DE2423220A1 - MULTIPLE GRIPPERS - Google Patents

Description

MlAKZ RAYMOED SKIMER II

2248 Ann Drive

St, Joseph, Michigan /V.St.A.

Our reference: S 2804

Multiple grippers

The invention relates to a multiple gripper or manipulator.

Numerous attempts have been made to produce a manipulator which has essentially the same capabilities has like the human hand. Since the human hand has numerous motor systems and control systems, were the known manipulators are very complicated and therefore-in extremely expensive to manufacture and maintain. Because of the intricacy of the human hand, numerous known manipulators attempted to combine different motor punctures of the human hand, which has led to a loss of operational capabilities.

The invention solves these and other problems which occur with the known manipulators in that that a manipulator is created that actually does all of them

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Has basic skills of the human hand. The inventive Construction is relatively simple and this reduces manufacturing and maintenance costs.

A number of pinger assemblies are generally in accordance with the invention each of which has a pinger that traverses at least one pinger axis through a single plane is pivotable perpendicular to the finger axis, a base on which the finger assemblies are mounted such that the plane of a each finger can be rotated around an adjustment or positioning axis through the plane and normal to the finger axis, a finger drive with which the fingers can be pivoted around the corresponding finger axes and setting or Positioning devices with which the finger assemblies can be moved such that at least two of the planes can be rotated about their corresponding adjustment or positioning axes. The finger drive pivots collectively the fingers around their finger axes.

The invention thus relates to a multiple gripper or a manipulator which has a base, a number of finger assemblies, which are mounted on the base, finger drive devices with which the fingers are optionally opened and can be closed in such a way that each finger moves in a single screw-in plane, and an adjustment or Positioning drive with which the finger assemblies can optionally be adjusted, so that different gripping shapes can be achieved. The invention also includes the operation of the manipulator and working methods of the manipulator »

The invention is to be explained in the following description with reference to the figures of the drawing. It demonstrate

Fig. 1 is a perspective view of an embodiment the invention,

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Pig. Figure 2 is an end view of the device shown in Figure 1;

Figure 3 is a sectional view taken along line 3-3 of Fig. 2, wherein the finger assemblies are in a pack-spread gripping division,

Figure 4 is a sectional view taken along line 4-4 of Figure 3;

Fig. 5 is a side view of a second embodiment the invention,

FIG. 6 is a longitudinal sectional view of that shown in FIG Contraption,

Figure 7 is a sectional view taken along line 7-7 of Fig. 5,

Figure 7A is a sectional view taken along line 7A-7A of Fig. 5,

8 is an enlarged side view of a tip of the embodiment shown in FIG. 5;

FIG. 9 is an edge view taken from line 9-9 of FIG Fig. 8 from,

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

11 to 18 show the embodiment shown in FIG operational.

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These figures and the following description relate to specific embodiments of the invention, and es it should be noted that the invention is not limited to these exemplary embodiments, since it can also be implemented in other forms can be.

Reference is made to FIGS. 1 to H. The manipulator is labeled 110. The manipulator 110 includes a base 111, a number of finger assemblies 112 mounted on the base 111, a finger drive mechanism 114 carried by the base 111, and an adjustment or positioning mechanism 115 carried by the base 111 and which is used to adjust the finger assemblies 112.

Basically, the manipulator is an assembly consisting of a drive and mechanisms for gripping are determined. These mechanisms, called fingers, are attached to the base. Three fingers are considered required and deemed sufficient by the manipulator. While grasping, the fingers can move closer to each other, stir or walk past each other. The manipulator has all drives below the palm surface of the base 111 on. A wrist mechanism (not shown) with multiple degrees of freedom can be used to control the manipulator to carry and move so that it can be approached in any direction to an object.

In the manufacture of manipulators one strives to have an extremely versatile hand with a minimal number of moving parts with a reliable drive system and an optimal number of degrees of freedom. The number of degrees of freedom is considered optimal when the manipulator has all the basic geometric shapes from either side with a minimal number of external control inputs. This basic

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shapes are rectangular and triangular prisms, spheres and cylinders.

The human hand is generally able to perform six basic grips: the lateral grip, the hook grip, the tip handle, the palm handle, the spherical and cylindrical handle. These six basic grips can be reduced to three basic mechanical equivalents because of similarities or similarities on the pack handle, the three-jaw handle and the tip handle, which almost double the basic grips of the hand. To large objects to detect, which the fingers can not include, a spreading grip can be generated, which consists in that the Fingers are inserted into an opening in the object and then bent outward to bring the object inside to capture the opening. The manipulator 110 can perform any of the four handles set forth above.

The base 111, shown in Figures 1 through M , has a generally upper palm plate 121 corresponding to the palm of the human hand, a base plate 122, and a number of spacers 124 which so connect the plates 121 and 122 that they are generally parallel, with the palm plate 121 forming a work surface 125. Cutouts 126 are provided in the palm plate for the finger assemblies 112, which will be further described.

Three finger assemblies 112, designated 112a-112c, are equally spaced between plates 121 and 122 an arranged points around the circle, which is determined by the radius R, which of the common Mittellienie CL of the plates 121 and 122 emanates.

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The finger assemblies 112a to 112c are identical in structure and therefore only one will be described in detail with the same reference numerals being used for all of them. Each assembly 112 has a support arm 130, the has two spaced apart mounting lugs 131. The finger 134 is pivotable between the lugs 131 mounted by means of a swivel joint 135 and can pivot about a roll-in axis CA. The arm 130 is attached to the back of the palm plate 121. The arms 130 of the assemblies 112b and 112c are connected to the plate 121 Connected via swivel joints I36, so that the arm 13Ο around can rotate an adjustment axis PA, which intersects the circle formed from the radius R and which runs perpendicular to the working surface 125 of the plate 121, while the curl axis CA runs perpendicular to the axis PA and is offset by the distance D outwards from this axis. The arm I30 of the Assembly 112a is attached to the rear of plate 121 so that it extends radially. The distance from the circle with the radius R to the axis CA corresponds to the distance D and the orientation of the axis CA is the same as it for the assemblies 112b and 112c has been described. It can be seen that the fingers 134 are traversed by a single curl plane CP can be pivoted through, as FIG. 1 shows, around the roll-in axis CA, which is perpendicular to the Level runs. The planes CPb and CPc of the modules 112b and 112c are pivoted about the adjustment axes PA, the run parallel to the rolling plane CP. In the illustrated embodiment, the axis PA lies within the rolling plane CP.

The fingers 134 may have hinges and articulations. The illustrated fingers, however, are individual elongate links 140 and each link is rotatably supported at 135 and extends outwardly over the working surface 125 of the plate 121. A drive leg 141 is integral with the fin

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ger member 140 is formed and extends under the arm 130 and is used to drive the pinger 13 ² I, as will be described. It should be noted that the fingers 134 are in a normal open position so that the longitudinal axes of the pingers 134 are along a line P substantially perpendicular to the work surface 125. The fingers 13 ¹ I are designed such that they are double-acting, and they can pivot both inwardly and outwardly relative to the line P, as will be described later.

Although a separate drive can be used for each finger assembly 112, a simplified common drive mechanism is shown. The drive mechanism 114 includes a tubular drive rod 150 that is slidably supported in the base plate 122, and this rod can slide along the center line CL of the base plate 111. The drive end 151 of the rod 150 extends into the space between the plates 121 and 122 and the other end is connected to a drive unit 154, such as the working cylinder shown in FIG. A drive adapter 155 is attached to the drive end 151 of the rod 150 in space 152. The outwardly extending drive arms 156a-156c are attached to the adapter 155 so that they are aligned with the arm 130 of each finger assembly 112a-112c. The drive arms 156b and 156c are pivotable about the adjustment axes PA of the assemblies 112b and 112c, so that the arms 156b and 156c pivot together with the arms 130 of the assemblies 112b and 112c. A drive linkage 158 connects each arm I56 to the associated finger 134 so that when the rod I50 moves the adapter 155 and drive arms 156 toward the rear of the palm plate 121, the fingers 134 are closed simultaneously. As the rod 150 and adapter 155 move towards the base plate 122, the fingers 134 are opened to their normal position. A further movement of the rod I50 towards the base plate 122 causes

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that the pingers 13 ^ further outwards on the lines P Spread over it in a spread grip position.

Reference is now made to FIG. It is recognizable, that the finger assemblies 112b and 112c from the three-jaw gripping position, which is shown in solid lines, can be moved into a pack gripping position, which is shown in dashed lines. It should be noted that the spread gripping position can be achieved in any position and that the top gripping position can be easily achieved with very little modification. As shown in FIG. 4, stops 159 can on the plate 121 which limit the movement of the finger assemblies about the axes PA.

The setting of the assemblies 112 can be done in various ways. The mechanism 115 has a drive gear 160 on a drive shaft 16, which is rotatably mounted about the center line CL of the base 111. A drive 162 like the one in The motor shown in FIG. 3 is used to selectively rotate gear 160. The shaft 161 extends through the rod 150, but is rotatable independently of this. The gear l60 meshes directly with the driven gear 164, which is connected to the arm 130 of the finger assembly 112b and is connected to the driven wheel I65 which is connected to the arm I30 of the Finger assembly 112c is connected via a reverse gear 166 in connection. If in the illustration in Fig When gear I60 is rotated counterclockwise, finger assemblies 112b and 112c are simultaneously in the pack gripping position moved and when the gear I60 is reversely rotated, the assemblies 112b and 112c are in their Three-jaw gripping position turned in.

The second embodiment is shown in FIGS. 5 to 18, and it is a "refinement of the manipulator 110. The refined manipulator is loaded with 210

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draws and includes pinger assemblies 212 mounted on a base 211 and is a finger drive mechanism 214 and an adjustment mechanism 215 are provided.

The base 211, shown in FIGS. 5 through 10, generally has an upper palm plate 221 that is similar to that of the The palm of the human hand corresponds to a base plate 222 and a number of spacers 224 that form the plates Connect 221 and 222 together in such a way that these plates run parallel to the palm plate 221, one Work surface 225 is created. There are cutouts 226 in plates 221 and 222 for finger assemblies 212 intended.

Three finger assemblies 212, designated 212a through 212c, are mounted between plates 221 and 222 at equidistant points around a circle which is formed by the radius R, which is extends from the common center line CL of plates 221 and 222, as shown in FIG.

The finger assemblies 212 a to 212 c have a similar structure to the finger assemblies 112 and the finger assemblies have the same structure as one another and therefore only one will be described in detail, with the same reference symbols being used for each finger assembly. Every Finger assembly 212 has a support arm 230 that has two im Mounting lugs 231 arranged at a distance from one another has. The fingers 234 are pivotably mounted between the lugs 231 namely by means of a swivel joint 235 · The pivoting takes place around an axis of rotation CA. The arm 230 is at the rear attached to the palm plate 221. The arms 230 of the finger assemblies 212b and 212c are connected to the plate 221 and connected to the plate 233 by means of swivel joints 236 so that the arms 230 can be pivoted about an adjustment axis PA which intersects the circle with the radius R and which is perpendicular

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runs to the working surface 225 of the plate 221, while the screwing axis CA runs perpendicular to the axis PA and im Distance to the outside around the distance D is arranged. The arm 230 of the assembly 212a is at the rear of the plate 221 mounted so that this arm extends radially. The distance from the circle with the radius R to the axis CA is the same the distance D and the alignment of the axis CA is the same as described for the assemblies 212b and 212c. It can be seen that each finger 234 can be pivoted through a single screw-in plane CP, specifically about the screw-in axis CA that is perpendicular to this plane. The levels CPb and CPc of the modules 212b and 212c are around the Adjustment axes PA pivoted, which runs parallel to the screw-in plane CP. In the illustrated embodiment, the Axis PA within the turning plane CP.

The illustrated pingers 23 ¹ J are individual elongated lever elements 240 which are rotatably mounted on the joint 235 and which extend outwardly beyond the working surface 225 of the plate 221. A drive leg 241 is integrally formed with the lever 240 and extends under the arm 230 and is used to drive the pinger 234. It should be noted that the pingers 234 assume a normal open position such that the longitudinal axes of the pingers 234 are along a line P which is substantially perpendicular to the work surface 225. The fingers 234 are double-acting fingers and they can pivot both inwardly and outwardly relative to the line P, as will be explained.

Each finger assembly 212 carries a tip 300 on the protruding end of the lever 240, as shown in FIGS. 8-10. Each tip 300 is a tip element 30I and an initial setting unit 302 on. The protruding end 242 of the lever 240 has a slot 244 that is generally parallel

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runs to the turning plane CP of the module 212. The tip 301 is generally a plate that has a V-shaped recess 304 at the inner and outer ends, thereby forming two spaced contact points 305 at opposite ends of the tip 301. The points 305 have contact surfaces 307 which capture the object to be gripped. The tip 301 is rotatably mounted in the middle between the lugs 245 in the end 242 of the lever 240, which ^{lie on both sides of the slot 24 1} J, on a pin 306 which is arranged between the lugs 245. The tip 301 is free to rotate about the axis TA of the pin 305 within the slot 244.

The initial setting unit 302 serves to initially set the tip 301 in a known pivot position with respect to the lever 240 to adjust. Various mechanisms can be used for this. The illustrated unit 302 comprises a compression spring 310 and a piston 311. A hole is in end 242 of lever 240 at the bottom of slot 244 is provided and slidably takes the spring 310 and the piston 311 on .. The bore 246 is arranged and designed in such a way that that the spring 310 in an elastic manner the tip 301 in a sets a predetermined direction of rotation. In the illustrated embodiment, the setting is made by the piston in a direction opposite to the clockwise direction of rotation with the piston acting against the tip 301. The direction of rotation, in which the tip 301 is acted upon, can easily be turned around by the fact that the adjustment unit 302 on the other Side of the slot 244 is arranged, as shown in phantom in FIG.

Though separate drive mechanisms for each finger assembly 212, a simplified common drive mechanism is shown. The drive mechanism includes a drive rod 250 that is slidable in the base plate 222 is mounted and along the center line CL

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the base 211 can slide. The drive end 251 of the rod

250 extends into space 252 between plates 221 and 222 and the other end is with a drive unit 25 ^ connected, such as with the piston 255 a double-acting working cylinder 256, which is shown in FIG. A drive adapter 258 is on the drive end

251 of the rod 2 * 10 mounted in space 252 and this adapter 258 can be moved back and forth in space 252 along the center line CL. The drive adapter 258 has two spaced apart mutually arranged, generally circular, parallel plates 259, which in the central portion by a shoulder are connected to one another, so that an annular space 26l, which is used for mounting an arm, is formed between the plates 259 will.

Outwardly extending drive arms 265a to 265c of FIG Finger drive rods 263 are mounted within the annulus and are aligned with the support arms 23Ο. Each drive arm 265 has a generally horizontal leg 266 and an upwardly and outwardly extending forked one Leg 268 on. Each leg 266 is slidably disposed between the plates 259 and is rotatable on a pivot 269 mounted between the plates 259, one rotation around the adjustment axis PA takes place. The leg 266 of the adjustment arm 265a is in a fixed position in alignment with the support arm 23Oa held by a second pin 270 which extends through the leg 266 between the plates 259, as shown in FIGS. 6 and 7. It can be seen that the drive arms 265b and 265c pivot about the axes PA while the arm 265a is held in a fixed position.

Drive linkages 271 connect each drive arm 265 to the Drive leg 241 of the fingers 23 ^ so that the fingers 23 ^ can be opened or closed when the drive adapter 258 within the space 252 by the drive unit

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is moved. The outer end 272 of each linkage 271 is between the ends of the forked leg 268 of the Arm 265, while the forked inner end 27 ^ den Drive leg 241 of the pinger 234 articulated. if the drive adapter 258 to the palm plate 221 of the base 211 is moved towards, the tips 301 are closed on the fingers and vice versa.

It should be noted that the mechanical translation of the drive input for the fingers 23 ** decreases as the fingers move conclude. This is advantageous because the larger objects that are grasped by fingers 234 will usually weigh more than smaller objects and therefore require a greater holding force. A change in holding power is achieved without a change in the pressure medium pressure in cylinder 256. It should be noted that the finger drive linkages 263 are slide crank mechanisms, with the slide or crank axis runs parallel to the screw-in plane of the finger assemblies 212. The movement of linkage 263 is the same Level like the screw-in level of the associated finger assembly 212.

Reference is now made to FIG. It can be seen that the finger assemblies 212b and 212c from the three-jaw gripping position, which is shown in dashed lines, can be brought into a pack gripping position in solid lines is shown. The spread position can be taken in any position ^ and the tip gripping position can be in the Three-jaw gripping fur be taken. The adjustment mechanism 215 causes the assemblies 212b and 212c in their different gripping pitches can be set.

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The adjustment mechanism 215 has two drive sub-assemblies 280 carried by drive arm 265a. One of the subassemblies 280 is in driving communication with the drive arm 265b and one of the subassemblies 280 is in drive communication with drive arm 265c. the Sub-assemblies are arranged and designed in mirror image, so that only one sub-assembly in detail will be described, with the same reference numerals being used for both subassemblies 280.

The subassembly 280, which is connected to the drive arm 265b, includes a fluid cylinder 281 carried by a bracket 282 which is mounted on one side of the horizontal leg 266 of the drive arm 265a. The cylinder 281 is arranged so that its center line CL _n is generally parallel to the center line of the tendon leg 266 of the arm 265a and generally parallel to the working surface 225 of the palm plate 221. This center line is transverse to the leg 266 of the arm 265a by the distance d , offset.

The end of the piston rod 285 of the working cylinder 280 is connected to the leg 266 of the drive arm 265b via a connecting rod 286. One end of the connecting rod is rotatably connected to the end of the piston rod 285 and the other end is rotatably connected to the leg 266 of the arm 265b in a slot 288 formed in the side of the leg 266. The connection is made by means of a drive pin 289. The drive pin 289 is arranged away _{from the adjustment axis PA of the arm 265b by a distance d 2.} When the piston rod 285 is extended, the adjustment arm 265b and finger assembly 212b are moved to their pack gripping position. The distances d 1 and d 1 are dimensioned sufficiently large to ensure that sufficient torque acts on the arm 265b and on the assembly 212b to set them.

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The working cylinders 280 shown are single-acting cylinders and a spring return is provided. Be it notes that double acting cylinders can also be used. The cylinders 280 can be controlled or independently be connected in parallel so that they work synchronously.

The operation of the second embodiment will be explained with reference to Figs. The various modes of operation are shown in these figures. It should be noted that the finger assemblies 212 can be selectively brought into their three-jaw gripping position or pack gripping position by an adjustment mechanism 215. The opening and closing of the fingers 23 ¹ I is carried out by the drive unit 254, the fingers 23 ¹ I being opened and closed at the same time.

FIGS. 11 through I ¹ J show the manipulator 210 grasping a generally rectangular object _{O R.} In this operation, the piston rods 285 of the cylinders 28I are extended to bring the finger assemblies 212b and 212c into the pack gripping position. 11 shows that the fingers 23 ¹ J are closed sufficiently that the innermost contact points 305 just grasp _{the opposite sides of the object O R.} An enlarged view of part of FIG. 11 shows the corresponding position of the tips 301 in FIG. 12. It should be noted that when the fingers 23 ¹ J are closed, the object 0 _{R is} centered between these fingers. The object 0 _R is initially adjacent the work surface 225 of the palm plate 221. When the finger 23 ¹ I move further inwardly to the object to capture 0 _R, then it can be seen that the reaction force F _R at the point 305, the 0 _R is in contact with the article is applied and causes that a MotnenJ; on the tip 301 "is exerted, and uv / ar ent £ mgen"

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set for the action of the setting unit 302 in order to pivot the tip 301 in the direction of the clockwise direction of rotation in the illustration in FIG. 12. As a result, a holding force F _{n is} generated on the object O n, which presses the object towards the face plate 221. This ensures that the object O _R is clamped against the plate 221st The clamping force is generated when the tip 301 rotates in the clockwise direction until the outer contact tip 305 at the inner end of the tip 301 rests against the side of the object O _R. This position is shown in Fig. 13 and an enlarged detail of Fig. 13 is shown in Fig. LH, being shown that both inner contact points 305 bear against the object 0 _R. The manipulator 210 has now sufficiently _{grasped the object O R} so that this object can be picked up.

FIGS. 15 and 16 show how the manipulator 210 _{grasps a spherical object O 13} between the tips 301.

It should be noted that the fingers 23 * J opposite the object 0 " of the base 211 and that the tips 301 center the object Center og opposite the fingertips. It is recognizable, that the tips 30I allow the manipulator can capture relatively small objects. The finger assemblies 212b and 212c are shown in FIGS. and 16 in the three-jaw gripping position.

FIGS. 17 and 18 show how the manipulator 210 handles a large object O ₁ . detected, which has a corresponding opening H ₁ . on -

L L

has, which is sufficiently large so that the fingers 23 ^ can be used in this. The finger assemblies 212b and 212c are shown in their three-jaw gripping position so that the fingers 23 ^J J into opening H ₁ . introduced v / earth and about

L>

their normal open position out into their spread position can be opened in order to grasp the object CL within the opening IL.

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The inner and outer edges E ₁ and E _Q of each lever 2 * 10 of the fingers 23 ** can be used to detect objects, as FIG. 5 shows. The finger assemblies 212b and 212c are in their pack gripping position and grasp a cylindrical object, which is shown in phantom in FIG.

The finger drive cylinder 256 is connected to a source of pressurized fluid connected such that the rod 250 can be selectively extended and retracted. The adjusting cylinder 28l are also connected to pressure medium sources via corresponding control slides in such a way that "the piston rods 285 can optionally be extended and retracted. The cylinders 281 can be operated in parallel for simultaneous operation can be switched or can be switched so that they work independently of each other. The cylinders 2 8l are working independent of cylinder 256.

There have been described special embodiments of the invention, and it should be noted that modifications, additions and the like can be made within the scope of the invention lie.

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Claims (1)

Claims 1.jMultiple gripper or manipulator that performs different gripping movements can perform to grasp objects characterized by a palm base having a working surface, the base having a center line, which is generally perpendicular to the work surface, at least three finger assemblies carried by the base each of the finger assemblies having a bracket on the base and with a finger pivotable on each Holder is mounted about an axis of rotation which is generally perpendicular to the center line, with the finger for The work surface is moved to and from it and a single finger drive device is provided, which is in drive connection with all fingers to simultaneously the. To pivot fingers around these axes of rotation of the fingers in order to grasp the objects. 2. Multiple gripper according to claim 1, characterized in that an adjusting drive in drive connection with the holder stands to selectively adjust the holder so that the fingers in intersecting screw planes in Rotate a first position and in substantially parallel and transversely spaced from one another screwing planes in a second position. 3 · multiple grippers according to claim 2, characterized in that the brackets are fixedly mounted on the base such that two of the brackets are pivotable on the base by spaced apart arranged adjustment axes are mounted which are generally parallel to the center line of the base that the adjustment drive is in drive connection with these two brackets to v / ahlweise the two support arms around the adjustment axes to pivot in order to optionally pivot the two support arms between the first and the second position. 409849/0338 M. Multiple gripper according to claim 1, characterized in that the finger drive has a drive carried by the base, that this drive has an adapter, that a drive unit is provided to selectively the adapter along a drive path which is generally parallel to the center line of the base to move that connecting elements are provided connecting each finger to the adapter so that all fingers simultaneously according to the movement of the adapter be opened and closed. 5. Multiple gripper according to claim ¹ J, characterized in that the drive connection has at least three drive arms which are connected to the adapter and move with it, that one of the drive arms is attached to the adapter in such a way that it is aligned with one of the brackets and that two of the drive arms are rotatably mounted on the adapter about arm adjustment axes which are aligned with the adjustment axes of the two adjustment devices and that linkages are provided in drive connection between the drive arms and the fingers. 6. Multiple gripper according to claim 5> characterized in that the drive unit has a pressure medium cylinder which is carried by the base and which has a piston rod optionally extending along a path generally parallel to the Centerline of the base is movable, the piston rod having a protruding end and the adapter on the protruding end End of the piston rod is mounted. 7. Multiple gripper according to claim 2, characterized in that the adjusting drive has at least one motor from the Adapter is worn and in drive connection with the both drive's arms is available to selectively use the two drive arms and to pivot the two carriers about the adjustment axis. 409849/0338 8. Multiple gripper according to claim 7, characterized in that the motor is a pressure medium motor. 9. Multiple gripper according to claim 8 _S, characterized in that a first pressure medium cylinder is provided which is carried by the adapter and which has a first piston rod which is in drive connection with one of the drive arms in order to selectively pivot one of the two drive arms about its adjustment axis , wherein a second pressure medium cylinder is carried by the adapter, which has a second piston rod which is in drive connection with the other of the two drive arms in order to selectively pivot this drive arm about its adjustment axis. 10. Multiple gripper according to claim 1, characterized in that each pinger of the pinger assemblies has a protruding end, which extends beyond the base and in that the finger assemblies further include tip members which are rotatable mounted in each projecting end of the fingers rotatably about a tip axis generally parallel to the The axis of rotation of the fingers runs, the tips being designed and arranged in such a way that they grasp objects can. 11. Multiple gripper, which is designed so that it can perform various gripping operations in order to grasp objects, characterized by a base defining a centerline, three finger assemblies carried by the base, wherein each finger assembly has a support arm and wherein a finger is rotatably mounted on the support arm about an axis of rotation, the is generally perpendicular to the centerline, with the support arms having the base on three spaced apart Points are arranged around a circle lying in a plane generally perpendicular to the center line extends with the support arm of a finger assumes a fixed position so that this is generally radial to the circle 409849/0338 -.21 - extends and wherein the support arms of the other two fingers are selectively rotatable about their pivot points and about adjustment axes which are generally parallel to the centerline so that the screw-in axes of the other two finger assemblies move along an arcuate path centered with respect to the adjustment axes. 12. Tip assembly for each finger of a manipulator in which the fingers with their protruding ends are within Rotation planes can open and close in order to grasp objects, characterized by a tip component, the contact parts has, with which the objects are detected v / ground and a pivot bearing with which the tip can be pivoted on protruding end of the finger is supported by one The axis can be rotated, which runs perpendicular to the plane of rotation of the fingers, by a rotary movement independent of the finger movement to be able to perform. 13 tip assembly according to claim 12, characterized by means, with which the rotary movement of the Spitzenbau.teile in a first direction and in a second direction opposite to first direction is limited around the axis. lh. Tip assembly according to claim 13 , characterized by an adjustment device with which the tip is elastically biased in the first direction. 15. tip assembly according to claim 1 * 1, characterized in that the tip has two spaced apart contact surfaces which are formed so that the tip member in the second direction against the bias of the adjuster is pressed when one of the contact points comes into abutment against the object. 409849/0338