JP2020006509A - Link operation device - Google Patents

Abstract

To provide a link operation device which can exactly detect external forces from various directions acting on a device tip by a simple and inexpensive constitution, can improve the safety of the device as a whole, and can be used to cooperative work with a person.SOLUTION: A link operation device 1 is constituted of a parallel link mechanism 9 for connecting a base-end side link hub 12 and a tip-side link hub by a plurality of link mechanisms 14. A controller 3 for controlling posture control actuators 10 is arranged. Posture control means 4 for outputting commands to the posture control actuators 10, and load estimation means 5 for estimating a load acting on the tip-side link hub are arranged at the controller 3. The load estimation means 5 has a collision detection function for detecting a collision acting on the tip-side link hub by torque change amounts acting on the posture control actuators 10. Also, there is arranged collision-coping control means for turning off operations of the posture control actuators 10, and making the operations free by the collision detection of the load estimation means 5.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a link actuating device used for cooperative work with a device such as a medical device or an industrial device, which requires a high speed, high accuracy, and a wide operating range, or with a person.

  Patent Literatures 1 and 2 propose parallel link mechanisms used for various working devices. The configuration of the parallel link mechanism of Patent Document 1 is relatively simple, but since the operating angle of each link is small, if the operating range of the traveling plate is set to be large, the link length increases, and the overall size of the mechanism increases. There is a problem. The parallel link mechanism of Patent Literature 2 has a configuration in which the link hub on the distal end side is connected to the link hub on the proximal end side so that the posture can be changed via three or more sets of link mechanisms in a four-node chain. While being compact, it can operate in a precise and wide operating range.

JP-A-2000-94245 U.S. Pat. No. 5,893,296

Conventional link operating devices such as the parallel link mechanism of Patent Document 2 require an expensive sensor to detect a force acting on the tip of the parallel link mechanism.
Link actuation devices used for cooperative work with humans, such as medical equipment, are required for safety to be able to escape immediately and freely when human hands or arms interfere by mistake. For this purpose, it is necessary to detect and cope with the force acting on the tip of the link operating device. Further, in medical equipment and industrial equipment, it is required to be able to detect a force acting on the tip of the link operating device in order to perform the operation with high accuracy.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, to detect external forces acting on the tip of the device from various directions with a simple and inexpensive configuration, to improve the safety of the entire device, and to cooperate with humans. It is to provide a link actuating device that can be used.

The link actuating device of the present invention is configured such that the distal end link hub is connected to the proximal end link hub via three or more sets of link mechanisms so that the attitude can be changed. The proximal and distal end link members, one ends of which are rotatably connected to the side link hub and the distal link hub, and the other ends of the proximal and distal end link members have opposite ends. Each link mechanism is a central link member rotatably connected, and each of the link mechanisms has a geometric model that expresses this link mechanism in a straight line, and includes a base portion and a distal portion with respect to a center portion of the center link member. Is a symmetrical shape, and two or more link mechanisms among the three or more link mechanisms allow the two or more link mechanisms to arbitrarily change the attitude of the distal link hub with respect to the proximal link hub. In link actuator provided with eta,
A controller for controlling each of the attitude control actuators is provided. The controller has a controller for outputting a command to each of the attitude control actuators, and a load estimating means for estimating a load acting on the link hub on the distal end side. Is provided, the load estimating means has a collision detection function of detecting a collision acting on the link hub on the distal end side from a torque change amount acting on each of the attitude control actuators,
A collision handling control means is provided which turns off the operation of each of the attitude control actuators and makes it free when the load estimation means detects a collision.

  According to this configuration, the proximal link hub, the distal link hub, and the three or more link mechanisms rotate the distal link hub about two orthogonal axes with respect to the proximal link hub. A flexible two-degree-of-freedom mechanism is configured. This two-degree-of-freedom mechanism can widen the movable range of the link hub on the distal end side while being compact. By controlling the operation of each posture control actuator, the posture of the distal link hub with respect to the proximal link hub can be arbitrarily changed.

In the link operating device having such a configuration, each of the attitude control actuators may include a torque detecting unit, and the load estimating unit may estimate a load from a detection signal of the torque detecting unit. Each attitude control actuator is provided with a torque detecting means, and a load estimating means for estimating a load acting on the distal link hub from a detection signal of the torque detecting means is provided. The load can be estimated without providing the movable portion. Since the load on the distal link hub is transmitted to each of the attitude control actuators via each of the link mechanisms, the load on the distal link hub can be calculated from the torque of each of the attitude control actuators. The torque detecting means for detecting the torque of the attitude control actuator can be constituted by a simple detecting means such as a sensor for detecting a current applied to the attitude control actuator.
As described above, since the posture control actuator is provided with the torque detecting means and another sensor is not provided on a movable portion such as the distal link hub, the load acting on the distal link hub is estimated. This leads to overall compactness and cost reduction.
In addition, since the link actuating device having the above-described structure has no singularity within its movable range and can move smoothly in all directions, even when loads are applied to the link hub on the distal end from various directions, the posture controlling actuator is used. Torque can be reliably transmitted, and the load can be accurately estimated.

In the present invention, the three or more sets of link mechanisms may be arranged at equal intervals in a circumferential direction in which the link mechanisms are arranged, and the attitude control actuator may be provided for all of the link mechanisms.
By arranging three or more link mechanisms at equal intervals and providing attitude control actuators for all the link mechanisms, torque is transmitted to each attitude control actuator in a well-balanced manner. Therefore, it is possible to more accurately estimate the load using the detection signal of the torque detection means provided in the attitude control actuator.

In the link operating device of the present invention, in the basic configuration, the attitude control actuator is provided for the three or more sets of link mechanisms.
When three sets of link mechanisms are used, interference between the link mechanisms is reduced, and not only the operating range is increased, but also the number of parts is reduced, which leads to cost reduction. Further, when three sets of link mechanisms are provided and the attitude control actuator is provided for these three sets of link mechanisms, torque transmission can be performed in a well-balanced manner. Therefore, when the load acting on the tip of the apparatus is obtained from the torque detecting means of each attitude control actuator, the calculation is easy and the load can be estimated more accurately.

In this invention, the load estimating means may have a function of detecting a collision acting on the link hub on the distal end side from a torque change amount detected by the torque detecting means.
When the link hub on the distal end side or the one mounted on it collides with something, the torque acting on the attitude control actuator changes abruptly. Therefore, collisions in various directions can be detected based on the amount of the torque fluctuation. With the configuration in which the load estimating means is provided with the collision detection function as described above, even when the link operating device comes into contact with a person or an object, it is possible to take measures such as detecting the contact and stopping the device. Is improved.

The link operating device according to the present invention has a function in which the load estimating means detects a load value acting on the link hub on the distal end side and a direction in which the load acts from each torque value of the torque detecting means.
Measure the torque acting on each attitude control actuator for the load acting on the tip in advance, and create a table etc. that defines the relationship between the torque acting on each attitude control actuator and the load acting on the tip If a calculation formula for calculating the load acting on the tip from the torque acting on each attitude control actuator is established by a mechanism analysis, the load on the tip side can be estimated from the torque value detected by the torque detecting means. When the load acting on the distal end is detected with high accuracy, the operation by the end effector or the like attached to the link hub on the distal end side can be performed with high accuracy.

  The link actuating device of the present invention is configured such that the distal end link hub is connected to the proximal end link hub via three or more sets of link mechanisms so that the attitude can be changed. The proximal and distal end link members, one ends of which are rotatably connected to the side link hub and the distal link hub, and the other ends of the proximal and distal end link members have opposite ends. Each link mechanism is formed of a central link member rotatably connected, and each of the link mechanisms has a geometric model that expresses the link mechanism in a straight line, and includes a proximal portion and a distal portion with respect to a central portion of the central link member. Is a symmetrical shape, and two or more link mechanisms among the three or more link mechanisms allow the two or more link mechanisms to arbitrarily change the attitude of the distal link hub with respect to the proximal link hub. In a link actuating device provided with an eta, a controller for controlling each of the attitude control actuators is provided, and in this controller, attitude control means for outputting a command to each of the attitude control actuators, and a link hub on the distal end side. A load estimating means for estimating a load acting on the link hub is provided, and the load estimating means detects a collision acting on the link hub on the distal end side based on a torque change amount acting on each of the attitude control actuators. With the collision response control means that turns off the operation of each of the attitude control actuators by the load estimation means and detects the collision, the external force acting on the tip of the apparatus from various directions can be easily obtained. Detection can be performed with an inexpensive configuration, and safety of the entire apparatus can be improved.

It is the front view which omitted a part of link operation device concerning a 1st embodiment of this invention. It is explanatory drawing which combined the cross-sectional view of the link hub etc. of the base end side of the link actuator with the block diagram of the conceptual structure of a control system. It is the schematic diagram which represented one link mechanism of the link operation device with a straight line. It is a perspective view of the operation device main body of the same link operation device. It is a perspective view which shows the operation state different from FIG. 4 of the same link operating device. It is a graph which shows the relationship between the torque used by the load estimating means of the link operating device, and the occurrence of a collision. It is explanatory drawing of the table which shows the relationship of the torque, the acting force, and the acting direction in the load estimation means of the link actuating device. It is the front view which omitted some link operation devices concerning other embodiments of the present invention. It is explanatory drawing which combined the cross-sectional view of the link hub etc. of the base end side of the link actuator with the block diagram of the conceptual structure of a control system. It is an explanatory view combining a front view in which a part of a link operating device according to still another embodiment of the present invention is omitted and a block diagram of a conceptual configuration of a control system. It is a cross-sectional view of the link hub etc. of the base end side of the link operating device.

  A first embodiment of the present invention will be described with reference to FIGS. The link operating device 1 includes a parallel link mechanism 9, an attitude control actuator 10 that operates the parallel link mechanism 9, and a controller 3 that controls the attitude control actuator to change the attitude of the parallel link mechanism 9 (see FIG. 2).

  FIG. 1 is a front view of the link operating device, and FIGS. 4 and 5 are perspective views showing different states of the link operating device. The parallel link mechanism 9 is configured by connecting a link hub 13 on the distal end side to a link hub 12 on the proximal end side via three sets of individual link mechanisms 14 so as to be able to change the posture. In FIG. 1, only one set of link mechanisms 14 is shown. In this embodiment, the three sets of link mechanisms 14 are arranged at equal intervals in the circumferential direction in which the link mechanisms 14 are arranged, and the attitude control actuator 10 is provided for all of the link mechanisms 14. The internal space in which the three sets of link mechanisms 14 are arranged is the internal space S of the parallel link mechanism 9. The number of the link mechanisms 14 may be four or more.

  Each individual link mechanism 14 is composed of a proximal end link member 15, a distal end link member 16, and a center link member 17, and constitutes a four-bar chain link mechanism composed of four rotating pairs. . The proximal and distal end link members 15 and 16 are L-shaped, and have one end rotatably connected to the proximal link hub 12 and the distal link hub 13, respectively. The center link member 17 has the other ends of the end link members 15 and 16 on the base end side and the distal end side rotatably connected to both ends, respectively.

  The parallel link mechanism 9 has a structure in which two spherical link mechanisms are combined, and includes a rotating pair of the link hubs 12 and 13 and the end link members 15 and 16, and the end link members 15 and 16 and the center link member 17. The center axis of each rotation pair intersects the respective spherical link centers PA and PB (FIG. 3) on the base end side and the distal end side. In addition, the distance from each rotational pair of the link hubs 12 and 13 and the end link members 15 and 16 to the respective spherical link centers PA and PB is also the same on the base end side and the distal end side. The distance from each rotational pair of the center link member 16 and the center link member 17 to the respective spherical link centers PA and PB is also the same. The central axes of the rotation pairs of the end link members 15, 16 and the center link member 17 may have a certain intersection angle γ (FIG. 1) or may be parallel.

  FIG. 2 is a cross-sectional view of the link hub 12 on the base end side, the end link member 15 on the base end side, and the like, in which blocks of the conceptual configuration of the controller 3 are added. The figure shows the relationship between the center axis O1 of each rotating pair of the base link hub 12 and the base end link member 15, and the spherical link center PA. The shape and positional relationship of the link hub 13 on the distal end side and the end link member 16 on the distal end side are the same as those in FIG. 2 (not shown). In the example shown in the figure, the center axis O1 of each rotating pair of the link hubs 12, 13 and the end link members 15, 16 and the center axis O2 of each rotating pair of the end link members 15, 16 and the center link member 17 are shown. Is 90 °, the angle α may be other than 90 °.

  The three sets of link mechanisms 14 are geometrically identical. As shown in FIG. 3, the geometrically identical shape is represented by a geometric model in which each link member 15, 16, 17 is represented by a straight line, that is, each rotational pair and a line connecting these rotational pairs. This means that the model has a shape in which the proximal end portion and the distal end portion with respect to the central portion of the central link member 17 are symmetrical. FIG. 3 is a diagram in which one set of link mechanisms 14 is represented by a straight line. The parallel link mechanism 9 of this embodiment is of a rotationally symmetric type, and includes a base link hub 12 and a base end link member 15, and a front link hub 13 and a front end link member 16. The positional relationship is such that the positional relationship is rotationally symmetric with respect to the center line C of the center link member 17. The central portion of each central link member 17 is located on a common track circle D.

  The proximal link hub 12, the distal link hub 13, and three sets of link mechanisms 14 allow the distal link hub 13 to freely rotate about two orthogonal axes with respect to the proximal link hub 12. A degree mechanism is configured. In other words, this is a mechanism that allows the attitude of the link hub 13 on the distal end side to be freely changed with two degrees of freedom with respect to the link hub 12 on the proximal end side. This two-degree-of-freedom mechanism can make the movable range of the link hub 13 on the distal end relative to the link hub 12 on the proximal end wide while being compact.

  For example, a straight line that passes through the spherical link centers PA and PB and that intersects at right angles with the center axis O1 (FIG. 2) of each rotation pair of the link hubs 12 and 13 and the end link members 15 and 16 is formed as a center axis of the link hubs 12 and 13. In the case of QA and QB, the maximum value of the bending angle θ (FIG. 3) between the central axis QA of the proximal link hub 12 and the central axis QB of the distal link hub 13 may be about ± 90 °. it can. Further, the turning angle φ (FIG. 3) of the distal link hub 13 with respect to the proximal link hub 12 can be set in the range of 0 ° to 360 °. Is the vertical angle at which the central axis QB of the distal link hub 13 is inclined with respect to the central axis QA of the proximal link hub 12, and the turning angle φ is the vertical link hub. 12 is a horizontal angle at which the center axis QB of the link hub 13 on the distal end side is inclined with respect to the center axis QA of the twelve.

  The posture of the distal link hub 13 with respect to the proximal link hub 12 is changed with the center of rotation O at the intersection O between the central axis QA of the proximal link hub 12 and the central axis QB of the distal link hub 13. Will be FIG. 4 shows a state in which the central axis QA of the proximal link hub 12 and the central axis QB of the distal link hub 13 are on the same line, and FIG. 5 shows the central axis QA of the proximal link hub 12. 5 shows a state where the central axis QB of the link hub 13 on the distal end side has a certain operating angle. Even if the posture changes, the distance L (FIG. 3) between the spherical link centers PA and PB on the proximal and distal ends does not change.

  In this parallel link mechanism 9, the angle of the rotation center of the link hubs 12 and 13 and the end link members 15 and 16 of each link mechanism 14 and the center axis O1 (FIG. 2) and the length from the spherical link centers PA and PB are set. The center axes O1 of the rotation pairs of the link hubs 12, 13 and the end link members 15, 16 of each link mechanism 14, which are equal to each other, and the center axis O2 of the rotation pairs of the end link members 15, 16 and the center link 17 Intersect the spherical link centers PA and PB on the proximal side and the distal side, and the geometric shapes of the proximal end link member 15 and the distal end link member 16 are equal, and the central link member When the shape of the center link member 17 is the same as the shape of the base end portion on the distal end side, the angular position relationship between the center link member 17 and the end link members 15 and 16 with respect to the symmetry plane of the center link member 17 is obtained. Are the same on the proximal side and the distal side, the geometrical symmetry makes the proximal link hub 12 and the proximal end link member 15, the distal link hub 13 and the distal end The part link member 16 moves in the same manner.

  As shown in FIG. 1, the link hub 12 on the proximal end side includes the base member 6 and three rotation shaft connecting members 21 provided integrally with the base member 6. The base member 6 has a circular through hole 6a (FIG. 2) in the center, and three rotation shaft connecting members 21 are arranged around the through hole 6a at equal intervals in the circumferential direction. The center of the through hole 6a is located on the link hub center axis QA on the base end side. A rotating shaft 22 whose axis intersects the link hub center axis QA is rotatably connected to each rotating shaft connecting member 21 by a bearing 23. The bearing 23 is installed on the rotating shaft connecting member 21 together with the spacer 24. One end of the end link member 15 on the proximal end side is connected to the rotating shaft 22 by being fixed with a nut 22c.

The rotation shaft 22 is arranged coaxially with the output shaft of the speed reduction mechanism 52. One end of the proximal end link member 15 is connected to the output shaft of the speed reduction mechanism 52 via a spacer 28 with a bolt 29 so as to rotate integrally with the output shaft of the speed reduction mechanism 52. The bolt 29 is fixed from a notch 25 formed at one end of the end link member 15 on the base end side.
A notch 26 is provided at the other end of the end link member 15 on the base end side, and a rotation shaft 35 rotatably connected to one end of the center link member 17 disposed in the notch 26 is connected. Is done.

  As shown in FIGS. 1, 4, and 5, the link hub 13 on the tip side includes a plate-shaped tip member 40 and three rotating shafts provided on the bottom surface of the tip member 40 at equal circumferential intervals. And a connecting member 41. An end effector (not shown) serving as a working machine is attached to the distal end member 40 according to the use of the link operating device 1. The center of the circumference where each rotation shaft connecting member 41 is arranged is located on the link hub center axis QB on the distal end side. Each rotating shaft connecting member 41 is rotatably connected to a rotating shaft 42 (FIG. 4) whose axis intersects the link hub center axis QB. One end of the end link member 16 on the front end is connected to the rotation shaft 42 of the link hub 13 on the front end. A rotating shaft 45 rotatably connected to the other end of the center link member 17 is connected to the other end of the end link member 16 on the distal end side. The rotation shaft 42 of the link hub 13 on the distal end side and the rotation shaft 45 of the center link member 17 have the same shape as the rotation shaft 35, and are connected to the rotation shaft connecting member 41 and the rotation shaft via two bearings (not shown). The center link member 17 is rotatably connected to the other end.

  The attitude control actuator 10 of the link actuating device 1 is a rotary actuator having a speed reduction mechanism 52, specifically, a servomotor with a speed reduction mechanism, and is provided on the upper surface of the base member 6 of the link hub 12 on the base end side. , Are installed coaxially with the rotation shaft 22. The attitude control actuator 10 and the speed reduction mechanism 52 are provided integrally, and the speed reduction mechanism 52 is fixed to the base member 6 by a motor fixing member 53. In this example, the attitude control actuator 10 is provided in all three sets of link mechanisms 14. If the attitude control actuators 10 are provided in at least two of the three link mechanisms 14, the attitude of the distal link hub 13 with respect to the proximal link hub 12 can be determined.

  In FIG. 2, a controller 3 is a device for controlling the parallel link mechanism 9 of the link actuating device 1, and changes the attitude given by a higher-level control means (not shown) or a manual input operation means (not shown). Attitude control means 4 for outputting a rotation angle instruction to each attitude control actuator 10 in accordance with the previous instruction is provided. The posture command of the change destination to the controller 3 is given, for example, by the turning angle φ (FIG. 3) and the bending angle θ, and the posture control means 4 sends the given command of the turning angle φ and the bending angle θ to a predetermined value. Is converted into a command of the rotation angle of each attitude control actuator 10 in accordance with the following equation, and is output to each attitude control actuator 10. The attitude control means 4 performs feedback control by a servo mechanism (not shown) using a detection signal of a rotation angle detector (not shown) provided in each attitude control actuator 10. When the end effector (not shown) is provided in the parallel link mechanism 9, the controller 3 also controls the end effector.

  The controller 3 is provided with a load estimating means 5 for estimating a load acting on the link hub 13 (FIG. 1) on the distal end side. Each of the attitude control actuators 10 has torque detecting means 8, and estimates the applied load of the link hub 13 on the distal end side by the load estimating means 5 from the detection signals of the torque detecting means 8. The torque detecting means 8 includes, for example, a current sensor for detecting a current flowing through each of the attitude control actuators 10.

  The estimation of the acting load of the link hub 13 on the distal end side by the load estimating means 5 does not necessarily need to be estimated as a numerical value, and may be, for example, a stepwise estimation that can determine whether or not a collision has occurred. . FIG. 6 shows an example of collision detection, in which the vertical axis shows the value of the torque detected by each torque detecting means 8, and the horizontal axis shows the passage of time. In the example shown in the figure, the torque value of the attitude control actuator 10 during acceleration is shown, and the torque value of each attitude control actuator 10 gradually increases, but sharply increases at time t1. . The load estimating means 5 calculates the torque change amount (indicated by the gradient of the torque change curve in FIG. 5) which is the change amount per unit time of the torque detected by each of the torque detecting means 8 based on the torque change amount. 13 may detect that it has collided. In this collision detection, it is only necessary to know whether or not the torque change amount has exceeded a threshold value, for example. In this collision detection, the load estimating means 5 may determine that a collision has occurred if any one of the detected values of the torque detecting means 8 exceeds the threshold value. Alternatively, a collision may be determined based on the detection values of the respective torque detecting means 8 according to a predetermined rule.

  When the load estimating means 5 has a collision detection function as described above, the controller 3 or the attitude control means 4 thereof is provided with the collision detection by the load estimating means 5 so that each of the attitude control actuators 10 A collision handling control means (not shown) that makes the operation free by servo-off or the like may be provided. As described above, the safety is improved by allowing the parallel link mechanism 9 to freely move by servo-off or the like.

In this embodiment, in addition to the collision detection function, the load estimating means 5 calculates the load value acting on the link hub 13 on the distal end side and the direction in which the load acts based on the respective torque values of the torque detecting means 8. Detection is possible.
In this example, specifically, the torque acting on each posture control actuator 10 with respect to the load acting on the link hub 13 on the distal end side is measured in advance, and the measurement result is used to apply the posture control actuator 10 to each posture control actuator 10. A table 7 (FIG. 7) defining the relationship between the acting torques T1, T2, T3 and the load acting on the link hub 13 on the distal end side is prepared, and the detected values of the torques T1, T2, T3 are determined by The acting force and the direction are obtained by collating with the table 7. The direction in the table 7 is, for example, the turning angle φ of the link hub 13 on the distal end side shown in FIG.

  The load estimating means 5 has a calculation formula for calculating the load acting on the link hub 13 on the distal end side from the torque acting on each posture control actuator 10 by a mechanism analysis, instead of using the table 7 in FIG. The load acting on the link hub 13 on the distal end side may be estimated from the torque values T1, T2, T3 detected by the torque detecting means 8.

  According to the link operating device 1 having this configuration, as described above, the proximal link hub 12, the distal link hub 13, and the three or more sets of link mechanisms 14 form the proximal link hub 12. On the other hand, a two-degree-of-freedom mechanism in which the link hub 13 on the distal end side is rotatable about two orthogonal axes is configured. This two-degree-of-freedom mechanism allows a wide movable range of the link hub 13 on the distal end side while being compact. By controlling the operation of each posture control actuator 10, the posture of the distal link hub 13 with respect to the proximal link hub 12 can be arbitrarily changed.

  In the link actuating device 1 having such a configuration, the attitude control actuator 10 is provided with the torque detecting means 8 and the load estimating means 5 for estimating the load acting on the link hub 13 on the distal end side from the detection signal of the torque detecting means 8. Is provided, the load can be estimated without providing another sensor on a movable portion such as the link hub 13 on the distal end side. Since the load of the link hub 13 on the distal end side is transmitted to each of the attitude control actuators 10 via each of the link mechanisms 14, the load on the link hub 13 on the distal end side can be calculated from the torque of each of the attitude control actuators 10. The torque detecting means 8 can be constituted by a simple detecting means such as a sensor for detecting a current applied to the attitude control actuator 10.

In this manner, the torque acting on the distal link hub 13 is estimated without providing the torque detecting means 8 on the attitude control actuator 10 and providing another sensor on a movable portion such as the distal link hub 13. This leads to downsizing of the entire apparatus and cost reduction.
In addition, since the link operating device 1 having the above-described configuration has no singularity within its movable range and can move smoothly in all directions, the posture control is performed even when loads are applied to the distal end link hub 13 from various directions. Torque is reliably transmitted to the actuator 10 for use, and the load can be accurately estimated.

  In this embodiment, the three or more sets of the link mechanisms 14 are arranged at equal intervals, and the attitude control actuators 10 are provided in all of the link mechanisms 14, so that the torque is transmitted to each attitude control actuator 10 in a well-balanced manner. Is done. Therefore, the load can be accurately estimated using the detection signal of the torque detection means 8 provided in the attitude control actuator 10. Further, since three sets of the link mechanisms 14 are used, mutual interference of the link mechanisms 14 is reduced, and not only the operating range is increased, but also the number of parts is reduced, leading to cost reduction.

Further, the load estimating means 5 has a function of detecting a collision acting on the link hub 13 on the distal end side from a torque change amount detected by the torque detecting means 8.
When a component mounted on the link hub 13 on the distal end side, for example, an end effector (not shown) collides with something, the torque acting on the attitude control actuator 10 changes abruptly (see the figure). Therefore, collisions in various directions can be detected based on the amount of the torque fluctuation. With the configuration in which the load estimating means 5 is provided with a collision detection function, even when the link operating device 1 comes into contact with a person or an object, measures can be taken such as detecting the contact and stopping the device. , Safety is improved.

  The load estimating means 5 further has a function of detecting, from the respective torque values of the torque detecting means 8, a load value acting on the link hub 13 on the distal end side and a direction in which the load acts. As described above, if the table 7 and the like are prepared or a calculation formula is prepared, the load on the distal end side can be estimated from the torque value detected by the torque detecting means 8. When the load acting on the distal end is accurately detected, the operation by the end effector or the like attached to the link hub 13 on the distal end side can be performed with high accuracy.

  8 and 9 show another embodiment. Except for matters to be particularly described, they are the same as those of the first embodiment shown in FIGS. 1 to 7, and thus redundant description will be omitted. In this embodiment, as shown in FIGS. 8 and 9, the link hub 13 on the distal end side is formed in a polygonal shape, and the link hub 12 on the proximal end side is formed on the base member 6 through a spacer 65 with a polygonal base. The link hub 12 on the end side is provided. An end effector (not shown) is installed on the link hub 13 on the distal end side. Further, an attitude control actuator 10 is connected as shown in FIG.

  All three sets of link mechanisms 14 of the parallel link mechanism 9 rotate the proximal end link member 15 to arbitrarily change the attitude of the distal link hub 13 with respect to the proximal link hub 12. An attitude control actuator 10 and a speed reduction mechanism 71 that reduces and transmits the operation amount of the attitude control actuator 10 to the end link member 15 on the base end side are provided. The attitude control actuator 10 is a rotary actuator, more specifically, a servomotor with a speed reducer 52, and is fixed to the base member 6 by a motor fixing member 53. The speed reduction mechanism 71 includes the speed reducer 52 of the attitude control actuator 10 and a gear type speed reduction unit 73. In the following, a spur gear is used for the reduction mechanism 71, but another mechanism (for example, a bevel gear or a worm mechanism) may be used.

  The gear type reduction unit 73 includes a small gear 76 connected to an output shaft of the attitude control actuator 10 via a coupling 75 so as to be capable of transmitting rotation, and a small gear 76 fixed to the proximal end link member 15. 76 and a large gear 77 that meshes. In the illustrated example, the small gear 76 and the large gear 77 are spur gears, and the large gear 77 is a sector gear having teeth formed only on the peripheral surface of the sector. The large gear 77 has a larger pitch circle radius than the small gear 76, and the rotation of the output shaft of the attitude control actuator 10 is transmitted to the proximal end link member 15 at reduced speed.

  Also in the case where the parallel link mechanism 9 and the attitude control actuator 10 are configured as in this embodiment, the load estimating means 5 of the controller 3 can be used in various directions acting on the front end of the apparatus, as in the first embodiment. Can be detected with a simple and inexpensive configuration, and the safety of the entire apparatus can be improved.

  10 and 11 show still another embodiment. Except for matters to be particularly described, they are the same as those of the first embodiment shown in FIGS. 1 to 7, and thus redundant description will be omitted. In this embodiment, the link hub 12 on the proximal end side and the link hub 13 on the distal end side have a donut shape having a spherical outer shape with a through hole formed at the center thereof. The proximal end link member 15 and the distal end link member 16 are respectively rotated at equal circumferential positions on the outer peripheral surfaces of the proximal link hub 12 and the distal link hub 13. They are freely connected.

  FIG. 11 is a cross-sectional view showing a rotating pair of the proximal link hub 12 and the proximal end link member 15, and a rotating pair of the proximal end link member 15 and the central link member 17. is there. The proximal end link hub 12 has radial shaft holes 81 formed in the outer peripheral portion at three locations in the circumferential direction, and the shaft members 83 are rotatably supported by two bearings 82 provided in each shaft hole 81. Have been. The center of the shaft member 83 coincides with the center axis of the rotation pair of the link hub 12 on the base end side and the end link member 15 on the base end side. The outer end of the shaft member 83 protrudes from the proximal link hub 12, and the proximal end link member 15 is coupled to the projecting screw portion 83 a, and is fastened and fixed by a nut 94.

  The bearing 82 is, for example, a rolling bearing such as a deep groove ball bearing. The outer ring (not shown) of the bearing 82 is fitted into the inner periphery of the shaft hole 81, and the inner ring (not shown) of the bearing 82 is formed on the outer periphery of the shaft member 83. Is fitted. The outer ring is retained by a retaining ring 85. A spacer 86 is interposed between the inner ring and the end link member 15 on the proximal side, and the tightening force of the nut 84 is transmitted to the inner ring via the end link member 15 on the proximal side and the spacer 86. Thus, a predetermined preload is applied to the bearing 82.

  Two bearings 89 are provided in communication holes 88 formed at both ends of the center link member 17 at the rotating pair of the end link member 15 and the center link member 17 on the base end side. The shaft portion 90 at the tip of the end link member 15 is rotatably supported. The bearing 89 is fastened and fixed by a nut 92 via a spacer 91.

  The bearing 89 is, for example, a rolling bearing such as a deep groove ball bearing. The outer ring (not shown) of the bearing 89 fits into the inner periphery of the communication hole 88, and the inner ring (not shown) of the bearing 89 is the outer periphery of the shaft portion 90. Is fitted. The outer ring is retained by a retaining ring 93. The tightening force of the nut 92 screwed to the tip screw portion 90 a of the shaft portion 90 is transmitted to the inner race via the spacer 91, and a predetermined preload is applied to the bearing 89. In FIG. 11, a bevel gear 57 described later is omitted.

  As described above, the rotation pair of the base link hub 12 and the base end link member 15 and the rotation pair of the base end link member 15 and the center link member 17 have been described. The rotational pair of the link hub 13 and the distal end link member 16 and the rotational pair of the distal end link member 16 and the central link member 17 have the same configuration (not shown).

  As described above, the four rotating pair portions of each link mechanism 14, that is, the rotating pair portion of the proximal link hub 12 and the proximal end link member 15, the distal link hub 13 and the distal end A bearing 82 is provided on the rotating pair of the partial link member 16, the rotating pair of the end link member 15 and the center link member 17 on the proximal side, and the rotating pair of the end link member 16 and the center link member 17 on the distal side. , 89, the frictional resistance at each rotating pair can be suppressed to reduce the rotational resistance, and smooth power transmission can be ensured and the durability can be improved.

In FIG. 10, the base end side link hub 12 is fixed to the upper surface of the base member 6 via a spacer 65. The attitude control actuator 10 is attached to the lower surface of the base member 6 in a hanging state. The number of the posture control actuators 10 is the same as the number of the link mechanisms 14, three. The attitude control actuator 10 is a rotary actuator, and a bevel gear 56 attached to an output shaft thereof and a fan-shaped bevel gear 57 attached to a shaft member 83 (FIG. 5) of the link hub 12 on the base end side mesh with each other.
In this example, the same number of attitude control actuators 10 as the link mechanisms 14 are provided. However, if at least two of the three sets of link mechanisms 14 are provided with the attitude control actuators 10, The attitude of the link hub 13 on the distal end side with respect to the link hub 12 on the side can be determined.

  In the parallel link mechanism 9, by rotating each of the attitude control actuators 10, the rotation is transmitted to the shaft member 83 via the pair of bevel gears 56 and 57, and the base member is connected to the base side link hub 12. The angle of the end link member 15 on the end side changes. Thereby, the position and posture of the distal link hub 13 with respect to the proximal link hub 12 are determined. Here, the angle of the end link member 15 on the proximal side is changed using the bevel gears 56 and 57, but another mechanism (for example, a spur gear or a worm mechanism) may be used.

  Also in the case where the parallel link mechanism 9 and the attitude control actuator 10 are configured as in this embodiment, the load estimating means 5 of the controller 3 can be used in various directions acting on the front end of the apparatus, as in the first embodiment. Can be detected with a simple and inexpensive configuration, and the safety of the entire apparatus can be improved.

  Although the embodiments for carrying out the present invention have been described based on the embodiments, the embodiments disclosed herein are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 ... Link actuating device 3 ... Controller 4 ... Attitude control means 5 ... Load estimation means 6 ... Base member 8 ... Torque detection means 9 ... Parallel link mechanism 10 ... Attitude control actuator 12 ... Base end side link hub 13 ... End side Link hub 14 ... Link mechanism 15 ... End end link member 16 ... End end link member 17 ... Center link member O1 ... Rotation of link hub and end link member Pairwise center axis O2 ... End The central axes PA, PB of the rotation pair of the link member and the central link member, the spherical link centers QA, QB, the central axis S of the link hub, the internal space.

Claims (2)

The distal-side link hub is connected to the proximal-side link hub via three or more sets of link mechanisms so that the posture can be changed, and each of the link mechanisms is connected to the proximal-side link hub and the distal-side link hub, respectively. A proximal end and a distal end link member having one end rotatably connected to the link hub, and a center having both ends rotatably connected to the other end of the proximal and distal end link members, respectively. A link member, wherein each of the link mechanisms has a geometric model in which the link mechanism is represented by a straight line, and has a shape in which a proximal end portion and a distal end portion with respect to the center of the central link member are symmetrical, A two-degree-of-freedom mechanism provided with an attitude control actuator for arbitrarily changing the attitude of the distal link hub with respect to the proximal link hub in at least two of the three or more link mechanisms. In the link actuating device,
A controller for controlling each of the attitude control actuators is provided. The controller has a controller for outputting a command to each of the attitude control actuators, and a load estimating means for estimating a load acting on the link hub on the distal end side. Is provided, the load estimating means has a collision detection function of detecting a collision acting on the link hub on the distal end side from a torque change amount acting on each of the attitude control actuators,
A link actuating device comprising: a collision handling control unit that turns off the operation of each of the attitude control actuators and makes it free by the collision detection of the load estimating unit. 2. The link operating device according to claim 1, wherein each of said attitude control actuators has torque detecting means, and estimates a load by said load estimating means from a detection signal of said torque detecting means.

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