JP6432481B2 - Robot hand - Google Patents

Description

  The present invention relates to a robot hand.

  A robot hand configured by connecting a hand portion such as a hand or an end effector and an arm portion via a joint portion is widely used. As an example of a robot hand, for example, Patent Document 1 discloses a five-finger hand arm mechanism having a finger hand mechanism part (hand part), a forearm member (arm part), and a wrist mechanism part (wrist joint part). ing. In Patent Document 1, the end portion on the forearm member side of the finger hand mechanism portion is connected to the wrist joint member of the wrist mechanism portion. The wrist joint member is configured to be rotatable (bent) at a wide angle. With these configurations, the finger mechanism unit (hand unit) can be bent at a wide angle symmetrically with respect to the forearm member in both directions.

Japanese Patent Laid-Open No. 7-285089

  In the robot hand according to Patent Document 1, the arm part side end of the hand part is connected to the wrist joint part. Accordingly, when the hand unit rotates around the wrist joint unit, the hand unit rotates without interfering with the arm unit. Therefore, the rotatable angle of the hand portion is widened.

  On the other hand, when the arm part side end of the hand part is connected to the wrist joint part, the wrist joint part is separated from the hand part in the direction along the surface in contact with the contact part in contact with the object in the hand part. It becomes. In this case, if the hand part (contact part) is brought into contact with an object and the load from the arm part is supported by the hand part, the moment generated at the wrist joint part increases. This corresponds to the distance between the rotation center of the wrist joint part and the position where the force (reaction force from the object) acts on the contact part by increasing the distance between the contact part of the hand part and the wrist joint part. This is because the moment arm becomes large.

  As described above, when the moment generated at the wrist joint portion increases, the torque required for a drive unit (for example, a motor) provided at the wrist joint portion may increase. As a result, the drive unit and the wrist joint unit are enlarged, and the size of the robot hand may be increased accordingly.

  The present invention provides a robot hand that can reduce the required output of the drive unit of the wrist joint while ensuring the rotatable angle of the hand.

  A robot hand according to the present invention is provided with an arm part, a hand part having a contact part that comes into contact with an object in the outside world, and a first end part of the hand part on the arm part side provided at a tip of the arm part. A wrist joint part rotatably supporting the hand part via a link part provided on the wrist joint part having a drive part for driving the hand part, and at the tip of the arm part, the arm part A load support portion that supports a load from the rotation portion, and the center of rotation of the hand portion at the wrist joint portion extends from the contact portion in a direction along a virtual plane that is a virtual plane in contact with the contact portion. The distance from the rotation center to the tip of the load support portion is shorter than the length from the rotation center to the root portion of the link portion, and is the load support portion in contact with the virtual plane? Or exchange That the first region is present, the first region than the contact portion, near the center of rotation in the direction of the load on the virtual position projected on the virtual plane.

  Since the length from the rotation center to the tip of the load support part is shorter than the length from the rotation center to the base part of the link part, the load support part does not interfere with the hand part, so the rotation angle of the hand part is secured. be able to. Furthermore, since the first region is closer to the virtual position than the contact portion, the moment arm can be made smaller, so that the moment at the wrist joint portion can be suppressed, thereby reducing the required torque of the drive portion. Is possible. Therefore, the robot hand according to the present invention can reduce the required output of the drive unit of the wrist joint while ensuring the rotatable angle of the hand.

Preferably, the load support portion is provided so as to protrude from the wrist joint portion.
When the load support portion is provided on a structural member whose posture changes with the rotation of the hand portion, the load support portion also changes with the rotation of the hand portion, thus preventing interference of the load support portion. For this reason, it is necessary to make sure that there is no other structural member in the range of movement of the load support portion accompanying the posture change. In this case, it may be necessary to increase the size of the wrist joint. On the other hand, the posture of the wrist joint does not change with the rotation of the hand. Therefore, by providing a load support part at the wrist joint part, it is possible to prevent the load support part from interfering with structural members around the wrist joint part when the hand part is rotated without enlarging the wrist joint part. Is done. That is, the present invention can suppress an increase in the size of the wrist joint.

Preferably, the load support portion is made of an elastic material.
By adopting the above-described configuration, the load support portion can come into contact with a surface when it comes into contact with an object in the outside world, so that the surface pressure in the contact area with the object can be suppressed.

Preferably, a curved portion is provided at an end of the load support portion.
With the above-described configuration, it is possible to suppress the surface pressure in the contact area with the object without depending on the angle at which the load support portion contacts the object in the outside world.

  ADVANTAGE OF THE INVENTION According to this invention, the robot hand which can reduce the request | requirement output of the drive part of a wrist joint part can be provided, ensuring the rotatable angle of a hand part.

It is a figure which shows the robot hand concerning Embodiment 1. FIG. FIG. 3 is a perspective view illustrating details of the vicinity of a hand portion of the robot hand according to the first exemplary embodiment. It is the front view which showed the detail of the vicinity of the hand part of the robot hand concerning Embodiment 1. FIG. It is the front view which showed the detail of the vicinity of the hand part of the robot hand concerning Embodiment 1. FIG. It is a figure which shows the state which the hand part of the robot hand concerning Embodiment 1 is rotating around the bending axis. It is a figure which shows the state which the hand part of the robot hand concerning Embodiment 1 contacted with the object. It is a figure which shows the robot hand concerning the 1st comparative example. It is a figure which shows the robot hand concerning the 2nd comparative example. It is the perspective view which showed the detail of the vicinity of the hand part of the robot hand concerning Embodiment 2. FIG. It is the front view which showed the detail of the vicinity of the hand part of the robot hand concerning Embodiment 2. FIG. It is the perspective view which showed the detail of the vicinity of the hand part of the robot hand concerning Embodiment 3. FIG. It is the front view which showed the detail of the vicinity of the hand part of the robot hand concerning Embodiment 3. FIG. 5 is a diagram illustrating a state in which a contact portion and a load support portion of the hand portion of the robot hand according to the first embodiment are in contact with the surface of the object when the surface of the object in the outside world is not flat.

(Embodiment 1)
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating a robot hand 1 according to the first embodiment. The robot hand 1 is an articulated robot having a plurality of joints. Although FIG. 1 shows an example in which the robot hand 1 is applied to a manipulator, the robot hand 1 according to the first embodiment can also be applied to an arm of a humanoid robot.

  The robot hand 1 includes a base part 2, a shoulder part 4, a shoulder joint part 6, an upper arm part 8, an elbow joint part 10, a forearm part 12, a wrist joint part 20, a hand link part 16, and a hand part 14. The base part 2 is fixed to the base 900. The shoulder 4 is provided so as to protrude from the base 2 vertically, for example.

  The shoulder joint portion 6 is provided between the shoulder portion 4 and the upper arm portion 8. The shoulder joint portion 6 rotatably supports the upper arm portion 8. The shoulder joint portion 6 has a single-axis, two-axis, or three-axis rotation shaft, and a motor that rotationally drives the rotation shaft. For example, the shoulder joint portion 6 rotatably supports the upper arm portion 8 around an axis perpendicular to the paper surface. The elbow joint 10 is provided between the upper arm 8 and the forearm 12. The elbow joint part 10 supports the forearm part 12 rotatably. The elbow joint unit 10 has one, two, or three axes of rotation, and a motor that rotates the rotation axis. For example, the elbow joint 10 supports the forearm 12 so as to be rotatable about an axis perpendicular to the paper surface.

  The wrist joint portion 20 is provided between the forearm portion 12 (arm portion) and the hand portion 14. The wrist joint portion 20 is provided at the tip of the forearm portion 12. The wrist joint portion 20 supports the hand portion 14 through the hand link portion 16 so as to be rotatable. The wrist joint unit 20 has one, two, or three rotation axes. For example, the wrist joint portion 20 supports the hand portion 14 rotatably around at least an axis (bending axis) perpendicular to the paper surface.

  The hand part 14 has a contact part 14a that comes into contact with an object 90 in the outside world. The robot hand 1 performs some work by bringing the contact portion 14a into contact with the object 90. Further, for example, the base unit 2 is provided with a control unit 3 that controls the operation of the robot hand 1 by controlling the joint angle of each joint unit (shoulder joint unit 6, elbow joint unit 10 and wrist joint unit 20). It has been. The hand part 14 and the wrist joint part 20 will be described in detail below.

  FIG. 2 is a perspective view illustrating details of the vicinity of the hand unit 14 of the robot hand 1 according to the first exemplary embodiment. 3 and 4 are front views showing details of the vicinity of the hand portion 14 of the robot hand 1 according to the first embodiment. Further, FIG. 2 shows an example in which the contact portion 14a of the hand portion 14 is configured as a plane, but the contact portion 14a does not need to be configured only as a plane. For example, the contact portion 14a may have a curved surface like a human palm.

  Here, the virtual plane 40 illustrated in FIGS. 3 and 4 is a virtual plane in contact with the contact portion 14a. FIG. 3 shows a state where the angle θh of the virtual plane 40 with respect to the forearm portion 12 is 90 degrees. In other words, FIG. 3 shows a state in which the forearm portion 12 is perpendicular to the hand portion 14. FIG. 4 shows a state where the angle θh of the virtual plane 40 with respect to the forearm portion 12 is smaller than 90 degrees. Note that the virtual line 40 a is a virtual line parallel to the virtual plane 40.

  The wrist joint unit 20 is composed of a gimbal mechanism having two rotation axes that are orthogonal to each other. Specifically, the wrist joint unit 20 includes a bending shaft 22 and a swing shaft 24 that are orthogonal to each other. The wrist joint unit 20 includes a motor 22a and a motor 24a that rotate and drive the bending shaft 22 and the swing shaft 24, respectively. The wrist joint portion 20 has two surfaces provided with both ends of the bending shaft 22, two surfaces provided with both ends of the swing shaft 24, a surface on the forearm portion 12 side, and a surface on the hand portion 14 side. It consists of a substantially hexahedron.

  Two hand link portions 16 (links) are provided on the end portion 14 b (first end portion) of the hand portion 14 on the side of the forearm portion 12 so as to sandwich the wrist joint portion 20. The two hand link portions 16 are fixed in the vicinity of both ends of the bending shaft 22. When the bending shaft 22 is rotated by the rotational driving force (torque) of the motor 22a, the hand link portion 16 rotates around the bending shaft 22, so that the hand portion 14 uses the center of the bending shaft 22 as the rotation center P in FIG. Rotate (bend) in the direction of arrow A. That is, the motor 22a rotates the hand unit 14 in the direction of arrow A.

  Two forearm link portions 13 are provided on the end portion 12 b of the forearm portion 12 on the hand portion 14 side so as to sandwich the wrist joint portion 20. The two forearm link portions 13 are respectively fixed in the vicinity of both ends of the swing shaft 24. When the swing shaft 24 is rotated by the rotational driving force (torque) of the motor 24a, the hand link portion 16 rotates around the swing shaft 24. Therefore, the hand portion 14 uses the center of the swing shaft 24 as the rotation center Q. Rotate (swing) in the direction of arrow B in FIG. That is, the motor 24a rotates the hand unit 14 in the direction of arrow B.

  Further, the width W1 of the hand link portion 16 is narrower than the interval between the two forearm link portions 13. Similarly, the width W2 of the forearm link portion 13 is narrower than the interval between the two hand link portions 16. Thereby, when the hand part 14 rotates around the bending axis | shaft 22 or the rocking | fluctuation axis | shaft 24, it is suppressed that the forearm link part 13 and the hand link part 16 mutually interfere. Therefore, the rotatable angle of the hand unit 14 can be widened.

  Further, as shown in FIG. 3, the rotation center P of the bending shaft 22 of the hand unit 14 is the end of the hand unit 14 in the direction along the virtual plane 40, that is, in the direction parallel to the virtual plane 40 (direction of the arrow C <b> 1). It is in a position away from the part 14b. In other words, the rotation center P is at a position deviated from the direction perpendicular to the virtual plane 40 of the contact portion 14a (the direction of the arrow C2). With such a configuration, the hand unit 14 can be prevented from interfering with the forearm unit 12 as compared with a second comparative example to be described later, so that the rotatable angle of the hand unit 14 can be widened.

  In the first embodiment, a load support portion 30 is provided at an end portion 20a (second end portion) which is a surface of the wrist joint portion 20 on the hand portion 14 side (that is, a surface opposite to the forearm portion 12). Is provided. The load support portion 30 supports a load Fa (compression force) applied to the forearm portion 12 by the operation of the shoulder joint portion 6 and the elbow joint portion 10 at the tip of the forearm portion 12. Although specifically described later, when the contact portion 14 a of the hand unit 14 contacts the object 90, the load support unit 30 can also contact the object 90. Thereby, the load Fa from the forearm part 12 can be supported. In the first embodiment, the load support portion 30 is provided so as to protrude from the end portion 20 a of the wrist joint portion 20.

  When a virtual line La passing through the rotation center P along the longitudinal direction of the forearm portion 12 is defined, the virtual line La substantially coincides with a straight line connecting the rotation center of the elbow joint portion 10 and the rotation center P of the wrist joint portion 20. . The direction of the virtual line La coincides with the direction of the load Fa applied to the forearm portion 12. In addition, the angle θh matches the angle between the virtual plane 40 and the virtual line La. Here, in the first embodiment, the imaginary line La passes through the wrist joint portion 20, and therefore the imaginary line La can pass through the load support portion 30.

  The length D1 from the rotation center P of the bending shaft 22 of the hand portion 14 to the tip 34 of the load support portion 30 is greater than the length D2 from the root portion 16a of the hand portion 14 of the hand link portion 16 to the rotation center P. Also short. Thereby, even when the hand part 14 rotates around the rotation center P, the load support part 30 does not interfere with the hand part 14. Therefore, the rotatable angle of the hand part 14 is ensured, that is, the load support part 30 is prevented from hindering the rotation of the hand part 14.

  In addition, the thickness of the load support portion 30 is large enough to withstand the load Fa from the forearm portion 12. On the other hand, the thickness of the load support part 30 is thin enough not to interfere with the hand link part 16 and the forearm link part 13. Thereby, the rotatable angle of the hand part 14 is ensured, and the load support part 30 can support the load Fa from the forearm part 12.

  The material of the load support unit 30 may be formed of a flexible material (elastic material) such as sponge, rubber, or urethane. Since the load support portion 30 is formed of an elastic material, the load support portion 30 is compressed and deformed when contacting the object 90. Thereby, the load support part 30 contacts the object 90 in a surface. Further, the larger the area of the surface when the load support portion 30 contacts the object 90, the smaller the surface pressure. The load support unit 30 has such flexibility that the surface pressure when the load support unit 30 contacts the object 90 is sufficiently small with respect to the strength of the object 90. Further, the load support portion 30 may be formed of a material having a friction coefficient that does not slip with respect to the object 90 when it comes into contact with the object 90. Further, the load support portion 30 is formed of a material that can withstand a shearing force and a compressive force generated by a load Fa applied to the object 90 when it comes into contact with the object 90.

  As shown in FIGS. 3 and 4, the load support portion 30 protrudes to the extent that it makes contact with or intersects with the virtual plane 40. Preferably, since the load support unit 30 intersects with the virtual plane 40, the load support unit 30 can come into contact with the surface when the load support unit 30 comes into contact with the object 90. The pressure can be suppressed. FIG. 3 shows a case where the angle θh is 90 degrees. As shown in FIG. 4, even if the angle θh is not 90 degrees, the load support unit 30 is connected to the virtual plane 40. Configured to touch or cross. That is, there is a region (first region 30 a) where the load support unit 30 contacts or intersects the virtual plane 40. The first region 30 a is a point (or a line) when the load support unit 30 is in contact with the virtual plane 40, and a surface when the load support unit 30 intersects the virtual plane 40. The extent to which the load support unit 30 protrudes from the virtual plane 40 is appropriately determined according to the optimal posture of the robot hand 1 when the contact unit 14a (and the load support unit 30) of the hand unit 14 contacts the object 90. Can be.

  Further, a curved portion 32 is provided at the end of the load support portion 30. The bending portion 32 is formed in an arc shape when viewed from the direction along the bending axis 22 (direction perpendicular to the paper surface), and is linear when viewed from the direction along the swing axis 24 (left and right direction in FIG. 3). Is formed. That is, the curved portion 32 is formed in a shape formed by cutting a cylinder along the height method. In other words, the curved portion 32 is formed in a “barrel-vaulted shape”. In this case, the bending of the bending portion 32 corresponds to a part of the side surface of the cylinder. Desirably, the arc shape of the bending portion 32 is formed by an arc centered on the rotation center P. In other words, the bending portion 32 is formed such that a cross section by a plane perpendicular to the bending axis 22 is an arc centered on the rotation center P.

  FIG. 5 is a diagram illustrating a state in which the hand portion 14 of the robot hand 1 according to the first embodiment is rotating around the bending axis 22. In FIG. 5, the hand unit 14 rotates from the state (a) (corresponding to the state of FIG. 3) to the state (b) (corresponding to the state of FIG. 2), and further to the state (c). It is rotating. In other words, assuming that the longitudinal direction of the forearm portion 12 is downward, the contact portion 14a of the hand portion 14 is directed downward (a), directed laterally (b), and directed upward. Rotate to shift to (c).

  Here, as described above, the rotation center P of the bending shaft 22 of the hand portion 14 is located away from the end portion 14b of the hand portion 14 in the direction along the virtual plane 40 in contact with the contact portion 14a. Further, as described above, the load support unit 30 is configured in a size that does not interfere with the hand unit 14, the hand link unit 16, and the forearm link unit 13. Therefore, the load support portion 30 does not hinder the rotation of the hand portion 14. Therefore, a rotatable angle of the hand portion 14 (an angle of θa or more shown in FIG. 5) can be ensured.

  Here, if the load support portion 30 is not provided with the bending portion 32 and has a rectangular shape, depending on the angle of the hand portion 14 and the size of the load support portion 30, the corner portion of the load support portion 30 may be a hand. There is a possibility of interfering with the part 14 (the root part 16a of the hand link part 16). On the other hand, in the present embodiment, since the load support portion 30 is provided with the curved portion 32, the load support portion 30 has an angle that interferes with the hand portion 14 (the root portion 16a of the hand link portion 16). There is no part. Therefore, the rotatable angle of the hand part 14 can be ensured more reliably. Furthermore, since the bending portion 32 is formed in an arc shape with the rotation center P as the center, the bending of the bending portion 32 is along the rotation locus of the root portion 16a of the hand link portion 16. Therefore, the rotatable angle of the hand portion 14 can be ensured more reliably.

  As shown in FIGS. 3 and 4, a position where the rotation center P is projected onto the virtual plane 40 in the direction of the load Fa when viewed from a direction parallel to the bending axis 22 is defined as a virtual position P1. That is, the virtual position P1 corresponds to the intersection of the virtual plane 40 and the virtual line La. At this time, the distance between the contact portion 14a and the virtual position P1 on the virtual plane 40 is a distance D3. In addition, the reference | standard in the contact part 14a of the distance D3 is made into the edge part by the side of the wrist joint part 20 of the contact part 14a.

  In the state shown in FIG. 3, since the angle θh is 90 degrees, the virtual position P1 is included in the first region 30a. Accordingly, the distance (D4) between the first region 30a and the virtual position P1 can be regarded as substantially zero. Therefore, D3> D4. If the distance between the virtual position P1 and the point farthest from the virtual position P1 in the first region 30a is the distance D4, D3> D4. Accordingly, in FIG. 3, the first region 30a where the load support portion 30 contacts or intersects the virtual plane 40 is closer to the virtual position P1 than the contact portion 14a.

  In the state shown in FIG. 4, the virtual position P <b> 1 is out of the first region 30 a due to the forearm 12 being inclined. Even in this case, D3> D4. This can be achieved even when an arbitrary point in the first region 30a is used as the reference of D4. Therefore, in the present embodiment, the first region 30a where the load support portion 30 contacts or intersects the virtual plane 40 is closer to the virtual position P1 than the contact portion 14a. That is, in the first embodiment, since the load support portion 30 is provided at the wrist joint portion 20 including the rotation center P, when the load support portion 30 contacts or intersects the virtual plane 40 at the angle θh, the first The region 30a is closer to the virtual position P1 than the contact portion 14a.

  FIG. 6 is a diagram illustrating a state in which the hand unit 14 of the robot hand 1 according to the first embodiment is in contact with the object 90. In FIG. 6, as shown in FIG. 4, the angle θh of the forearm portion 12 (virtual line La) with respect to the virtual plane 40 is less than 90 degrees. Here, the load Fa from the forearm portion 12 is applied toward the rotation center P along the virtual line La. In this case, the load support portion 30 is in contact with the surface 90a of the object 90, and a contact region 30c is formed. Thereby, the load support part 30 supports the load Fa.

  Here, since the load support unit 30 according to the present embodiment is formed of an elastic material, the load support unit 30 contacts the object 90 with a surface. Therefore, the surface pressure in the contact region 30c can be suppressed. Moreover, the length by which the load support part 30 protrudes from the virtual plane 40 may vary depending on the angle θh. However, when the load support portion 30 actually contacts the object 90, the difference is absorbed because the load support portion 30 is formed of an elastic material. That is, at the angle θh where the load support portion 30 protrudes from the virtual plane 40 is long, when the load support portion 30 comes into contact with the object 90, the load support portion 30 is greatly compressed and deformed. Thereby, the contact state of the contact part 14a and the load support part 30 can be stabilized irrespective of the angle θh.

  In addition, if the load support portion 30 is not provided with the bending portion 32 and has a rectangular shape, the corner portion of the load support portion 30 contacts the surface 90 a of the object 90 depending on the angle θh of the forearm portion 12. Sometimes. When the corner contacts the surface 90a of the object 90, the contact area 30c becomes very small. Thereby, the surface pressure in the contact region 30c increases, and the object 90 may be damaged.

  On the other hand, since the curved portion 32 is provided in the load support portion 30 according to the present embodiment, there is no corner portion at the end portion of the load support portion 30 that makes the contact region 30c small. Therefore, it is possible to suppress the surface pressure in the contact region 30c without depending on the angle (angle θh) at which the load support unit 30 contacts the surface 90a of the object 90. Furthermore, since the curved portion 32 is formed in an arc shape centered on the rotation center P, the shape of the contact region 30c can be made closer to a constant without depending on the angle θh. Thereby, even when the angle θh changes, the area of the contact region 30c can be stabilized. Therefore, the surface pressure in the contact region 30c can be stabilized. In addition, this makes it possible to increase the area of the contact region 30c without depending on the angle (angle θh) at which the load support portion 30 contacts the surface 90a of the object 90. Therefore, the surface pressure in the contact region 30c can be more reliably suppressed.

  Here, when the load support portion 30 comes into contact with the surface 90a of the object 90, a reaction force Fb against the load Fa is applied from the surface 90a of the object 90 to the action point 30p inside the contact region 30c. Here, since the reaction force Fb and the load Fa are balanced in the direction of the imaginary line La, the direction of the reaction force Fb is parallel to the direction of the load Fa but in the opposite direction, and the magnitude of the reaction force Fb is It is equal to the magnitude of the load Fa.

  On the other hand, the direction of the reaction force Fb is along the virtual line Lb. Here, as shown in FIG. 6, when the angle θh of the forearm portion 12 (virtual line La) with respect to the virtual plane 40 is smaller than 90 degrees, the virtual line Lb deviates from the virtual line La. This shift becomes the moment arm M1, and a moment (counterclockwise direction in the state of FIG. 6) is generated in the forearm portion 12. Therefore, a force that falls in the direction of arrow E acts on the forearm portion 12. In order to resist the force in the direction of the arrow E, the motor 22a of the wrist joint unit 20 generates a torque T1 on the bending shaft 22 in the counterclockwise direction. Thereby, since the hand part 14 presses the object 90, it is suppressed that the forearm part 12 falls in the direction of arrow E. That is, the angle θh is maintained at the angle shown in FIG. The torque T1 is output according to the load Fa and the moment arm M1.

  Here, when the distance between the virtual position P1 and the action point 30p is D4, the moment arm M1 is represented by D4 * sin θh. The moment generated in the forearm 12 is expressed as Fa * M1 = Fa * D4 * sin θh. When the maximum torque of the motor 22a is T1max, T1max> Fa * M1 (= Fa * D4 * sin θh) is satisfied.

(Comparative example)
Here, a comparative example with the present embodiment will be described.
FIG. 7 is a diagram showing a robot hand 100 according to a first comparative example. The robot hand 100 according to the first comparative example is different from the robot hand 1 according to the first embodiment in that the load supporting unit 30 is not provided. Other configurations of the robot hand 120 are substantially the same as those of the robot hand 1 according to the first embodiment. Further, the angle θh in FIG. 7 is the same as the angle θh in FIG.

  Since the robot hand 100 does not have the load support portion 30, when the contact portion 14a of the hand portion 14 comes into contact with the object 90 with the load Fa applied from the forearm portion 12, the hand portion 14 supports the load Fa. . At this time, a reaction force Fb is applied to the contact portion 14a. For comparison with the first embodiment, the reaction force Fb is applied to the end of the contact portion 14a on the wrist joint portion 20 side. Here, since the reaction force Fb and the load Fa are balanced in the direction of the imaginary line La, the direction of the reaction force Fb is parallel to the direction of the load Fa but in the opposite direction, and the magnitude of the reaction force Fb is It is equal to the magnitude of the load Fa.

  On the other hand, the direction of the reaction force Fb is along the virtual line Lb. Here, as shown in FIG. 7, the rotation center P is located away from the end 14 b of the hand unit 14 in the direction along the virtual plane 40 (the direction of the arrow C <b> 1). As a result, as described above, there is a distance D3 between the virtual position P1 and the end portion 14b. Therefore, the virtual line Lb deviates from the virtual line La. This deviation becomes the moment arm M2. Here, as shown in FIG. 7, the contact state between the contact portion 14 a and the object 90 is maintained so that the structural member (the forearm link portion 13 and the like) of the forearm portion 12 and the wrist joint portion 20 do not contact the object 90. In order to achieve this, the motor 22a of the wrist joint 20 generates a torque T2 in the counterclockwise direction on the bending shaft 22. Accordingly, the hand unit 14 presses the object 90 and the angle θh is maintained, so that the contact state between the contact unit 14a and the object 90 is maintained. The torque T2 is output according to the load Fa and the moment arm M2.

  When the distance between the virtual position P1 and the end portion 14b is D3, the moment arm M2 is represented by D3 * sin θh. The moment around the bending axis 22 is expressed as Fb * M2 = Fa * D3 * sin θh. When the maximum torque of the motor 22a is T2max, T2max> Fb * M2 (= Fa * D4 * sin θh) is satisfied.

  Here, as described above, since D3> D4, the moment arm M1 is smaller than the moment arm M2. Therefore, the moment in the state shown in FIG. 6 is smaller than the moment in the state shown in FIG. This is because the first region 30a is closer to the virtual position P1 than the contact portion 14a. And torque T1 required in order to maintain the state shown in FIG. 6 becomes smaller than torque T2 for maintaining the state shown in FIG. In other words, the robot hand 1 according to the first embodiment includes the load support portion 30, and the first region 30a is closer to the virtual position P1 than the contact portion 14a. Therefore, the moment arm can be reduced. Therefore, the moment in the wrist joint part 20 can be suppressed. Therefore, the robot hand 1 according to the first embodiment can reduce the required torque (required output) of the motor 22a as compared with the robot hand 100 according to the first comparative example. Thereby, the increase in the size of the motor 22a and the wrist joint part 20 can be suppressed.

  FIG. 8 is a diagram showing a robot hand 120 according to a second comparative example. The robot hand 120 includes a forearm portion 12, a joint portion 122, and a hand portion 124. The joint portion 122 is provided with a bending shaft 22, and the hand portion 124 rotates in the direction of arrow A when the bending shaft 22 is rotationally driven by a motor built in the joint portion 122. In addition, the hand unit 124 includes a contact unit 124 a that contacts the object 90.

  As shown in FIG. 8, the rotation center P of the bending shaft 22 of the hand portion 124 is away from the end portion 124b of the hand portion 124 in the direction along the virtual plane 40 in contact with the contact portion 124a (the direction of the arrow C1). I don't mean. In other words, the rotation center P is in a direction perpendicular to the virtual plane 40 of the contact portion 124a (the direction of the arrow C2). With such a configuration, when the load Fa is applied to the forearm portion 12, the virtual line La can pass through the contact portion 124a, so the direction of the reaction force Fb applied to the contact portion 124a is on the virtual line La. Thereby, in the 2nd comparative example, the moment by load Fa does not generate | occur | produce. Therefore, in the second comparative example, it is not necessary to increase the required torque of the motor in order to support the load Fa.

  However, since the rotation center P is in the direction perpendicular to the virtual plane 40 of the contact portion 124a (the direction of the arrow C2), when the hand portion 124 rotates in the direction of the arrow A, the hand portion 124 interferes with the forearm portion 12. . Therefore, as compared with the robot hand 1 according to the first embodiment, the rotatable angle of the hand unit is reduced.

  On the other hand, the robot hand 1 according to the first embodiment can secure the rotatable angle of the hand unit 14 as described above. Furthermore, as described above, the robot hand 1 according to the first embodiment can reduce the required torque of the motor for supporting the load Fa. That is, in the robot hand 1 according to the first embodiment, it is possible to achieve both the securing of the rotatable angle of the hand portion 14 and the reduction of the required torque of the motor of the wrist joint portion 20.

(Embodiment 2)
Next, a second embodiment will be described. In the robot hand 1 according to the first embodiment, the wrist joint unit 20 has two rotation axes (the bending axis 22 and the swing axis 24). On the other hand, the robot hand 1 according to the second embodiment is different from the robot hand 1 according to the first embodiment in that the wrist joint has one rotation axis. Since other components of the robot hand 1 according to the second embodiment are substantially the same as those of the robot hand 1 according to the first embodiment, the description thereof is omitted.

  FIG. 9 is a perspective view illustrating details of the vicinity of the hand portion 14 of the robot hand 1 according to the second exemplary embodiment. FIG. 10 is a front view showing details of the vicinity of the hand portion 14 of the robot hand 1 according to the second embodiment. In the following description, components that are substantially the same as those in the first embodiment are denoted by the same reference numerals.

  The robot hand 1 according to the second embodiment includes at least a forearm portion 12, a wrist joint portion 50, a hand link portion 16, and a hand portion 14. The wrist joint part 50 is provided between the forearm part 12 and the hand part 14 and supports the hand part 14 via the hand link part 16 so as to be rotatable. The wrist joint unit 50 includes a bending shaft 22 and a motor 22a that rotates the bending shaft 22 in the direction of arrow A. The wrist joint portion 50 is fixed to the end portion 12 b of the forearm portion 12. The remaining configuration of the wrist joint 50 is the same as that of the wrist joint 20. Further, the end 50a (second end) which is the surface of the wrist joint portion 50 on the hand portion 14 side is provided with a load support portion 30 similar to that of the first embodiment. The load support part 30 has the same curved part 32 as in the first embodiment.

  As in the robot hand 1 according to the second embodiment, even if the rotation axis of the hand unit 14 is one axis, the relationship between the hand unit 14, the bending shaft 22, and the load support unit 30 is the same as in the embodiment. 1 is the same as the case where the rotation axis is two axes. Therefore, the robot hand 1 according to the second embodiment can achieve substantially the same effect as the robot hand 1 according to the first embodiment as described above.

(Embodiment 3)
Next, Embodiment 3 will be described. The robot hand 1 according to the third embodiment is different from the first embodiment in that a load support portion is provided on the structural member of the forearm portion 12 instead of the wrist joint portion 20. Since other components of the robot hand 1 according to the third embodiment are substantially the same as those of the robot hand 1 according to the first embodiment, the description thereof is omitted.

  FIG. 11 is a perspective view showing details of the vicinity of the hand portion 14 of the robot hand 1 according to the third embodiment. FIG. 12 is a front view showing details of the vicinity of the hand portion 14 of the robot hand 1 according to the second embodiment. In the following description, components that are substantially the same as those in the first embodiment are denoted by the same reference numerals.

  In the third embodiment, a load support portion 60 is provided at one end of the two forearm link portions 13. 11 and 12 show an example in which the load support portion 60 is provided on the forearm link portion 13a on the side of the contact portion 14a of the hand portion 14 among the two forearm link portions 13. FIG. However, depending on the optimum posture of the forearm portion 12 and the hand portion 14, the load support portion 60 may be provided on the forearm link portion 13b on the opposite side of the hand portion 14 from the contact portion 14a.

  Similar to the load support portion 30, the load support portion 60 supports the load Fa applied to the forearm portion 12. Note that the material of the load support unit 60 may be the same as the material of the load support unit 30 according to the first embodiment. Further, the thickness of the load support portion 60 is large enough to withstand the load from the forearm portion 12. Thereby, the load support part 60 can support the load Fa from the forearm part 12.

  On the other hand, the width of the load support portion 60 is so thin that it does not interfere with the hand link portion 16. Furthermore, the length D5 from the rotation center P to the tip 64 of the load support portion 60 is shorter than the length D2 from the root portion 16a of the hand link portion 16 to the rotation center P. Thereby, even when the hand portion 14 rotates around the rotation center P of the bending shaft 22, the load support portion 60 is suppressed from interfering with the hand portion 14. Therefore, the rotatable angle of the hand unit 14 is ensured, that is, the hindering of the rotation of the hand unit 14 is suppressed.

  Further, similarly to the first embodiment, the load support portion 60 protrudes to the extent that it contacts or intersects the virtual plane 40. That is, as in the first embodiment, there is a region (first region 60 a) where the load support unit 60 contacts or intersects the virtual plane 40. Preferably, since the load support unit 60 intersects the virtual plane 40, the load support unit 60 comes into contact with the surface when contacting the object 90, and thus the surface pressure when the load support unit 60 contacts the object 90 is contacted. Can be suppressed. Further, how much the load support unit 60 protrudes from the virtual plane 40 is appropriately determined according to the optimal posture of the robot hand 1 when the contact portion 14a (and the load support unit 60) of the hand unit 14 contacts the object 90. Can be.

  A curved portion 62 is provided at the end of the load support portion 60. The bending portion 62 is formed in an arc shape when viewed from the direction along the bending axis 22. Further, the bending portion 62 according to the third embodiment is formed in an arc shape when viewed from the direction along the swing shaft 24. That is, the curved portion 62 is formed in a shape formed by cutting a sphere. In other words, the curved portion 62 can be formed in a “hemispherical shape”.

  Desirably, the arc shape of the bending portion 62 is formed by an arc centered on the rotation center of the wrist joint portion 20. That is, the arc shape of the bending portion 62 when viewed from the direction along the bending axis 22 is formed by an arc centered on the rotation center P. Desirably, the arc shape of the curved portion 62 when viewed from the direction along the swing axis 24 is formed by an arc centered on the rotation center Q. Thus, since the curved portion 62 is formed in the load support portion 60, when the load support portion 60 comes into contact with the object 90 in contact with the surface instead of the corner portion, as in the first embodiment, It is possible to suppress the surface pressure when the load support unit 60 comes into contact with the object 90.

  In the first embodiment, the load support portion 30 is provided at the wrist joint portion 20. Therefore, the posture of the load support portion 30 when the contact portion 14 a of the hand portion 14 and the load support portion 30 come into contact with the object 90 depends only on the rotation angle of the bending shaft 22. Do not depend. In other words, in the case of the first embodiment, when the contact portion 14a is in contact with the object 90, the forearm portion 12 is viewed from the direction along the swing shaft 24 even in a state where the forearm portion 12 is inclined toward the near side or the far side in FIG. At this time, the posture of the load support portion 30 is not inclined with respect to the surface 90 a of the object 90. Therefore, the curved portion 32 of the load support portion 30 according to the first embodiment only needs to be formed in an arc shape with the rotation center P as the center.

  On the other hand, in the third embodiment, the load support portion 60 is provided on the structural member (the forearm link portion 13a) of the forearm portion 12. Therefore, the posture of the load support portion 60 when the contact portion 14 a of the hand portion 14 and the load support portion 60 come into contact with the object 90 depends not only on the rotation angle of the bending shaft 22 but also on the rotation angle of the swing shaft 24. To do. In other words, in the case of the third embodiment, when the forearm portion 12 is tilted to the near side or the far side in FIG. 12 when the contact portion 14a comes into contact with the object 90, it swings with the tilt of the forearm portion 12. The posture of the load support unit 60 when viewed from the direction along the axis 24 is also inclined with respect to the surface 90 a of the object 90.

  Therefore, the curved portion 62 of the load support portion 60 according to the third embodiment is not only formed in an arc shape centered on the rotation center P but also formed in an arc shape centered on the rotation center Q. Yes. Thereby, in the third embodiment, even when the hand unit 14 rotates around the swing shaft 24, the load support unit 60 contacts the surface 90a of the object 90 in a plane. Therefore, even in this case, it is possible to suppress the surface pressure when the load support unit 60 comes into contact with the object 90. As described above, the curved portion 32 of the load support portion 30 according to the first embodiment can be formed in a simpler shape than the curved portion 62 of the load support portion 60 according to the third embodiment.

  Further, the load support portion 60 according to the third embodiment is configured such that the distance D4 between the first region 60a and the virtual position P1 is smaller than the distance D3 between the contact portion 14a and the virtual position P1. Yes. As a result, as in the first embodiment, the moment arm can be made smaller than in the first comparative example, so that the required torque of the motor 22a can be reduced. Thereby, also in Embodiment 3, the increase in the size of the motor 22a and the wrist joint part 20 can be suppressed. That is, in the robot hand 1 according to the third embodiment, it is possible to achieve both the securing of the rotatable angle of the hand unit 14 and the reduction of the required torque of the motor of the wrist joint unit 20.

  Note that the load support portion 60 according to the third embodiment is provided on the forearm link portion 13 which is a structural member of the forearm portion 12. Here, the posture of the forearm link portion 13 changes as the hand portion 14 rotates. Therefore, in order to prevent the interference by the load support part 60, it is necessary that there is no other structural member (for example, the hand link part 16) in the movement range of the load support part 60 accompanying the posture change. In this case, it may be necessary to increase the size of the wrist joint 20, such as increasing the length of the bending shaft 22 and increasing the distance between the two hand links 16. On the other hand, in the robot hand 1 according to the first embodiment, the load support portion 30 is provided at the wrist joint portion 20 whose posture does not change with the rotation operation of the hand portion 14. Therefore, in the first embodiment, compared with the third embodiment, even if the size of the wrist joint portion 20 is not increased, the load support portion 30 is located around the wrist joint portion when the hand portion 14 is rotated. Interference with the structural member is prevented. In other words, the robot hand 1 according to the first embodiment can suppress the enlargement of the wrist joint portion 20.

  Further, the wrist joint portion 20 is closer to the rotation center P than the forearm link portion 13a. Therefore, the example of FIG. 4 (Embodiment 1) is easier to make the distance D4 shorter than the distance D3 by design than the example of FIG. 12 (Embodiment 3). Therefore, the robot hand 1 according to the first embodiment has a greater degree of design freedom than the robot hand 1 according to the third embodiment.

(Modification)
Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention. For example, in the present embodiment, an example in which the drive unit built in the wrist joint unit is a motor has been described, but the drive unit is not limited to a motor. For example, the drive unit may be a hydraulic cylinder.

  In the above-described embodiment, an example in which the robot hand 1 is applied to a manipulator is shown. However, the robot hand 1 can also be applied to an arm of a humanoid robot. In this case, the hand part 14 may have a finger part. In this case, the contact portion 14a may have a curved surface. Further, in this case, the virtual plane 40 is a virtual plane that is in contact with the contact portion 14a that includes the finger portion and is formed of a curved surface.

  In the above-described embodiment, the load support portion has a curved portion. However, the load support portion does not necessarily have a curved portion. For example, depending on the joint angles of the shoulder joint portion 6 and the elbow joint portion 10, it may be possible to control such that the load support portion always contacts the object 90 at the same angle (for example, perpendicular) with respect to the surface 90 a of the object 90. . In this case, if the end portion of the load support portion that contacts the object 90 is formed in a plane, it can always contact the object 90 in the plane, so that the contact area increases, and the contact area in the load support portion due to the load Fa. The surface pressure at is reduced. That is, the surface pressure in the contact area can be reduced without providing a curved portion in the load support portion. On the other hand, since the load support portion has a curved portion, the surface pressure in the contact region can be reduced regardless of the angle at which the load support portion contacts the object 90 with respect to the surface 90a of the object 90.

  Moreover, although the case where the surface 90a of the object 90 is a plane is illustrated in the above-described embodiment, the surface 90a is not necessarily a plane. In this case, it is not necessary for the entire contact portion 14a to contact the surface 90a of the object 90. That is, at this time, the load support portion comes into contact with the object 90 and a part of the contact portion 14a comes into contact with the object 90. Even in this case, the load support portion can support the load Fa from the forearm portion 12. Moreover, even if the surface 90a is not a plane, the height difference of the surface 90a can be absorbed to some extent by forming the load support portion according to the present embodiment from an elastic material. That is, when the height of the surface 90a in contact with the load support portion 30 is higher than the height of the position of the surface 90a in contact with the contact portion 14a, the surface 90a is flat (that is, when the height is the same). As compared with the load support portion 30, the load support portion 30 is more greatly compressed and deformed. Thereby, the area which the contact part 14a contacts the surface 90a can be enlarged. In addition, when the height of the surface 90a which contacts the load support part 30 is lower than the height of the position of the surface 90a which contacts the contact part 14a, the contact part 14a is formed by forming the contact part 14a from an elastic material. The area in contact with the surface 90a can be increased. That is, in the present embodiment, the contact state between the contact portion 14a and the load support portion 30 can be stabilized.

  In addition, when the contact part 14a of the hand part 14 contacts only with the object 90 whose surface 90a is a plane, you may provide a load support part in the hand link part 16. FIG. However, with such a configuration, the degree of freedom of the load support portion with respect to the hand portion 14 becomes zero. Therefore, when the surface 90a is not a flat surface, even if the contact portion 14a contacts the surface 90a, the load support portion may not contact the surface 90a and the load may not be supported. In addition, with such a configuration, the load support unit is prevented from interfering with other structural members (for example, the forearm link unit 13) with the rotation of the hand unit 14, so It is necessary to avoid the structural member. Therefore, it is necessary to increase the size of the wrist joint.

  However, in the first embodiment, the above-described problem does not occur because of the configuration described above. That is, in the first embodiment, since the degree of freedom of the load support portion with respect to the hand portion 14 is not 0, as shown in FIG. 13, even if the surface 90a is not a flat surface, the contact portion 14a contacts the surface 90a. When it does, the load support part 30 can contact the surface 90a. Further, as described above, in the first embodiment, since the load support portion 30 is provided in the wrist joint portion 20, it is possible to suppress an increase in the size of the wrist joint portion 20.

DESCRIPTION OF SYMBOLS 1 ... Robot hand, 12 ... Forearm part, 14 ... Hand part, 14a ... Contact part, 14b ... End part, 16 ... Hand link part, 16a ... Root part, DESCRIPTION OF SYMBOLS 20 ... Wrist joint part, 20a ... End part, 22 ... Bending axis, 22a ... Motor, 24 ... Swing axis, 24a ... Motor, 30 ... Load support part, 30a ... 1st area | region, 30c ... Contact area | region, 30p ... Action point, 32 ... Bending part, 34 ... Tip, 40 ... Virtual plane, 50 ... Wrist joint part , 50a ... end, 60 ... load support, 60a ... first region, 62 ... curved part, 64 ... tip

Claims (4)

An arm,
A hand portion having a contact portion that contacts an external object;
A wrist joint that is provided at a distal end of the arm part and rotatably supports the hand part via a link part provided at a first end of the hand part on the arm part side; A wrist joint unit having a drive unit for driving the hand unit;
A load support portion for supporting a load from the arm portion at the tip of the arm portion;
Have
The rotation center of the hand part in the wrist joint part is at a position away from the contact part in a direction along a virtual plane that is a virtual plane in contact with the contact part,
The length from the rotation center to the tip of the load support part is shorter than the length from the rotation center to the root part of the link part,
There is a first region where the load support portion contacts or intersects the virtual plane, and the first region is a virtual image in which the center of rotation is projected on the virtual plane in the direction of the load from the contact portion. Robot hand close to the position. The robot hand according to claim 1, wherein the load support portion is provided so as to protrude from the wrist joint portion. The robot hand according to claim 1, wherein the load support portion is formed of an elastic material. The robot hand according to claim 3, wherein a curved portion is provided at an end of the load support portion.

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