JP7022964B2 - How to hold the robot hand - Google Patents

Description

The present invention relates to a method for gripping a robot hand.

The robot hands of Patent Document 1 and Patent Document 2 include a palm portion and a plurality of finger portions connected to the palm portion, and it is proposed that the plurality of finger portions grip the object to be grasped on the finger pad side. Has been done. Patent Document 1 and Patent Document 2 also propose that the object to be gripped is gripped by a finger portion facing each other and a palm portion between the finger portions.

6 to 8 show a typical example when the robot hand 10 having the palm portion 20 and the plurality of finger portions 30 and 40 connected to the palm portion 20 grips the object to be gripped H. Here, the finger portions 30, 40 have links 31, 32, 41, 42, and the joints 33, 34, 43, 44 are between the links 31, 41 and the links 32, 42 and the palm portion 20. They are connected by. The finger pads 30a and 40a of the finger portions 30 and 40 are arranged so as to face each other when the link is extended.

FIG. 6 shows an example of gripping a small object H to be gripped by using a finger portion 30 and a palm portion 20. In this case, the links 31 and 32 of the finger portion 30 are bent to form a fixed chain structure in which the fingertip of the link 31 is in contact with the palm portion 20, and the gripped object H entering the fixed chain is a link. It is in contact with the 31, 32, and the palm portion 20 and is gripped in a stable state.

FIG. 7 shows an example in which a large object H to be gripped is gripped by the fingers 30 and 40 and the palm 20. In this case, the palm portion 20, the finger pad portion 30a of the finger portion 30, and the finger pad portion 40a of the finger portion 40 form the side surface of the gripped object H on the palm side, and the finger on the opposite palm side of the gripped object H. Due to the contact of the side surfaces facing the abdomen 30a and 40a, the object to be gripped H is gripped by wrapping around the finger pad.

JP-A-2002-264066, FIGS. 3 (a) to (d), FIGS. 4 (a) to (c), FIGS. 5 (a) to (c), FIGS. 8 (a) to (d), etc. Japanese Unexamined Patent Publication No. 2009-274204, FIGS. 5A to 5E, etc.

The example shown in FIG. 8 is an example in which the robot hand 10 grips the gripped object H, which is larger than the gripped object H shown in FIG. 6 and smaller than the gripped object H shown in FIG. 7.
In this case, the link 31 and the link 32 of the finger portion 30 are bent so as to grip the object H to be gripped in cooperation with the palm portion 20. The finger portion 40 does not grip the object to be gripped, and the fingertip is in contact with the finger back side of the link 31 of the finger portion 30.

As shown in FIG. 8, when the gripped object H is gripped, a gap is formed between the link 31 of the finger portion 30 and the palm portion 20 so that the gripped object H can move. Therefore, the finger portion 30 and the palm portion are formed. As shown by the arrow in FIG. 8, the gripped object H sandwiched between the portions 20 may move from this gap toward the finger portion 40, and it cannot be said that the gripped object H is gripped in a stable state. There's a problem. That is, depending on the size of the object to be gripped, it may be difficult to stably grip the object to be gripped by the robot hand.

An object of the present invention is to provide a gripping method for a robot hand that can grip a robot hand in a firm and stable state even if the size of the object to be gripped is difficult to grip by the conventional method.

INDUSTRIAL APPLICABILITY The present invention is a method for gripping a robot hand including a palm portion and a plurality of fingers connected to the palm portion and having finger pad sides facing each other. One of the fingers is in a state where the fingertip abuts on the palm and bends toward the finger pad, and the back of the finger is directed toward the other finger, and the other finger is a finger. It is bent toward the abdomen so that the object to be grasped is sandwiched between the palm and the back of the finger, the other finger and the palm are in contact with the object to be grasped. It grips the gripped object.

Further, the one finger portion is bent toward the finger pad until the finger tip is in contact with the palm, and the other finger is bent toward the finger pad to hold the gripped object. It has a gripping step of gripping the finger pad of the other finger, the palm, and the finger back of the one finger during or after the finger flexion stage. Is preferable.

Further, the finger portion may have two or more joints.
Further, the finger portion may be provided with two or more.

According to the present invention, even if the size of the object to be gripped is such that it is difficult to grip by the conventional method, the effect of being able to grip the object firmly and stably is obtained.

Schematic diagram of the robot hand of one embodiment. Explanatory drawing of the process of grasping the object to be grasped by a robot hand. Explanatory drawing of the process of grasping the object to be grasped by a robot hand. Explanatory drawing of the process of grasping the object to be grasped by a robot hand. Explanatory drawing of an example of gripping an object to be grasped by a robot hand. Explanatory drawing of an example of gripping an object to be grasped by a conventional robot hand. Explanatory drawing of an example of gripping an object to be grasped by a conventional robot hand. Explanatory drawing of an example of gripping an object to be grasped by a conventional robot hand. Explanatory drawing of the state in which the object to be grasped is grasped by the robot hand of another embodiment. Explanatory drawing of the state in which the object to be grasped is grasped by the robot hand of another embodiment. (A) is a schematic explanatory view of a robot hand adopted in Examples, Reference Examples and Comparative Examples, and (b) is an explanatory diagram of a reference example in which an object to be grasped is gripped by the robot hand. (A) to (c) are explanatory views of the gripping method of the comparative example, and (d) is the explanatory view of the gripping method of the reference example. Explanatory drawing of the gripping method of an Example. (A) and (b) are explanatory views of the gripping method of the reference example, and (c) and (d) are explanatory views of the embodiment. (A) and (b) are explanatory views of the gripping method of the reference example. (A) to (c) are explanatory views of the gripping method of the comparative example, and (d) and (e) are explanatory views of the gripping method of the embodiment.

(Embodiment)
A method of gripping a robot hand according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5. It should be noted that FIGS. 1 to 5 show a two-dimensional representation of the robot hand 10, and when these drawings (paper surfaces) are taken as a plane, the links of the fingers 30 and 40 and the links in the direction orthogonal to the plane. It should be understood that the palm portion 20 has a depth (that is, a thickness, etc.). Further, the lengths of the links 31, 32, 41, and 42 constituting the finger portions 30, 40 are substantially the same length in the present embodiment, but the length of each link is not limited.

The palm portion 20 of the robot hand 10 shown in FIG. 1 is provided as an end effector at the tip of a robot arm (not shown). The palm portion 20 is provided with a contact region 20a that comes into contact with the gripped object H so as to be surface-contactable when gripping the gripped object H (see FIG. 4). In the present embodiment, the gripped object H is cylindrical and has a length in a direction orthogonal to the paper surface like the finger portions 30, 40 and the palm portion 20 of the robot hand 10. Further, the shape of the object to be gripped is not limited.

A pair of finger portions 30 and 40 are arranged on both sides of the palm portion 20 with the contact region 20a interposed therebetween. Since the links and joints of the fingers 30 and 40 are the same as those of the conventional examples described with reference to FIGS. 6 to 8, the same reference numerals are given and the description thereof will be omitted.

Therefore, the finger pads 30a and 40a of the fingers 30 and 40 are arranged so as to face each other when the link is extended, and the finger backs 30b and 40b of the fingers 30 and 40 are arranged so as to face each other. Will be done.

Each link of the finger portions 30 and 40 has joints 33, 34, 43, 44 toward the contact region 20a of the palm portion 20 when an electric motor (not shown) provided corresponding to each link is rotated in the normal direction. When the electric motor is reversed, it can be extended to the opposite side.

Further, the finger pads 30a and 40a of the fingers 30 and 40 are covered with elastic members that can be elastically deformed. Further, if a portion that comes into contact with the object to be gripped H is planned in advance, the elastic member may be arranged only at that portion. Alternatively, there may be an elastic member inside the mechanism of the finger portion.

A method of gripping the object H to be gripped by the robot hand 10 configured as described above will be described. The robot hand 10 is controlled by a teaching playback method.

The control of the robot hand 10 is not limited to the teaching playback method. For example, a distance sensor that detects the distance to the object to be gripped H, a pressure-sensitive sensor that detects the contact pressure with the object to be gripped, and a drive current of a drive motor that drives the link of each finger on the finger and palm. , Various controls may be autonomously performed based on the detection results of various sensors that detect the rotation speed of the drive motor. For example, it can be performed by position control, compliance control (including rigidity control), impedance control, and the like.

Hereinafter, the finger bending step, the gripping step, and the holding step of the present embodiment will be described.
<Finger flexion stage>
In the teaching playback method of the present embodiment, the finger portion 30 is set to execute the finger portion bending step. Initially, as shown in FIG. 1, it is assumed that the links 31, 32, 41, 42 of the fingers 30 and 40 are in the extended state. As shown in FIG. 2, the finger portion 30 bends toward the finger pad portion 30a until the position of the two-dot chain line, that is, the position where the fingertip abuts on the contact region 20a of the palm portion 20. Due to this bending of the finger portion 30, the finger back portion 30b of the finger portion 30 faces the finger pad portion 40a of the finger portion 40.

<Gripping stage and holding stage>
Next, as shown in FIG. 3, the palm portion 20 moves to the gripped object H side, and a robot arm (not shown) operates or is covered until the gripped object H abuts on the contact region 20a. The gripped object H is transferred by a transfer device (not shown) until it comes into contact with the contact region 20a.

When the gripped object H comes into contact with the contact region 20a, the finger portion 40 facing the finger portion 30 bends toward the finger pad 40a, and the gripped object H is moved to the finger of the finger portion 40. It is gripped by the abdominal portion 40a, the finger back portion 30b of the finger portion 30, and the contact region 20a of the palm portion 20 (see FIG. 4). The bending of the finger portion 40 may be started while the finger portion 30 is executing the finger portion bending step.

The contact for gripping the object H to be gripped by the finger portion 40 is not limited after the finger portion bending step of the finger portion 30 is completed, and the finger portion before the finger portion bending stage of the finger portion 30 is completed is not limited. 30 may be in operation. It is preferable that the finger portion 40 is bent from the link 42 on the base side of the link 41 to the gripped object H side first.

After gripping the gripped object H (that is, after the gripping step is completed), the fingers 30, 40 and the palm 20 hold the gripped object H (corresponding to the holding step).
In the above description, after the gripped object H comes into contact with the contact region 20a, the fingers are gripped by the fingers 40 and 30, but when the gripped object H is close to the contact region 20a, the finger portion is used. The finger portion 40 facing the 30 is started to bend toward the finger pad portion 40a, and then the gripped object H is brought into contact with the finger pad 40a of the finger portion 40, the finger back portion 30b of the finger portion 30, and the palm portion 20. It may be gripped by three parties of 20a.

As shown in FIG. 4, in the finger portion 30, the fingertip, which is the tip of the link 31, abuts on the palm portion 20 to form a fixed chain composed of the links 31, 32 and the palm portion 20. The structure is strong against external force, and the object to be gripped H can be gripped firmly and stably by the robot hand 10.

FIG. 5 shows a gripping state of the fingers 40 when the link lengths of the fingers 30 and 40 are not the same as the diameter of the gripped object H and the sizes of the gripped objects H are different. Each is shown. In FIG. 5, the links 31, 32, 41, and 42 are simply shown by lines. In FIG. 5, the links 41 and 42 shown by solid lines are the cases described above. When the link length is the same as the diameter of the object to be gripped H, it will be described later in Examples.

In FIG. 5, when the gripped object H1 larger than the gripped object H is gripped by the links 41 and 42 indicated by the two-dot chain line, the finger back portion 30b of the finger portion 30, and the palm portion 20. It is illustrated that the grip is firmly and stably in the same state as.

Further, in FIG. 5, the links 41 and 42 shown by the alternate long and short dash lines show the case of gripping the gripped object H2 having a size smaller than that of the gripped object H. In this case, the object to be gripped H2 is gripped by the finger pad portions 40a (links 41 and 42) of the finger portion 40 and the contact region 20a of the palm portion 20. In this case, the finger pad 40a (links 41 and 42) of the finger portion 40 is bent so as to be familiar with the gripped object H2, and the gripped object H2 is gripped in cooperation with the palm portion 20. It is possible to stably hold the grip. In this case, the finger portion 30 does not grip the object to be gripped H2, and is in an extended state, for example. The mode in which the finger portion is excluded from the extended state will be described in a later example.

The present embodiment has the following features.
(1) In the method of gripping the robot hand of the present embodiment, of the plurality of finger portions 30 and 40 whose finger pad portions 30a and 40a sides face each other, the finger portion 30 of the finger portion 30 abuts on the palm portion 20 and the finger pad portion. The state is such that the finger back portion 30b is bent toward the 30a side and the finger back portion 30b is directed toward the finger portion 40 side. Then, the finger portion 40 is bent toward the finger pad portion 40a so that the gripped object H is sandwiched between the palm portion 20 and the finger portion 40. Further, the finger back portion 30b, the finger portion 40, and the palm portion 20 of the finger portion 30 come into contact with the gripped object H to grip the gripped object H.

As a result, according to the present embodiment, even if the size of the object to be gripped is a size that is difficult to grip by the conventional method, it is possible to grip the object firmly and stably.
(2) Further, in the method of gripping the robot hand of the present embodiment, in order to obtain the state described in (1) above, the finger portion 30 moves toward the finger pad portion 30a until the fingertip is in contact with the palm portion 20. It has a finger flexion stage to flex.

Further, the finger portion 40 is bent toward the finger pad portion 40a, and the gripped object H is moved to the finger pad 40a and the palm portion 20 of the finger portion 40 during the finger flexion stage or after the finger flexion stage is completed. It has a gripping step of gripping with the finger back portion 30b of 30.

As a result, the state described in (1) above can be obtained by the method performed in the above order. Therefore, even if the size of the object to be gripped is such that it is difficult to grip by the conventional method, it can be easily realized that the object can be gripped firmly and in a stable state.

(3) In the method of gripping the robot hand of the present embodiment, the fingers 30 and 40 are provided with two joints. As a result, according to the present embodiment, the effects of (1) and (2) can be easily realized in a robot hand in which the fingers 30 and 40 have two joints.

(4) In the method of gripping the robot hand of the present embodiment, two fingers are provided. As a result, according to the present embodiment, the effects of (1) and (2) can be easily realized in a robot hand provided with two fingers.

<When the cross-sectional shape of the object H to be gripped is circular>
Next, examples, reference examples, and comparative examples of gripping the robot hand 10 when the sizes of the objects to be gripped H having a circular cross-sectional shape are different will be described. In the robot hands described with reference to FIGS. 11 to 16, the same reference numerals are given to the members corresponding to the configuration of the robot hand according to the embodiment.

In the robot hand 10 described with reference to FIGS. 11 to 16, the link lengths of the links 31, 32, 41, and 42 of the fingers 30 and 40 are the same as each other. In the palm portion 20, the length between the finger portions 30 and 40 is 2 liters.

Further, in FIG. 11A, the joint angle θ1 of the link 42 and the joint angle θ2 of the link 41 are 0 ° ≦ θ1 ≦ 90 °, 0 ° with the clockwise bending (rotation) of the link as the positive direction. The range is ≤θ2≤90 °. Further, the joint angle of the link 32 and the joint angle of the link 31 are similarly in the range of 0 ° to 90 ° with the counterclockwise direction of the link as positive.

In FIG. 11A, K1 holds the joint angle θ2 of the link 41 at 0 °, and the tip (fingertip) of the link 41 when the joint angle θ1 of the link 42 is bent (rotated) from 0 ° to 90 °. ) Shows the movement trajectory. For convenience of explanation, the movement locus K1 is shown ignoring the interference with the joint 34.

Further, in FIG. 11A, K2 first rotates the joint angle θ2 of the link 41 from 0 ° to 90 °, and then bends (rotates) the joint angle θ1 of the link 42 from 0 ° to 90 °. The movement locus of the tip (fingertip) of the link 41 of the above is shown.

An example of gripping a gripped object H having a radius r and a circular cross section with the robot hand 10 will be described with reference to FIGS. 11 (b) and 12 to 14.
(In the case of 1.l / 2 <r <l)
FIG. 11B is a reference example when l / 2 <r <l, and the gripped object H is stably gripped by wrapping the gripped object H by the finger pads and palms 20 of the fingers 30 and 40.

(When 2.r = l / 2)
It is conceivable that the object to be gripped H is gripped by the robot hand 10 as shown in FIGS. 12 (a) to 12 (d).

FIG. 12A is a comparative example when r = l / 2, with the joint angles of the links 32 and 42 set to 0 °, the joint angles of the links 31 and 41 set to 90 °, and the palm portion 20. It is gripped by the finger pad on the tip side of the link 31 and the link 41. In this example, the fingertips of the two fingers 30 and 40 interfere with each other, and stable gripping (wrapping) using the finger pads of both fingers is impossible. Further, when the gripped object H is gripped between the finger pad portion and the palm portion 20 proximal to the fingertips of both finger portions, the gripped object H is not stable, and therefore, as shown by the arrow in FIG. 12A, the gripped object is gripped. There is a risk that H will move to the link 32 or the link 42 side.

FIG. 12B is another comparative example when r = l / 2, where the joint angle of the link 32 is 0 °, the joint angle of the link 31 is 90 °, and the palm portion 20 and the link 31 are set. , 32 is gripped by both finger pads, and the links 41 and 42 are bent to bring the tip (fingertip) of the link 41 into contact with a portion above the central portion in the height direction of the object to be gripped. It was done. In this example, the object to be gripped H cannot be wrapped, and the grip cannot be firmly performed.

FIG. 12C is another comparative example when r = l / 2, where the joint angle of the link 32 is 0 °, the joint angle of the link 31 is 90 °, and the palm portion 20 and the link 31 are set. , 32 are gripped by both finger pads, and the joint angles of the links 41 and 42 of the finger 40 are set to 0 °. In this example, the finger portion 30 and the palm portion 20 are gripped, but since the finger portion 40 side is open, when an external force is applied from the finger dorsal side of the finger portion 30, it is shown in FIG. 12 (c). The object to be gripped H may move in the direction of the arrow, resulting in unstable gripping.

FIG. 12D is a comparative example when r = l / 2. In this example, the link 32 is slightly tilted and the joint angle of the link 31 is refracted by nearly 90 °, the gripped object H is sandwiched between the finger pad and the palm portion 20 of the link 31, and the finger portion of the gripped object H is sandwiched. The link 41 and the link 42 in a state where the 40 side is held at a joint angle of 0 ° are inclined toward the gripped object H side, and the gripped object H is wrapped by the links 41 and 42. In FIG. 12 (d), since the links 41 and 42 are drawn by lines for convenience of explanation, the joints 43 are shown in a state of interfering with the object to be gripped, but the links 41 and 42 are actually shown. Since the joint 43 has a thickness, it should be understood that the joint 43 does not interfere with the gripped object H. In the figure described below, when the joint interferes with the gripped object H or the link and is shown, it should be understood in the same manner as above.

In the example of FIG. 12D, since the object to be gripped H is wrapped by the finger portions 30, 40 and the palm portion 20, stable gripping is possible, but it is compared with the embodiment shown in FIG. 13 to be described later. Then, when an external force acts, it is necessary to generate torque in all joints to counteract this.

FIG. 13 is an example when r = l / 2. In this example, the joint angle of the link 31 is 90 °, the joint angle of the link 32 is 45 °, and a fixed chain consisting of the links 31, 32 and the palm portion 20 is formed to have a structure strong against external force. .. Further, in the finger portion 40 facing the finger portion 30, the link 41 is bent toward the gripped object H side, and the gripped object H is moved to the finger pad portion of the finger portion 40, the finger back portion 30b of the finger portion 30, and the palm. It is gripped by the portion 20. As a result, the robot hand 10 can grip the object to be gripped in a firm and stable state.

In this state, it is sufficient to generate torque facing the external force only on the finger portion 40 side, so that in the case of an actuator that electrically operates the bending and extension of each link, there is an effect of power saving.
In FIG. 13, it is assumed that the radius r of the gripped object H is r = l / 2, but even if the radius r of the gripped object H is l / 2 <r <l. Similar wrapping is possible, and the object to be gripped H can be gripped in a stable state.

(When 3.0 <r <l / 2)
FIG. 14A is a reference example when 0 <r <l / 2. The joint angles of the links 41 and 42 of the finger portion 40 are set to 0 °, the joint angle of the link 31 of the finger portion 30 is set to 0 °, and the link 32 is brought into contact with the finger pad of the link 31 with respect to the gripped object H. By bending the fingers, the finger pads of the links 31 and 42 of the two fingers and the palm 20 wrap the object H to be gripped and grip it in a stable state.

FIG. 14B is a reference example when 0 <r <l / 2, the joint angle of the links 41 and 42 of the finger portion 40 is 0 °, and the joint angle of the link 31 of the finger portion 30 is 90. °, the joint angle of the link 32 is set to 45 °, the tip (fingertip) of the link 31 is in contact with the palm portion 20, and a fixed chain structure is formed. Grasp the object H. In this way, the palm portion 20 and one finger portion 30 wrap the gripped object H and grip it in a stable state.

In addition, in any of the reference examples of FIGS. 14 (a) and 14 (b), it can be gripped only at a specific place according to the diameter of the object to be gripped H.
FIG. 14C is an example when 0 <r <l / 2, the joint angle of the link 31 is 90 °, the joint angle of the link 32 is 45 °, and the links 31, 32 and the palm are set. A fixed chain consisting of the portions 20 is formed to have a structure that is strong against external force. Further, the finger portion 40 bends the links 41 and 42 toward the gripped object H side, and grips the gripped object H by the finger pad portion of the finger portion 40, the finger back portion 30b of the finger portion 30, and the palm portion 20. As a result, the robot hand 10 can grip the object to be gripped in a firm and stable state.

FIG. 14D is an example when 0 <r <l / 2, the joint angle of the link 31 is set to less than 90 °, the joint angle of the link 32 is bent to 45 ° or more, and the link 31 is bent. , 32 and a fixed chain consisting of the palm portion 20 are formed to form a structure that is strong against external force. Further, the finger portion 40 is tilted toward the gripped object H with the joint angle of the link 41 set to 90 °, and the link 42 is tilted so that the finger pads of the links 41 and 42 come into contact with the gripped object H to be gripped. The object H is gripped by the finger pad of the finger 40, the finger back 30b of the finger 30, and the palm 20.

As a result, the gripped object H having the same size can be adjusted to a gripping position different from that shown in FIG. 14 (c), and the gripped object H can be gripped firmly and stably. Similarly, in the embodiment of FIG. 13, the gripping position can be changed by changing the joint angles of the link 31 and the link 32 on the premise that a fixed chain is formed.

In the above embodiment, the following effects are obtained.
(1) Since one finger portion forms a fixed chain, a firm grip is possible.
(2) When an external force is generated, it is sufficient to generate a torque facing the external force only on the other finger side. Therefore, in the case of an actuator that electrically operates the bending and extension of each link, the effect of power saving is effective. be.

(3) The gripping position can be adjusted for objects to be gripped of the same size.
<When the cross-sectional shape of the object H to be gripped is a rectangular shape with rounded corners>
Next, an example of gripping the object H to be gripped having a rectangular cross section with reference to FIGS. 15 and 16 will be described. Let h be the length of the long axis of the object to be gripped H. The configuration of the robot hand 10, the link length, and the length of the palm portion 20 are the same as those of the robot hand 10 described in the examples, reference examples, and comparative examples.

(When l <h <2l)
FIG. 15A is a reference example when l <h <2l. As shown in FIG. 15A, this is an example in which the long axis of the object to be gripped H is gripped so as to stand with respect to the palm portion 20. In this example, the joint angles of the links 32 and 42 of the fingers 30 and 40 are set to 0 °, and the joint angles of the links 31 and 41 are applied to both sides of the upper part of the gripped object H by the finger pads of the links 31 and 41, respectively. By setting the angle of contact, the fingers are gripped by the finger pads of the links 31, 41 of the palms 20, fingers 30, and 40.

Further, FIG. 15B is a reference example when l <h <2l. As shown in FIG. 15B, this is an example in which the short axis of the object to be gripped H is gripped so as to stand against the palm portion 20. In this example, the joint angles of the links 32 and 42 of the fingers 30 and 40 are set to 0 °, and the joint angles of the links 31 and 41 are applied to both sides of the upper part of the gripped object H by the finger pads of the links 31 and 41, respectively. The gripped object H is brought into contact with both sides of the upper portion of the gripped object H at an angle of contact, and the gripped object H is gripped by the finger pads of the links 31, 41, 32, and 42 of the palm portion 20, the finger portions 30, and 40. In this way, the object to be gripped H can be gripped in any of the examples, but in particular, the example of FIG. 15B can be gripped in a more stable state.

(When 0 <h ≤ l)
16 (a) to 16 (c) are comparative examples of gripping when 0 <h ≦ l, and FIGS. 16 (d) and 16 (e) show gripping when 0 <h ≦ l. Is an example of.

The comparative example of FIG. 16A is an example in which h = l and the long axis of the object to be gripped H is gripped with two fingers so as to be held upright with respect to the palm portion 20.
When gripping the object to be gripped with two fingers, it is necessary to prevent the two fingers from interfering with each other. In FIG. 16A, the joint angle of the link 32 is set to 0 °, the joint angle of the link 31 is set to 90 °, the palm portion 20 and both finger pads of the links 31 and 32 are gripped, and the links 41 and 42 are held. It is gripped by bending and abutting the tip (fingertip) of the link 41 on the side portion of the object to be gripped H facing the finger portion 40. In this example, the object to be gripped H cannot be wrapped, and the grip cannot be firmly performed.

Although not shown, when 0 <h <l and the long axis of the object to be gripped H is upright with respect to the palm portion 20 and gripped by the two fingers and the palm portion 20, the following There is a gripping method.
That is, the link 32 is set as a joint angle tilted toward the finger portion 40, the joint angle of the link 31 is set to 90 ° or smaller than 90 °, and the link 31, The finger pads of 32 are brought into contact with each other, and the links 41 and 42 are bent so that the tip (fingertip) of the link 41 is brought into contact with the side portion of the object H to be gripped facing the finger portion 40 and gripped. However, even in this gripping method, the object to be gripped H cannot be wrapped, and the gripping is not firm.

16 (b) and 16 (c) are examples in which the gripped object H is gripped by one finger portion and the palm portion 20 in a state where the gripped object H is laid down on the palm portion 20. As shown in the figure, the joint angle of the link 32 is set to an angle smaller than 90 ° and tilted toward the finger portion 40, and the joint angle of the link 31 is set to 90 ° or an angle smaller than 90 ° with the palm portion 20. The object H to be gripped is gripped by both finger pads of the links 31 and 32, and the joint angle of the links 41 and 42 of the finger portions 40 is set to 0 °. In these examples, the gripping of the finger portion 30 and the palm portion 20 has a degree of freedom in the gripping position, but the side surface of the object to be gripped H along the long axis needs to be brought into contact with the palm portion 20. Further, the tip of the finger portion 30 does not contact the palm portion 20 and does not form a fixed chain, and when an external force is applied from the finger back side of the finger portion 30, the gripped object H moves toward the finger portion 40 side. There is a risk of movement, resulting in unstable grip.

In the embodiment of FIG. 16D, the joint angle of the link 31 is 90 °, the joint angle of the link 32 is 45 °, and a fixed chain consisting of the links 31, 32 and the palm portion 20 is formed with respect to an external force. It has a strong structure. Further, the finger portion 40 bends the links 41 and 42 toward the gripped object H side, and grips the gripped object H by the finger pad of the links 41 and 42, the finger back portion 30b of the finger portion 30, and the palm portion 20. As a result, the robot hand 10 can grip the object to be gripped in a firm and stable state.

In the embodiment of FIG. 16 (e), the joint angle of the link 31 is set to less than 90 °, and the joint angle of the link 32 is bent to 45 ° or more to form a fixed chain consisting of the links 31, 32 and the palm portion 20. It has a structure that is strong against external forces. Further, the finger portion 40 is tilted toward the gripped object H with the joint angle of the link 41 set to less than 90 °, and the link 42 is tilted so that the finger pads of the links 41 and 42 come into contact with the gripped object H. The gripped object H is gripped by the finger pad of the finger 40, the finger back 30b of the finger 30, and the palm 20. Also in this case, the robot hand 10 can grip the object to be gripped in a firm and stable state.

Further, as can be seen in both embodiments, the side portion of the gripped object H along the long axis can be gripped without contacting the palm portion 20, and the gripping position and gripping posture of the gripped object H can be grasped. Adjustment is possible.

In the examples of FIGS. 16 (d) and 16 (e), the following effects are obtained.
(1) Since one finger portion forms a fixed chain, a firm grip is possible.
(2) The gripping position and gripping posture can be adjusted.

The embodiment of the present invention is not limited to the above embodiment, and the configuration may be changed as described below as well as the design change of the above configuration.
-The number of finger links is two in the above embodiment, but may be one or three or more.

-For example, FIG. 9 shows a case where the finger portion 30 has one joint, and the link 31 and the joint 33 are omitted in the configuration of the embodiment, and the tip (finger tip) of the link 32 is substantially L-shaped. It is bent toward the finger portion 40 in a shape. Even in such a configuration, if it operates in the same manner as in the above embodiment, the same effect can be obtained.

FIG. 10 is an example in which the number of links of the finger portion 30 is three, and the link 36 is provided between the links 31 and 32 via the joints 33 and 35. As shown in FIG. 10, the finger portion 30 is bent in a horizontal U-shape when gripping the object to be gripped, and the fingertip of the finger portion 30 is in contact with the contact region 20a. Therefore, the grip of the object to be gripped H can be stably held.

-In the above embodiment, the actuator for bending and extending each link is an electric motor, but the actuator is not limited to the electric motor, and may be other actuators such as solenoids, hydraulic cylinders, pneumatic cylinders and the like. You may change it.

-In the above embodiment, the robot hand 10 has been described in the case of two fingers, but the number of fingers is not limited to two. That is, three or more fingers may be provided. In this case, one or two or more sides facing each other across the gripped object H may be one or two or more, and the other side may also be one or two or more side by side.

-In the case of an object to be gripped H (for example, an electric drill or the like) in which good work cannot be performed unless the gripping posture is appropriate, it is necessary to make adjustments so that the gripping posture is appropriate. According to the embodiment, the gripping posture can be adjusted, and stable holding can be performed even when an appropriate gripping posture is obtained. That is, since the object to be gripped is brought into contact with the back of the finger having a fixed chain structure and held in cooperation with other fingers, it is stably gripped even when a large external force is applied. Is possible.

For example, when the drilling work is performed while the electric drill or the like is gripped by the robot hand as described above, the drilling work is hindered because the drilling work is stably held even if a large reaction force is applied. There is no.

10 ... Robot hand, 20 ... Palm, 20a ... Contact area,
30 ... finger, 30a ... finger pad, 30b ... finger back, 31, 32 ... link,
33, 34 ... joints,
40 ... finger, 40a ... finger pad, 40b ... finger back, 41, 42 ... link,
43, 44 ... Joints, H, H1, H2 ... Objects to be grasped.

Claims (4)

In a method of gripping a robot hand including a palm portion and a plurality of finger portions connected to the palm portion and having finger pad sides facing each other.
Of the plurality of fingers whose finger pad sides face each other, one finger tip abuts on the palm and bends toward the finger pad, and the back of the finger is directed toward the other finger. In the state of
The other finger portion is bent toward the finger pad to hold the object to be grasped with the palm portion.
A method for gripping a robot hand in which the back of one finger, the other finger, and the palm of the finger come into contact with the object to be gripped to grip the object to be gripped. The one finger portion has a finger flexion stage in which the finger tip is flexed toward the finger pad until the finger tip is in contact with the palm portion.
The other finger is bent toward the finger pad, and the gripped object is placed on the finger pad of the other finger, the palm, and during the finger bending step or at the end of the finger bending step. The gripping step of gripping with the back of one of the fingers,
The method for gripping a robot hand according to claim 1. The method for gripping a robot hand according to claim 1 or 2, wherein the finger portion has two or more joints. The method for gripping a robot hand according to any one of claims 1 to 3, wherein the finger portion includes two or more.

Images