclosure also contemplates the method of operation of the mecha- [56] References Clted "ism.

UNITED STATES PATENTS 393223 I l/IRXH Elliott 294/97

22 Claims, 19 Drawing Figures PATENTED AUBZ 6 I975 xi? 1 U? 8 PATENTED AUGZB 1975 PATENTED AUGZSIBYS

2/2 I\ amt

7 500 r 210 w 1 b 0 o I 1 E I I E E I f I I l (SPREAD 240 P I POSITION p CYLINDR/CA I 4 l OBJECTLI I MULTIPLE PREHENSION MECHANISM CROSS-REFERENCE TO RELATED APPLICATIONS This application is a continuation-impart of my copending application Ser. No. 360,022, filed May 14, 1973 entitled Multiple Prehension Manipulator Mechanism, now abandoned.

BACKGROUND OF THE INVENTION Many attempts have been made to produce a manipulator having substantially the same capabilities as the human hand. Because the human hand has many motor and control systems, such prior art manipulators have been very complicated and therefore prohibitively expensive to manufacture and maintain. Because of the complexity of the human hand, many of these prior art manipulators attempted to combine several motor functions of the human hand with the attendant loss of capability.

SUMMARY OF THE INVENTION The invention disclosed herein overcomes these and other problems associated with the prior art by provid ing a manipulator mechanism which has virtually all of the basic capabilities associated with the human hand. The construction of the invention is relatively simple thereby reducing the manufacturing cost and maintenance cost.

The invention comprises generally a plurality of finger assemblies, each including a finger pivoted about at least one finger axis through a single plane normal to the finger axis, a base mounting the finger assemblies so that the plane of each finger can e rotated about a positioning axis through the plane and normal to the finger axes, finger drive means for pivoting the fingers about the respective finger axes, and positioning means for moving the finger assemblies so that at least two of the planes will be rotated about their respective positioning axes. The finger drive means collectively pivots the fingers about their finger axis.

These and other features and advantages will become more apparent upon consideration of the following specification and accompanying drawings wherein like characters of reference designate corresponding parts throughout the various views and in which:

BRIEF DESCRIPTION OF THE DRAWINGS FIG. I is a perspective view of one embodiment of the invention;

FIG. 2 is an operating end view of the invention of FIG. 1;

FIG. 3 is a cross-sectional view taken along line 33 in FIG. 2 showing the finger assemblies in wrap-spread prehensile mode;

FIG. 4 is a cross-sectional view taken along line 4-4 in FIG. 3;

FIG. 5 is a side view illustrating a second embodi ment of the invention;

FIG. 6 is a longitudinal cross-sectional view of FIG. 5;

FIG. 7 is a cross-sectional view taken along line 77 in FIG. 5;

FIG. 7A is a cross-sectional view taken along line 7A7A in FIG. 5;

FIG. 8 is an enlarged side view of one of the tips of that embodiment of FIG. 5;

(ill

FIG. 9 is an edge view taken along line 9-9 in FIG.

FIG. 10 is a cross-sectional view taken along line 10-10 in FIG. 9; and,

FIGS. 11-18 illustrate the embodiment of FIG. 5 in operation.

These figures and the following detailed description disclose specific embodiments of the invention, how ever, it is to be understood that the inventive concept is not limited thereto since it may be embodied in other forms.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS Referring to FIGS. I-4, it will be seen that the first embodiment of the manipulator is designated by the

numeral

110. Generally, the manipulator mechanism includes a

base

1 l l, a plurality of

finger assemblies

112 mounted on base 111, a firger driving mechanism 114 carried by the base 111, and a

positioning mechanism

115 carried by base 111 for positioning the

finger assemblies

112.

Basically, the manipulator mechanism is an assembly of drive and mechanisms intended for prehension. These mechanisms, called fingers, are attached to a base. Three fingers are considered necessary and sufficient in the construction of the manipulator. Fingers can approach, contact, or pass one another during prehensile operation. The manipulator contains all of the drives below the palmar surface of base 111. A multiple degree-of-freedom wrist mechanism (not shown) may be used to connect to and move the manipulator so that it can approach an object from any direction.

The objective of the manipulator mechanism is to produce a highly versatile hand with a minimum number of moving parts, a dependable drive system, and an optimum number of degrees of freedom. The number of degrees of freedom is considered uptimum when it is estimated that the manipulator mechanism can grasp all of the basic geometrical shapes from any aspect with the minimum number of external control inputs. These basic shapes are rectangular and triangular prisms, spheres, and cylinders.

The human hand is generally accepted as being capable of the six basic prehensile patterns: lateral, hook, tip. palmar, spherical, and cylindrical. These six basic prehensile patterns, because of similarities, can be reduced to the three basic mechanical equivalents of wrap, three-jaw and tip prehension that very nearly duplicate the basic human hand prehensile patterns. Additionally, in order to grip large objects that the fingers can not surround, spread prehension is created which consists of inserting the fingers into an opening in the object and then bending them outward to engage the object within the opening. The

manipulator mechanism

110 is able to generate all of the above four equivalent prehensile patterns.

The base 111 seen in FIGS. 1-4 includes generally a

top palmar plate

121, which corresponds to the palm of the human hand, a

base plate

122 and a plurality of spacer supports 124 which connect

plates

121 and 122 so that they are generally parallel with palmar plate 12] providing a working

surface

125.

Appropriate cutouts

126 are provided in

palmar plate

121 for the

finger assemblies

112 to operate as will become more apparent.

Three

finger assemblies

112 designated 112,,1I2 are mounted between

plates

121 and 122 at equally spaced points about the circle defined by radius R from the common centerline CL of

plates

121 and 122.

FINGER ASSEMBLY Finger assemblies 112 112, are virtually identical in construction and therefore only one will be described in detail with like numerals applied to each. Each

assembly

112 includes a

support arm

130 having a pair of spaced apart mounting

ears

131. The

finger

134 is pivotally mounted between

ears

131 through a base

revolute joint

135 about a curl axis CA. The

arm

130 is attached to the back side of

palmar plate

121. The

arm

130 of

assemblies

112,, and 112, are connected to the

plate

121 through

revolute joint

136 so that the

arm

130 pivots about a positioning axis PA which intersects the circle of radius R and is normal to the working

sur face

125 of

plate

121 whereas the curl axis CA is normal to axis PA and spaced outwardly therefrom a distance D. The

arm

130 of

assembly

112, is fixed to the back of

plate

121 so that it extends radially, however, the distance from the circle of radius R to axis CA is the distance D and the orientation of axis CA is like that described above for

assemblies

112, and 112 Thus, it will be seen that the

finger

134 is pivotal through a single curling plane CP as best seen in FIG. 1 about the curling axis CA perpendicular to the plane. The planes CP,, and CP of

assemblies

112,, and 112, are pivoted about the positioning axis PA which is parallel to the curling plane CP. In the example shown, the axis PA lies within the curling plane CP.

The

fingers

134 may have multiple joints and links as fingers 34, however, those illustrated are single

elongate members

140 pivoted at joint 135 and projecting out over the working

surface

125 of

plate

121. A driving

leg

141 is integral with

member

130 and extends below

arm

130 for use in driving

finger

134 as will be explained. It will be noted that

fingers

134 have a normal open position so that the longitudinal axis of

finger

134 lies along a path P substantially perpendicular to working

surface

125. The

finger

134 is designed to be double acting so that it can pivot both inwardly and outwardly from path P as will become more apparent.

FINGER DRIVE MECHANISM While separate drive mechanism may be used for each

finger assembly

112, a simplified common drive mechanism is illustrated. Mechanism 114 includes a

tubular drive rod

150 slidably journalled in

base plate

122 for sliding movement along the centerline CL of base 111. The operating

end

151 of

rod

150 projects into

space

152 between

plates

121 and 122 and its other end is connected to a

drive unit

154 such as the fluid cylinder shown in FIG. 3. A power adapter 155 is attached to the operating

end

151 of

rod

150 in

space

152. The outwardly extending power arms 156 156, are attached to adapter 155 so that they are aligned with the

arm

130 each associated

finger assembly

112,,112,.. The power arms 156,, and 156,. are pivoted along the respective positioning axes PA of

assemblies

112,, and 112,. so that arms 156,, and 156 pivot in tandem with

arms

130 of

assemblies

112,, and 112 respectively. A

drive link

158 connects each arm 156 with its associated

finger

134 so that as

rod

150 moves adapter 155 and power arms 156 toward the back of

palmar plate

121, the

fingers

134 will be simultaneously closed and as

rod

150 and adapter 155 moves toward

base plate

122, the

fingers

134 will be opened to their normal position. Further movement of

rod

150 toward

base plate

122 cause the

fingers

134 to continue to spread outwardly past the paths P into the spread prehensile mode.

POSITIONING MECHANISM Referring to FIG. 2, it will be seen that finger assem blies 112,, and

12,. can be moved from a three-jaw prehcnsile mode shown in solid lines to a wrap prehensile mode shown in dashed lines. It will be noted that the spread prehensile mode can be achieved in either posi tion and that the tip prehensile mode could be easily provided for with very little modification.

Stops

159 may be provided on

plate

121 as seen in FIG. 4 to limit the movement of the finger assemblies about axes PA.

The positioning of the

assemblies

112 may be accom plished in a number of different ways, however, the mechanism includes a

drive gear

160 on

drive shaft

161 journalled for rotation about the centerline CL of base 111. An

appropriate power source

162 such as the motor shown in FIG. 3 is used to selectively rotate

gear

160.

Shaft

161 passes through rod but is rotatable independently thereof. Gear meshes directly with driven

gear

164 attached to

arm

130 of

finger assembly

112,, and is connected to driven gear 165 attached to

arm

130 of

finger assembly

112,. through reversing

idler gear

166. When

gear

160 is rotated clockwise as seen in FIG. 9, the

finger assemblies

112,, and 112,. will be simultaneously rotated toward the wrap mode position, and when gear 16 is rotated counterclockwise,

assemblies

112,, and 112,. will be rotated toward their three' jaw mode position.

SECOND EMBODIMENT OF THE INVENTION The second embodiment of the invention shown in FIGS. 5-18 is a refinement of the

manipulator mechanism

110 and is designated generally 210 with

finger assemblies

212 mounted on

base

211 with finger

driv ing mechanism

214 and

positioning mechanism

215.

The base 211 seen in FIGS. 5-10 includes generally a top

palmar plate

221, which corresponds to the palm of the human hand, a

base plate

222 and a plurality of spacer supports 224 which connect

plates

221 and 222 so that they are generally parallel with

palmar plate

221 providing a working

surface

225.

Appropriate cutouts

226 are provided in

plates

221 and 222 for the

finger assemblies

212 to operate as will become more appar ent.

Three

finger assemblies

212 designated 212,,-212 are mounted between

plates

221 and 222 at equally spaced points about the circle defined by radius R from the common centerline CL of

plates

221 and 222 as seen in FIG. 7.

FINGER ASSEMBLY Finger assemblies 212 -212 are similar to

assemblies

112, virtually identical in construction and therefore only one will be described in detail with like numerals applied to each. Each

assembly

212 includes a

support arm

230 having a pair of spaced apart mount ing

ears

231. The

finger

234 is pivotally mounted between

ears

231 through a base revolute joint 235 about a curl axis CA. The

arm

230 is attached to the back side of

palmar plate

221. The

arm

230 of

assemblies

212,, and 212,. are connected to the

plate

221 and

spacer

233 through revolute joint 236 so that the

arms

230 pivot about a positioning axes PA which intersect the circle of radius R and are normal to the working

surface

225 of

plate

221 whereas the curl axes CA are normal to axes PA and spaced outwardly therefrom a distance D. The

arm

230 of

assembly

212, is fixed to the back of

plate

221 so that it extends radially, however, the distance from the circle of radius R to axis CA is the dislance D and the orientation of axis CA is like that described above for

assemblies

212,, and 212, Thus, it will be seen that each

finger

234 is pivotal through a single curling plane (P about the curling axis CA perpendicular to the plane. The planes CP,, and CP,. of

assemblies

212,, and 212, are pivoted about the positioning axes PA which are parallel to the curling plane CP. In the example shown. the axis PA lies within the curling plane CP.

The lingers 234 illustrated are single

elongate members

240 pivoted at joint 235 and projecting out over the working

surface

225 of

plate

221. A driving

leg

241 is integral with

member

240 and extends below

arm

230 for use in driving

finger

234 as will be explained. It will be noted that

fingers

234 have a normal open position so that the longitudinal axis of

finger

234 lies along a path P substantially perpendicular to working

surface

225. The

finger

234 is designed to be double acting so that it can pivot both inwardly and outwardly from path P as will become more apparent.

Each

finger assembly

212 mounts a

tip assembly

300 at the projecting end of

member

240 as best seen in FIGS. 8-10. Each

tip assembly

300 includes a

tip

301 and an

initial positioner unit

302. The projecting

end

242 of

member

240 defines a

slot

244 therethrough oriented generally parallel to the curling plane C? of

assembly

212. The

tip

301 is a generally rectilinear plate defining a

Vshaped notch

304 at its inner and outer ends to define a pair of spaced apart contact

points

305 at opposite ends of

tip

301. The

points

305 define

contact surfaces

307 thereon to engage the object to be grasped. The

tip

301 is pivoted at its center between the

ears

245 in the

end

242 of

member

240 on opposite sides of

slot

244 on a

support pin

306 carried between

ears

245. The

tip

301 is free to pivot about the axis TA of

305 within

slot

244.

The

initial positioner unit

302 serves to initially position

tip

301 in a known pivotal position with respect to

member

240 as will become more apparent. While different mechanisms may be used, the

unit

302 illus- [rated includes a compression coil spring 310 and a plunger 3]]. An

appropriate hole

246 is provided in the

end

242 of

member

240 at the bottom of

slot

244 to slidably receive the spring 310 and plunger 31] therein, The

hole

246 is located so that the spring 310 resiliently urges the

tip

301 in a predetermined rotational direction, here shown as counterclockwise by the plunger 311 bearing against the

tip

301. The rotational direction in which tip 301 is urged can easily be reversed simply by shifting the

positioner unit

302 to the opposite side of the

slot

244 as shown by dashed lines in FIG. 10.

FINGER DRIVE MECHANISM While separate drive mechanisms may be used for each

finger assembly

212. a simplified common drive mechanism is illustrated. Mechanism 314 includes a

drive rod

250 slidably journalled in

base plate

222 for sliding movement along the centerline CL of

base

211. The operating

end

251 of

rod

250 projects into

space

252 between

plates

221 and 222 and its other end is connected to a

drive unit

254 such as the

piston

255 of a double

acting fluid cylinder

256 shown in FIG. 6. A

power adapter

258 is attached to the operating

end

251 of

rod

240 in

space

252 so that

adapter

258 can be reciprocated in

space

252 along the centerline CL.

Adapter

258 includes a pair of spaced apart, generally circular,

parallel carriage plates

259 joined at their cen tral portions by a

boss

260 so that an annular arm mounting recess 26] is defined between

plates

259.

Outwardly extending

power arms

265 265, of

finger drive linkages

263 are mounted within the

annular recess

261 in alignment with

support arms

230. Each

power arm

265 has a generally

horizontal leg

266 and an upwardly and outwardly extending

bifurcated leg

268. Each

leg

266 is slidably received between

carriage plates

259 and is rotatably mounted on a

pivot pin

269 extending between

plates

259 about the positioning axes PA. The

leg

266 of

positioning arm

265,, is held in a fixed position in alignment with

support arm

230,, by a

second pin

270 extending through

let

266 between

carriage plates

259 as seen in FIGS, 6 and 7. Thus. it will be seen that

power arms

265,, and 265,. can pivot about axes PA while

arm

265,, is held in a fixed position.

Drive

links

271 connect each

power arm

265 with the driving

leg

241 of the

finger

234 associated therewith so that

fingers

234 will be driven open or closed as the

power adapter

258 is moved within

space

252 by

drive unit

254. Each

link

271 has its

outer end

272 pinned between the ends of

bifurcated leg

268 of

arm

265 while its bifurcated

inner end

274 has the driving leg 24] of

finger

234 pinned therebetween. Thus, as the

power adapter

258 is moved toward the

palmar plate

221 of

base

211, the

tips

301 on

fingers

234 will be closed and vice versa.

It will further be noted that the mechanical advantage of the drive input to

fingers

234 decreases as the fingers close. This is advantageous since the larger objects to be grasped by

fingers

234 nonnally weigh more than smaller objects thereby requiring a greater holding force. Thus, a variation in holding force is provided without a change in the fluid pressure of

cylinder

256. It will also be noted that the

finger drive linkages

263 are slider crank mechanisms where the slider axis is parallel to the curling plane of the

particular finger assembly

212 with which it is associated. This causes the movement of the

linkage

263 to be coplanar with the curling plane of its associated

finger assembly

212.

POSITIONING MECHANISM Referring to FIG. 7, it will be seen that

finger assemblies

212,, and 212,. can be moved from a three-jaw prehensile mode shown in dashed lines to a wrap prehen sile mode shown in solid lines. It will be noted that the spread prehensile mode can be achieved in either position and that the tip prehensile mode is provided in the three-jaw prehensile mode. The

positioning mechanism

215 is effective to position the

assemblies

212,, and 212,. in their difi'erent modal positions.

The

positioning mechanism

215 includes a pair of

drive subassemblics

280 carried by the

power arm

265 one of the

sub-assemblies

280 is operatively connected to the

power arm

265,, and one of the

subassemblies

280 is operatively connected to

power arm

265, The

subassemblies

280 are mirror images of each other so that only one subassembly will be described in detail while like reference numbers will be applied to the

other assembly

280.

Subassembly 280 attached to

power arm

265,, includes a

fluid cylinder

281 carried by a

bracket

282 mounted on the side of the

horizontal leg

266 of

power arm

265 The

cylinder

281 is positioned so that its centerline CL is generally parallel to the centerline of

leg

266 of

arm

265,, and generally parallel to the working

surface

225 of

palmar plate

221 and displaced laterally of

leg

266 of

arm

265,, a distance d,.

The

piston rod

285 of

cylinder

280 has its projecting end connected to the

leg

266 of

power arm

265,, through a

connector

286. One end of

connector

286 is pinned to the projecting end of

piston rod

285 and its other end is pinned to the

leg

266 of

arm

265,, in a

slot

288 formed in the side of

leg

266 by a

drive pin

289.

289 is located from the positioning axis PA of

arm

265,, a distance d Thus, as the

piston rod

285 is extended. the

positioning arm

265,, and

finger assembly

212,, will be pivoted toward their wrap modal position and toward their three-jaw modal position. The distance d, and 41-, are sufficient to insure a sufficient turning moment on

arm

265,, and

assembly

212,, to position them.

The

fluid cylinders

280 illustrated are single action cylinders with a spring return, however, it is to be understood that double acting cylinders may be used. The

cylinders

280 may be independently controlled or plumbed in parallel so that they operate sychronously.

OPERATION OF SECOND EMBODIMENT The operation of the second embodiment of the invention will be best understood by reference to FIGS 11-18 showing the various modes of operation. It will first of all be noted that the

finger assemblies

212 can be selectively rotated to their three-jaw or wrap mode positions by a

positioning mechanism

215. The opening and closing of the

fingers

234 is effected by the

drive unit

254 with the

fingers

234 being simultaneously opened and closed.

FIGS, 11-14 illustrate the

mechanism

210 picking up a generally rectilinear object O,,. In this operation, the

piston rods

285 of

cylinders

281 are extended to position

finger assemblies

212,, and 212,. so that the wrap mode is accomplished. It will be seen in FIG. 11 that the

fingers

234 have closed sufficiently for the innermost contact points 305 to just engage opposed edges of the object O,,. An enlarged portion of FIG. 11 show ing the position of the

tips

301 in this position is seen in FIG. 12. It will further be noted that as the

fingers

234 are closed, the object 0,, will be centered therebetween. The object 0,, is illustrated as initially adjacent the working

surface

225 of the

palmar plate

221. As the

fingers

234 continue to move inwardly to grip the object it will be seen that a reaction force F,, will be exerted on that

point

305 in contact with the object 0,, which causes a moment to be exerted on the

tip

301 in opposition to the

positioner unit

302 to pivot the

tip

301 clockwise as seen in FIG. 12. This in turn causes a holding force F to be generated on the object O,, that forces the object toward the

palmar plate

221. This insures that the object 0,, is clamped against the

plate

221. This clamping force is generated as the

tip

301 ro tates clockwise until the

other contact point

305 at the inner end of the

tip

301 contacts the side of the object O,,. This position is shown in FIG. 13 and an enlarged portion of FIG 13 is seen in FIG. 14 showing both of the inner contact points 305 engaging the object O,,. The

mechanism

210 has now gripped object 0,, sufficiently to allow the object to be picked up.

FIGS. 15 and 16 illustrate the

mechanism

210 grip ping a spherical object 0 between the

tips

301. It will be noted that the

fingers

234 center the object 0,, with respect to the

base

211 and the

tips

301 center the object 0 with respect to the tips. Thus, it will be seen that the

tips

301 allow the

mechanism

210 to grip relatively small objects, The

finger assemblies

212,, and 212, are in their threejaw modal position in FIGS. 15 and 16.

FIGS. 17 and 18 illustrate the

mechanism

210 gripping a large object 0, having an appropriate hole H, therein sufficient for the

fingers

234 to be inserted into the hole H,,. The

finger assemblies

212,, and 212 are illustrated in their three-jaw position so that the

fingers

234 can be extended into the hole 1-1, and opened be yond their normal open position into their spread position to grip the object 0, within the hole H The inside and outside edges E, and E of each of

members

240 of

fingers

234 can be used to grip objects as illustrated in FIG. 1. The

finger assemblies

212,, and 212, are in their wrap prehensile mode and are gripping a cylindrical object as shown by dashed lines in FIG. 1.

The

finger drive cylinder

256 is connected to an appropriate source fluid under pressure (not shown) so that the

rod

250 can be selectively extended and re tracted. The positioning

cylinders

281 are also connected to an appropriate source of fluid under pressure (not shown) through appropriate valving (not shown) so that the

rods

285 can be selectively extended and retracted. The

cylinders

281 may be connected in paral lel for simultaneous operation only or may be con nected so that they operate independently of each other. The

cylinders

281 operate independently of

cylinder

256.

While specific embodiments of the invention have been disclosed herein, it is to be understood that the full use of modifications, substitutions and equivalents may be made without departing from the scope of the inventive concept.

I claim:

I. A multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising:

a palmar base defining a working surface thereon. said base having a centerline generally normal to said working surface;

at least three finger assemblies carried by said base. each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface;

single finger drive means operatively connected to all of said fingers for simultaneously pivoting said fingers about the respective said curl revolute axis of said finger to engage the objects; and,

positioning drive means operatively connected to said support means for selectively positioning said support means so that said fingers close in inter secting curling planes in a first position and in substantially parallel and laterally spaced curling planes in a second position.

2. The mechanism of

claim

1 wherein one of said support means is fixedly mounted on said base, wherein two of said support means are pivoted on said base at spaced apart positioning axes generally parallel to said centerline of said base, and wherein said positioning drive means is operatively connected to said two of said support means to selectively pivot said two of said support arms about said positioning axes to selectively move said two of said support arms between said first and second positions.

3. The mechanism of

claim

1 wherein said finger drive means includes power means carried by said base, said power means comprising adapter means, a drive unit for selectively moving said adapter means along an operating path generally parallel to said centerline of said base. and connector means operatively connecting each of said fingers to said adapter unit for effecting simultaneous opening and closing of all of said fingers in response to movement of said adapter means.

4. The mechanism of

claim

1 wherein said positioning drive means comprises at least one motor means carried by said adapter means and operatively connected to said two of said power arms to selectively pivot said two of said power arms and said two of said support means about said positioning axes.

5. The mechanism of

claim

4 wherein said motor means includes fluid cylinder means.

6. The mechanism of

claim

5 wherein said fluid cylinder means includes a first fluid cylinder carried by said adapter means having a first piston rod operatively connected to one of said two of said power arms to selectivcly pivot said one of said two of said power arms about its said positioning axis; and a second fluid cylinder carried by said adapter means having a second piston rod operatively connected to the other of said two of said power arms to selectively pivot said other of said two of said power arms about its said positioning axis.

7. The mechanism of

claim

1 wherein each of said fingers of said finger assemblies further includes a projecting end extendable over said base and wherein each of said finger assemblies further includes tip means rotatably mounted in said projecting end of said finger about a tip axis generally parallel to said curl revolute axis of said finger, said tip means constructed and arranged to grasp objects.

8. The mechanism of

claim

7 wherein said tip means defines at least two spaced apart contact surfaces thereon on the same side of said finger adapted to engage objects so that said tip means is rotated in re sponse to engagement with the object until said two contact surfaces both engage the object.

9. The mechanism of

claim

8 further including initial positioner means construced and arranged to resiliently urge said tip means in a first predetermined rotational direction so that the rotation of said tip means in response to enngagement with the object is in a second predetermined rotational direction opposite to said first direction.

10. The mechanism of

claim

1 wherein said finger drive mechanism includes a finger drive linkage operatively associated with each of said finger assemblies and operating substantially coplanar with the curling plane of said finger associated therewith. each of said finger drive linkages defining a slider crank mechanism. the slider axis thereof substantially parallel to said finger curling plane.

II. The mechanism of

claim

1 wherein each of said fingers includes a projecting end which opens and closes within said curling planes and a tip assembly carried by each of said projecting ends, each of said tip semblies comprising;

a tip member including contact means for engaging the object; and,

pivot means for pivotally mounting said tip member on the projecting end of said finger member about a tip axis generally normal to the curling plane of said finger member for pivotal movement independent of said finger member movement.

12. The mechanism of claim 11 wherein each of said tip assemblies further includes limiting means for limiting the pivotal movement of said tip member in a first direction and in a second direction opposite to said first direction about said tip axis.

13. The mechanism of

claim

12 wherein each of said tip assemblies further includes positioner means for resiliently urging said tip means in said first direction.

14. The mechanism of

claim

13 wherein each of said tip members defines two spaced apart contact surfaces arranged to urge said tip member in said second direction against the urging of said positioner means as an incident to the engagement of one of said contact points with the object.

15. The mechanism of claim 11 wherein each of said tip members defines a plurality of spaced apart contact surfaces thereon constructed and arranged so that said tip member is inherently shifted to cause at least two of said contact surfaces to engage the object as it is being grasped.

16. A multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising:

a palmar base defining a working surface thereon, said base having a centerline generally normal to said working surface;

single finger drive means operatively connected to all of said fingers for simultaneously pivoting said fingers about the respective said curl revolute axis of said finger to engage the objects, said finger drive means including power means carried by said base. said power means comprising adapter means. a drive unit for selectively moving said adapter means along an operating path generally parallel to said centerline of said base, and connector means operatively connecting each of said fingers to said adapter unit for effecting simultaneous opening and closing of all of said fingers in response to movement of said adapter means, said connector means including at least three power arms connected to said adapter means for movement there' with, one of said power arms fixed to said adapter means in alignment with said one of said support means and two of said power arms pivoted to said adapter means about arm positioning axes in alignment with said positioning axes of said two of said positioning means, and link means operatively connecting each of said power arms to said finger associated therewith.

17. The mechanism of claim 16 wherein said drive unit comprises a fluid cylinder carried by said base; said fluid cylinder including a piston rod selectively movable about a path generally parallel to the centerline of said base, said piston rod having a projecting end and said adapter means mounted on said projecting end of said piston rod.

18. A multiple prehension mechanism adapted to as sume different prehensile operational modes to grasp objects comprising:

a palmar base defining a working surface thereon, said base having a centerline generally normal to said working surfaces;

at least three finger assemblies carried by said base, each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface, one of said support means fixedly mounted on said base, two of said support means pivoted on said base at spaced apart positioning axes generally parallel to said centerline of said base said two of said support means selectively movable from a first position in which said fingers move in intersecting curling planes to a second position in which said fingers move in parallel curling planes.

19. A multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising:

a base defining a centerline;

three finger assemblies carried by said base, each of said finger assemblies including a support arm and a finger pivoted on said support arm about a curl revolute axis generally normal to said centerline, said support arms pinned to said base at three spaced points equally spaced about a circle lying in a plane generally perpendicular to said centerline, said support arm of one of said finger assemblies having a fixed position so that it extends generally radially of said circle and said support arms of the other two of said finger assemblies selectively pivotal about their associated points around positioning axes generally parallel to said centerline so that the curl revolute axes of said other two of said finger assemblies move about arcuate paths centered on said positioning axes.

20. The mechanism of claim 19 further including p0 sitioning means for selectively moving said other two of said finger assemblies to a first position in which said support arms extend from said circle in directions not parallel to each other and to a second position in which said support arms are all generally parallel and laterally spaced so that said fingers pivot generally parallel to each other.

21. The mechanism of claim 20 wherein said support arms of said other two of said finger assemblies extend substantially radially with respect toisaid circle in said first position.

22. The mechanism of

claim

21 further including finger drive means for selectively pivoting said fingers about said curl revolute axes to grasp objects.

Claims (22)

1. A multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising: a palmar base defining a working surface thereon, said base having a centerline generally normal to said working surface; at least three finger assemblies carried by said base, each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface; single finger drive means operatively connected to all of said fingers for simultaneously pivoting said fingers about the respective said curl revolute axis of said finger to engage the objects; and, positioning drive means operatively connected to said support means for selectively positioning said support means so that said fingers close in intersecting curling planes in a first position and in substantially parallel and laterally spaced curling planes in a secOnd position.

2. The mechanism of claim 1 wherein one of said support means is fixedly mounted on said base, wherein two of said support means are pivoted on said base at spaced apart positioning axes generally parallel to said centerline of said base, and wherein said positioning drive means is operatively connected to said two of said support means to selectively pivot said two of said support arms about said positioning axes to selectively move said two of said support arms between said first and second positions.

3. The mechanism of claim 1 wherein said finger drive means includes power means carried by said base, said power means comprising adapter means, a drive unit for selectively moving said adapter means along an operating path generally parallel to said centerline of said base, and connector means operatively connecting each of said fingers to said adapter unit for effecting simultaneous opening and closing of all of said fingers in response to movement of said adapter means.

4. The mechanism of claim 1 wherein said positioning drive means comprises at least one motor means carried by said adapter means and operatively connected to said two of said power arms to selectively pivot said two of said power arms and said two of said support means about said positioning axes.

5. The mechanism of claim 4 wherein said motor means includes fluid cylinder means.

6. The mechanism of claim 5 wherein said fluid cylinder means includes a first fluid cylinder carried by said adapter means having a first piston rod operatively connected to one of said two of said power arms to selectively pivot said one of said two of said power arms about its said positioning axis; and a second fluid cylinder carried by said adapter means having a second piston rod operatively connected to the other of said two of said power arms to selectively pivot said other of said two of said power arms about its said positioning axis.

7. The mechanism of claim 1 wherein each of said fingers of said finger assemblies further includes a projecting end extendable over said base and wherein each of said finger assemblies further includes tip means rotatably mounted in said projecting end of said finger about a tip axis generally parallel to said curl revolute axis of said finger, said tip means constructed and arranged to grasp objects.

8. The mechanism of claim 7 wherein said tip means defines at least two spaced apart contact surfaces thereon on the same side of said finger adapted to engage objects so that said tip means is rotated in response to engagement with the object until said two contact surfaces both engage the object.

9. The mechanism of claim 8 further including initial positioner means construced and arranged to resiliently urge said tip means in a first predetermined rotational direction so that the rotation of said tip means in response to enngagement with the object is in a second predetermined rotational direction opposite to said first direction.

10. The mechanism of claim 1 wherein said finger drive mechanism includes a finger drive linkage operatively associated with each of said finger assemblies and operating substantially coplanar with the curling plane of said finger associated therewith, each of said finger drive linkages defining a slider crank mechanism, the slider axis thereof substantially parallel to said finger curling plane.

11. The mechanism of claim 1 wherein each of said fingers includes a projecting end which opens and closes within said curling planes and a tip assembly carried by each of said projecting ends, each of said tip assemblies comprising: a tip member including contact means for engaging the object; and, pivot means for pivotally mounting said tip member on the projecting end of said finger member about a tip axis generally normal to the curling plane of said finger member for pivotal movement independent of said finger member movement.

12. The mechanism of claim 11 wherein each of said tip Assemblies further includes limiting means for limiting the pivotal movement of said tip member in a first direction and in a second direction opposite to said first direction about said tip axis.

13. The mechanism of claim 12 wherein each of said tip assemblies further includes positioner means for resiliently urging said tip means in said first direction.

14. The mechanism of claim 13 wherein each of said tip members defines two spaced apart contact surfaces arranged to urge said tip member in said second direction against the urging of said positioner means as an incident to the engagement of one of said contact points with the object.

16. A multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising: a palmar base defining a working surface thereon, said base having a centerline generally normal to said working surface; at least three finger assemblies carried by said base, each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface; and, single finger drive means operatively connected to all of said fingers for simultaneously pivoting said fingers about the respective said curl revolute axis of said finger to engage the objects, said finger drive means including power means carried by said base, said power means comprising adapter means, a drive unit for selectively moving said adapter means along an operating path generally parallel to said centerline of said base, and connector means operatively connecting each of said fingers to said adapter unit for effecting simultaneous opening and closing of all of said fingers in response to movement of said adapter means, said connector means including at least three power arms connected to said adapter means for movement therewith, one of said power arms fixed to said adapter means in alignment with said one of said support means and two of said power arms pivoted to said adapter means about arm positioning axes in alignment with said positioning axes of said two of said positioning means, and link means operatively connecting each of said power arms to said finger associated therewith.

18. A multiple prehension mechanism adapted to assume different prehensile operational modes to grasp objects comprising: a palmar base defining a working surface thereon, said base having a centerline generally normal to said working surfaces; at least three finger assemblies carried by said base, each of said finger assemblies including a support means mounted on said base, a finger pivotally mounted on each of said support means about a curl revolute axis generally perpendicular to said centerline for movement toward and away from said working surface, one of said support means fixedly mounted on said base, two of said support means pivoted on said base at spaced apart positioning axes generally parallel to said centerline of said base, said two of said support means selectively movable from a first position in which said fingers move in intersecting curling planes to a second position in which said fingers move in parallel curling planes.

19. A multiple prehension mechanism adapted to assume different prehensile operational mOdes to grasp objects comprising: a base defining a centerline; three finger assemblies carried by said base, each of said finger assemblies including a support arm and a finger pivoted on said support arm about a curl revolute axis generally normal to said centerline, said support arms pinned to said base at three spaced points equally spaced about a circle lying in a plane generally perpendicular to said centerline, said support arm of one of said finger assemblies having a fixed position so that it extends generally radially of said circle and said support arms of the other two of said finger assemblies selectively pivotal about their associated points around positioning axes generally parallel to said centerline so that the curl revolute axes of said other two of said finger assemblies move about arcuate paths centered on said positioning axes.

20. The mechanism of claim 19 further including positioning means for selectively moving said other two of said finger assemblies to a first position in which said support arms extend from said circle in directions not parallel to each other and to a second position in which said support arms are all generally parallel and laterally spaced so that said fingers pivot generally parallel to each other.

21. The mechanism of claim 20 wherein said support arms of said other two of said finger assemblies extend substantially radially with respect to said circle in said first position.

22. The mechanism of claim 21 further including finger drive means for selectively pivoting said fingers about said curl revolute axes to grasp objects.

US448341A 1973-05-14 1974-03-05 Multiple prehension mechanism Expired - Lifetime US3901547A (en)

Priority Applications (1)

Application Number	Priority Date	Filing Date	Title
US448341A US3901547A (en)	1973-05-14	1974-03-05	Multiple prehension mechanism

Applications Claiming Priority (2)

Application Number	Priority Date	Filing Date	Title
US36002273A	1973-05-14	1973-05-14
US448341A US3901547A (en)	1973-05-14	1974-03-05	Multiple prehension mechanism

Publications (1)

Publication Number	Publication Date
US3901547A true US3901547A (en)	1975-08-26

Family

ID=27000720

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US448341A Expired - Lifetime US3901547A (en)	1973-05-14	1974-03-05	Multiple prehension mechanism

Country Status (1)

Country	Link
US (1)	US3901547A (en)

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US6505870B1 (en)	2000-05-30	2003-01-14	UNIVERSITé LAVAL	Actuation system for highly underactuated gripping mechanism
US6652015B1 (en) *	2001-01-26	2003-11-25	Ta Instruments-Waters Llc	Gripper device
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CN102441892A (en) *	2011-10-25	2012-05-09	浙江大学	Under-actuated manipulator claw for picking fruits and vegetables
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EP2653415A1 (en) *	2012-04-20	2013-10-23	Festo AG & Co. KG	Gripper device for gripping objects
US20150165704A1 (en) *	2012-06-06	2015-06-18	Michelin Recherche Et Technique, S.A.	Device for supporting a raw rubber tire for the manufacture of a pneumatic tire
JP2016049593A (en) *	2014-08-29	2016-04-11	Thk株式会社	Actuator, and robot hand and walking robot using the actuator
CN105710878A (en) *	2016-04-29	2016-06-29	深圳博美德机器人股份有限公司	Mechanical gripper
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CN110842838A (en) *	2019-11-27	2020-02-28	东台市新杰科机械有限公司	Electric wrench for building electric tower
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US4990162A (en) *	1988-03-21	1991-02-05	Children's Hospital At Stanford	Rotary hand prosthesis
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US5161846A (en) *	1988-08-23	1992-11-10	Canon Kabushiki Kaisha	Hand apparatus
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US4957320A (en) *	1988-08-31	1990-09-18	Trustees Of The University Of Pennsylvania	Methods and apparatus for mechanically intelligent grasping
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EP0358966A3 (en) *	1988-08-31	1990-08-01	The Trustees Of The University Of Pennsylvania	Methods and apparatus for mechanically intelligent grasping
WO1990002030A1 (en) *	1988-08-31	1990-03-08	The Trustees Of The University Of Pennsylvania	Methods and apparatus for mechanically intelligent grasping
US5501498A (en) *	1988-08-31	1996-03-26	The Trustees Of The University Of Pennsylvania	Methods and apparatus for mechanically intelligent grasping
US5150937A (en) *	1989-09-07	1992-09-29	Canon Kabushiki Kaisha	Work pickup apparatus
US5328224A (en) *	1990-08-06	1994-07-12	University Of Utah Research Foundation	Robotic grasping apparatus
US5172951A (en) *	1990-08-06	1992-12-22	University Of Utah Research Foundation	Robotic grasping apparatus
US5280981A (en) *	1991-02-01	1994-01-25	Odetics, Inc.	End effector with load-sensitive digit actuation mechanisms
WO1993025458A1 (en) *	1992-06-05	1993-12-23	Siemens Aktiengesellschaft	Storage container with a gripping zone for a handling device
US5564880A (en) *	1992-06-05	1996-10-15	Siemens Aktiengesellschaft	Shelf storage system
US5378033A (en) *	1993-05-10	1995-01-03	University Of Kentucky Research Foundation	Multi-function mechanical hand with shape adaptation
US5486030A (en) *	1994-05-04	1996-01-23	Abc Packaging Machine Corporation	Apparatus and method for lifting and depositing bottles having handles
US5716352A (en) *	1994-06-24	1998-02-10	United States Surgical Corporation	Apparatus and method for performing surgical tasks during laparoscopic procedures
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US5762390A (en) *	1996-07-16	1998-06-09	Universite Laval	Underactuated mechanical finger with return actuation
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US20110089709A1 (en) *	2009-10-20	2011-04-21	Nexus Biosystems, Inc.	Gripper Apparatus and Method for Containers of Different Sizes
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