JOINT MECHANISM, MANIPULATOR, AND MANIPULATOR SYSTEM
Provided is a joint mechanism including a tubular first member having a through-hole; a second member disposed at the distal end of the first member and swivelable about a swivel axis intersecting a central axis thereof; a flexible, tubular guide sheath extending near the central axis of the through-hole and a distal end of which is fixed to the second member; a manipulation wire introduced toward the distal end of the guide sheath; and a turnaround section that is provided in the second member at a position decentered from the swivel axis in the radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member. A distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to a position decentered in the radial direction.
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This is a continuation of International Application PCT/JP2015/050541, with an international filing date of Jan. 9, 2015, which is hereby incorporated by reference herein in its entirety. This application claims the benefit of Japanese Patent Application No. 2014-004376, the content of which is incorporated herein by reference.
TECHNICAL FIELDThe present invention relates to joint mechanisms, manipulators, and manipulator systems.
BACKGROUND ARTIn the related art, a known medical device has a multi-joint bending mechanism in which a plurality of bending segments connected in a swivelable manner are independently and individually manipulated by means of manipulation wires (for example, see Patent Literature 1).
In this multi-joint bending mechanism, a position close to the outer periphery of each bending segment is pulled toward the basal end by using each manipulation wire so as to generate moment. Therefore, in order to efficiently transmit a traction force to the bending segments, the manipulation wires and tubular guide sheaths that guide the manipulation wires are routed so as to extend along paths located relatively close to the outer peripheries of the bending segments.
Furthermore, in the multi-joint bending mechanism in Patent Literature 1, the manipulation wire connected to the bending segments located closer toward the basal end is disposed at the inner side, in the radial direction of the bending segments, relative to the manipulation wire connected to the bending segments located closer toward the distal end. By applying a traction force to the manipulation wires, each bending segment swivels relative to the other bending segments, thus causing the manipulation wires and the guide sheaths to bend.
CITATION LIST Patent Literature{PTL 1}
The Publication of Japanese Patent No. 5197980
SUMMARY OF INVENTION Technical ProblemThe present invention provides a joint mechanism, a manipulator, and a manipulator system that can achieve bendability with a small traction force, reduced device size, and improved controllability.
Solution to ProblemA first aspect of the present invention provides a joint mechanism including a tubular first member having a through-hole extending along a central axis; a second member disposed at a distal end of the first member and swivelable relative to the first member about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the first member and a distal end of which is fixed to the second member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the second member at a position decentered from the swivel axis in a radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member. A distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the first member at a position decentered from the swivel axis in the radial direction.
A second aspect of the present invention provides a manipulator including two or more series-connected joint mechanisms described above.
A third aspect of the present invention provides a manipulator including a tubular manipulator body, a basal-end joint unit provided at a distal end of the manipulator body, and a distal-end joint unit connected in series to a distal end of the basal-end joint unit and equipped with at least one joint mechanism described above. The basal-end joint unit includes a swivel member connected to the manipulator body in a swivelable manner about a swivel axis, a tubular guide sheath whose opening at a distal end thereof is fixed to the manipulator body, and a manipulation wire that is introduced via the guide sheath and protrudes from the opening at the distal end of the guide sheath and a distal end of which is fixed to a position decentered from the swivel axis of the swivel member in a radial direction.
A fourth aspect of the present invention provides a manipulator including a tubular manipulator body having a through-hole extending along a central axis; a swivel member disposed at a distal end of the manipulator body and swivelable relative to the manipulator body about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the manipulator body and a distal end of which is fixed to the swivel member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the swivel member and that causes the manipulation wire introduced from the manipulator body via the guide sheath to make a U-turn toward the manipulator body. A distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the manipulator body at a position decentered from the swivel axis in the radial direction.
A fifth aspect of the present invention provides a manipulator system including the above-described manipulator, a slave device equipped with a driver that drives the manipulator, a master device equipped with an operation section to be operated by an operator, and a controller that controls the driver of the slave device based on an input signal input via the operation section of the master device.
A joint mechanism, a manipulator, and a manipulator system according to an embodiment of the present invention will be described below with reference to the drawings.
As shown in
As shown in
The endoscope 5 according to this embodiment is a flexible endoscope having a flexible, elongated insertion part 7, which is bendable, and includes an elongated flexible section (manipulator body) 8, a distal end section 9 disposed at the distal end, and a bendable section 10 disposed between the distal end section 9 and the flexible section 8. Although a flexible endoscope is described in this embodiment, a rigid endoscope having an elongated rigid section may be used as an alternative.
As shown in
The basal-end joint group 12 includes a plurality of, for example, four, flexure joints (joint mechanism) 12a to 12d. Each of these flexure joints 12a to 12d is provided between a corresponding pair of link members 13a to 13e and is configured to change the relative angle between the pair of neighboring link members 13a to 13e.
The flexure joints 12a to 12d can be independently flexed about axes 14a to 14d (extending in the Y-axis direction) arranged parallel to one another and spaced apart in the longitudinal direction of the insertion part 7, that is, the longitudinal-axis direction of the link members 13a to 13e. For example, each of the flexure joints 12a to 12d can be flexed in a flexion-angle range of ±60° so that the entire basal-end joint group 12 can be flexed by ±240°. The axes 14a to 14d do not necessarily need to be arranged parallel to one another so long as they are arranged side-by-side to allow for flexion.
The flexure joints 12a to 12d according to this embodiment will be described below with reference to
First, the flexure joint 12a located closest to the basal end will be described in detail.
As shown in
The link members 13a to 13e and the segments 15a to 15d are connected in a relatively swivelable manner about substantially parallel axes (intermediate axes) 16a to 16e. The axes 16a to 16e also do not necessarily need to be disposed parallel to one another so long as they are arranged side-by-side to allow for flexion.
As shown in
The flexure joint 12a according to this embodiment includes two pulleys 20a and 20b rotatably attached to the link member 13b; flexible, tubular guide sheaths 21a and 21b that extend through the through-hole 17 in the flexible section 8 and the through-holes 18 in the segments 15a to 15d, that are disposed along the vicinity of the central axes of the through holes, and whose openings at the distal ends are fixed to the component 13b1 of the link member 13b; and manipulation wires 22a and 22b inserted through the guide sheaths 21a and 21b from the basal end of the flexible section 8.
As shown in
Each of the segments 15a to 15d is provided with a pair of through-holes 24a and 24b through which the pair of manipulation wires 22a and 22b, which have been caused to make a U-turn toward the outer periphery by the pair of pulleys 20a and 20b, extend. After the pair of manipulation wires 22a and 22b are turned back in the reverse direction by the pair of pulleys 20a and 20b and extend through the through-holes 24a and 24b in the segments 15a to 15d, the ends thereof are respectively fixed to fixation sections 26a and 26b of the link member 13a.
The other flexure joints 12b to 12d have structures identical to that of the flexure joint 12a described above. Specifically, each of the flexure joints 12b to 12d includes four segments 15a to 15d between a first member, which is defined by one of the link members 13b to 13d at the distal end of the remaining one of the flexure joints 12b to 12d adjacent thereto at the basal end, and a second member, which is defined by one of the link members 13c to 13e adjacent thereto at the distal end. The guide sheaths 21a and 21b, the pulleys 20a and 20b, and the manipulation wires 22a and 22b in the flexure joints 12a to 12d are disposed as shown in a simplified view in
As shown in
As shown in
The manipulation wires 22a and 22b used for moving all of the flexure joints 11a to 11c and 12a to 12d are introduced to the bendable section 10 from the basal end of the flexible section 8 via the through-hole 17 in the flexible section 8.
As shown in
The drivers 6a and 6b are equipped with sliders (not shown) that are attached to the basal ends of the manipulation wires 22a and 22b, which extend toward the basal end through the interior of the flexible section 8, so as to pull the basal ends of the manipulation wires 22a and 22b and adjust the traction force F to be applied individually to the manipulation wires 22a and 22b. The drivers 6a and 6b are attachable to and detachable from drive sources 28 equipped with electrically-driven actuators or manually-operated masters (not shown) of the manually driven type.
The actuators of the drive sources 28 are, for example, linear actuators, such as linear motors. When the drivers 6a and 6b are attached to the actuators, the actuators engage with the sliders of the drivers 6a and 6b. When the actuators are actuated, the sliders slide so as to apply a traction force F to the manipulation wires 22a and 22b.
When manually-operated masters are attached to the drivers 6a and 6b, operation sections engage with the sliders of the drivers 6a and 6b. The sliders slide in accordance with a force applied by the surgeon A so as to apply a traction force F to the manipulation wires 22a and 22b.
The relay unit 27 is provided with an insertion port 29 for inserting a surgical device into a forceps channel (not shown) having an opening in an end surface thereof and extending in the longitudinal direction of the insertion part 7.
As shown in
The controller 4 controls the drivers 6a and 6b so as to make the flexion angles of the joints of the master device 2, indicated by the flexion-angle signals output from the master device 2, equal to the flexion angles of the flexure joints 11a to 11c and 12a to 12d in the bendable section 10 of the endoscope 5.
The operation of the flexure joints 12a to 12d, the endoscope 5, and the endoscope system 1 according to this embodiment having the above-described configuration will be described below.
In order to observe and treat the inside of the body of the patient P by using the endoscope 5 according to this embodiment, a process for inserting the endoscope 5 into the body cavity is performed by attaching a manually-operated master only to the distal-end driver 6a that drives the distal-end joint group 11.
While holding and operating the manually-operated master with his/her left hand, the surgeon A holds the insertion part 7 with his/her right hand and inserts the endoscope 5 into the body cavity based on a method similar to that used for an endoscope in the related art. In this case, an image of the state in the body cavity is captured by actuating the endoscope 5 and is displayed on the monitor 25. The surgeon A operates the manually-operated master while viewing the monitor 25 so as to drive the distal-end joint group 11, and inserts the insertion part 7 into the body cavity until the distal end section 9 of the endoscope 5 is brought close to an affected area.
In this state, a drive source 28 or a manually-operated master is not attached to the basal-end driver 6b that drives the basal-end joint group 12. Thus, the basal-end joint group 12 moves by passively following the movement of the distal-end joint group 11. This prevents the insertion process from being hindered by the basal-end joint group 12.
When the distal end section 9 of the insertion part 7 is disposed close to an affected area, a drive source 28 is attached to the basal-end driver 6b so as to switch from the manually-operated master to the drive source 28. The surgeon A then operates the master device 2.
The endoscope 5 according to this embodiment has four flexure joints 12a to 12d, which serve as the basal-end joint group 12 and can altogether be flexed by ±240°. Therefore, the bendable section 10 can be bent into a U-shape so that the distal-end surface of the endoscope 5 can be oriented toward the rear. Moreover, since there is still room for movement of the flexure joints 12a to 12d even in the state where the bendable section 10 is bent in a U-shape, the distal end section 9 of the insertion part 7 can advance or recede. As a result, this is advantageous in that the distal-end surface of the insertion part 7 can be oriented toward an easily observable or treatable position not only for an affected area located toward the front in the direction in which the endoscope 5 is inserted into the body cavity but also for an affected area located in the opposite direction, such as an affected area behind a fold.
In order to cause the flexure joint 12d according to this embodiment to flex as shown in
Accordingly, the traction force F transmitted to the distal end of the manipulation wire 22a causes tension to occur in the manipulation wire 22a between the pulley 20a on the link member 13e and the fixation section 26a on the link member 13d. This causes the link members 13d and 13e and the segments 15a to 15d therebetween to relatively swivel, so that the pulley 20a on the link member 13e and the fixation section 26a on the link member 13d are brought closer to each other, whereby the flexure joint 12d is flexed. The flexure joints 12a to 12c can be flexed in a similar manner.
In this case, in the flexure joints 12a to 12d, the guide sheaths 21a and 21b that guide the manipulation wires 22a and 22b from the basal end of the flexible section 8 to the link members 13b to 13e located toward the distal end are disposed along the vicinity of the central axes of the flexure joints 12a to 12d. Therefore, the radii of curvature of the guide sheaths 21a and 21b when the flexure joints 12a to 12d are flexed can be maintained at larger values than in a normal case where the sheaths are disposed at the inner side by being set near the outer peripheries of the joints.
Furthermore, the guide sheaths 21a and 21b are disposed along the vicinity of the central axes of the flexure joints 12a to 12d even in a case where the bending direction is inverted. Thus, the variation in the radii of curvature of the sheaths is reduced, and variations in the resistance force against bending, which is generated due to the rigidity of the sheaths, can be minimized.
The guide sheaths 21a and 21b each have a larger diameter and higher bending rigidity than the manipulation wire 22a disposed at the inner side. This is advantageous in that, by maintaining the radii of curvature during flexion at large values, the traction force F required for flexion can be reduced, and variations in the required traction force F can be minimized.
Furthermore, since the manipulation wires 22a and 22b are turned back by the pulleys 20a and 20b to make a U-turn, the manipulation wires 22a and 22b move smoothly with low friction when a traction force F is applied thereto for flexing the flexure joints 12a to 12d. Thus, the traction force F for causing the flexure joints 12a to 12d to flex can be further reduced.
Moreover, since the distal ends of the manipulation wires 22a and 22b turned back by the pulleys 20a and 20b are fixed to the fixation sections 26a and 26b located far, in the radial direction, from the axes 16e of the link members 13a to 13d serving as the first members, large moment can be generated by the traction force F applied to the manipulation wires 22a and 22b, which is advantageous in that the flexure joints 12a to 12d can be flexed efficiently.
Furthermore, in this embodiment, the link members 13b to 13e have identical pulleys 20a and 20b disposed at identical positions and in identical orientations in the circumferential direction and the radial direction, thereby achieving commonality of the link members 13b to 13e and reducing the number of types of components.
Furthermore, the endoscope 5 according to this embodiment having the above-described flexure joints 12a to 12d can minimize changes in the traction force F in accordance with the degree of flexion of the flexure joints 12a to 12d. This is advantageous in that the controllability using the drivers 6a and 6b can be improved.
Moreover, with the endoscope system 1 according to this embodiment, the controllability of the endoscope 5 is improved so that the responsiveness of the slave device 3 to the operation of the master device 2 is improved, which is advantageous in that improved manipulability can be achieved.
In the flexure joints 12a to 12d according to this embodiment, the pair of guide sheaths 21a and 21b that guide the pair of manipulation wires 22a and 22b for bending the flexure joints 12a to 12d toward both sides are disposed adjacent to each other with the axes 16a to 16e interposed therebetween. Alternatively, if space permits, the pair of guide sheaths 21a and 21b are preferably arranged in a single line on the axes 16a to 16e. Thus, when the flexure joints 12a to 12d are to be flexed toward both sides, all radii of curvature of the guide sheaths 21a and 21b can be made the same so that the path lengths of the sheaths become fixed, thereby eliminating the need to warp the sheaths and minimizing the traction force required for flexion.
Furthermore, although the pulleys 20a and 20b are used as turnaround sections that cause the manipulation wires 22a and 22b to make a U-turn in this embodiment, U-shaped tubular members 30a and 30b that are composed of a high-rigidity material and that allow the manipulation wires 22a and 22b to extend therethrough to make a U-turn may be used as an alternative, as shown in
Furthermore, in this embodiment, the positions of the pulleys 20a and 20b are identical among all of the link members 13b to 13e serving as the second members. Alternatively, as shown in
Furthermore, in this embodiment, the pair of pulleys 20a and 20b are disposed at symmetric positions at the opposite sides of the axis 16a. Alternatively, as shown in
Furthermore, in this embodiment, the pulleys 20a and 20b in all of the flexure joints 12a to 12d cause the manipulation wires 22a and 22b to make a U-turn. Alternatively, as shown in
Furthermore, in this embodiment, the basal-end joint group 12 is constituted of four flexure joints 12a to 12d having substantially parallel axes 14a to 14d. Alternatively, as shown in
Furthermore, in this embodiment, the endoscope 5 having the basal-end joint group 12 with the four series-connected flexure joints 12a to 12d is described as an example. Alternatively, as shown in
Furthermore, the segments 15a to 15d are described as having the through-holes 24a and 24b through which the manipulation wires 22a and 22b extend. Alternatively, as shown in
As shown in
In this case, since the tension generated in the manipulation wires 22a and 22b increases in accordance with the magnitude of the traction force F, the manipulation wires 22a and 22b become pressed against the inner surfaces of the through-holes 24a and 24b, thus resulting in increased friction. In contrast, as shown in
Although the endoscope 5 and the endoscope system 1 are described as examples of a manipulator and a manipulator system in this embodiment, the embodiment may alternatively be applied to other types of manipulators and manipulator systems, such as a surgical device.
Furthermore, although flexure joints provided in the endoscope 5 in the slave device 3 are described as an example, the embodiment may alternatively be applied to flexure joints provided in a manual endoscope.
Furthermore, examples of the manipulation wires 22a and 22b include solid wires, stranded wires, braided wires, and plates.
Consequently, the above-described embodiment derives the following solutions.
A first aspect of the present invention provides a joint mechanism including a tubular first member having a through-hole extending along a central axis; a second member disposed at a distal end of the first member and swivelable relative to the first member about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the first member and a distal end of which is fixed to the second member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the second member at a position decentered from the swivel axis in a radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member. A distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the first member at a position decentered from the swivel axis in the radial direction.
According to this aspect, when a traction force acting toward the basal end is applied to the basal end of the manipulation wire, the traction force propagates through the manipulation wire to the distal end thereof so as to act in a direction in which the turnaround section that causes the manipulation wire to make a U-turn and the first member to which the distal end of the manipulation wire is fixed are brought closer to each other. Since the positions where the turnaround section and the manipulation wire are fixed to the first member are decentered from the swivel axis in the radial direction, moment according to the decentered amount and the magnitude of the traction force is generated, so that the second member can be made to swivel relative to the first member in one direction about the swivel axis.
In this case, when the second member swivels relative to the first member, the guide sheath whose distal end is fixed to the second member also bends in the swiveling direction of the second member. However, since the guide sheath extends near the central axis of the joint mechanism and the manipulation wire alone is disposed near the outer periphery of the joint mechanism, the guide sheath, which has relatively high rigidity, can be prevented from being bent with an extremely small radius of curvature, thereby allowing for bending with a small traction force. As a result, reduced device size and improved controllability can be achieved.
In the above aspect, the turnaround section may be a pulley around which the manipulation wire is wound to cause the manipulation wire to make a U-turn.
Accordingly, when causing the second member to swivel relative to the first member by applying a traction force to the manipulation wire, the pulley is rotated so that the manipulation wire can be moved with a small frictional force, thereby allowing for bending with an even smaller traction force.
Furthermore, in the above aspect, the turnaround section may be a substantially U-shaped tubular member that allows the manipulation wire to extend therethrough so as to cause the manipulation wire to make a U-turn.
Accordingly, when causing the second member to swivel relative to the first member by applying a traction force to the manipulation wire, the manipulation wire can be moved within the tubular member while a fixed radius of curvature is maintained by the tubular member, thereby allowing for bending with a stable traction force.
Furthermore, in the above aspect, the guide sheath, the manipulation wire, and the turnaround section may include a pair of guide sheaths, a pair of manipulation wires, and a pair of turnaround sections, respectively, so as to cause the second member to swivel relative to the first member in two directions about the swivel axis.
Accordingly, the second member can be made to swivel relative to the first member in one direction by applying a traction force to one of the manipulation wires, and the second member can be made to swivel relative to the first member in the other direction by applying a traction force to the other manipulation wire. In the case where the second member is made to swivel relative to the first member in two directions about the swivel axis in this manner, the advantage of making the guide sheath extend near the central axis is high particularly in that the guide sheath can be prevented from being bent with an extremely small radius of curvature for both of the two directions.
Furthermore, in the above aspect, the pair of turnaround sections may be provided to cause the pair of manipulation wires to make a U-turn at positions partially overlapping each other in the radial direction.
Accordingly, the diameter of the turnaround sections can be made larger than the radius of the second member so that when the manipulation wires are caused to make a U-turn, a frictional force occurring between the manipulation wires and the turnaround sections can be reduced.
Furthermore, in the above aspect, the joint mechanism may further include one or more intermediate members provided between the first member and the second member and connected in a swivelable manner about two or more intermediate axes that are parallel to each other.
Accordingly, by causing the intermediate members to swivel about the intermediate axes, the positions of the intermediate axes are moved in the swiveling direction, so that a large overall swivel-angle range of the second member relative to the first member can be ensured.
Furthermore, in the above aspect, each intermediate member may be provided with a sheath pass-through hole that allows the guide sheath to extend therethrough and a wire pass-through section that allows the manipulation wire to extend therethrough. Moreover, the wire pass-through section may be a long hole or a cutout extending in a direction orthogonal to the intermediate axes.
Accordingly, the manipulation wire is moved through the wire pass-through section defined by a long hole or a cutout in the direction orthogonal to the intermediate axes in accordance with the swivel angle of the second member relative to the first member, so that a force applied to the manipulation wire in the lateral direction can be released as much as possible, whereby friction occurring when the manipulation wire moves can be reduced. Consequently, the second member can be made to swivel relative to the first member by simply applying a small traction force to the manipulation wire.
A second aspect of the present invention provides a manipulator including two or more series-connected joint mechanisms described above.
According to this aspect, an even larger overall bending-angle range can be ensured.
In the above aspect, the turnaround sections provided in the respective joint mechanisms may be disposed at substantially identical positions in the radial direction and a circumferential direction of the second members.
Accordingly, the plurality of first members, the plurality of second members, and the plurality of turnaround sections can respectively have identical shapes, thereby achieving commonality of components. Moreover, the turnaround sections and the distal ends of the manipulation wires, to which a traction force is to be applied, are fixed at identical positions so that uniform controllability can be achieved for all of the joint mechanisms.
Furthermore, in the above aspect, the turnaround sections provided in the respective joint mechanisms may be disposed at substantially identical positions in the radial direction of the second members but at different positions in a circumferential direction.
Accordingly, the routing of the manipulation wires from the openings at the distal ends of the guide sheaths toward the turnaround sections can be performed without difficulty while maintaining substantially identical fixation positions for the turnaround sections and the distal ends of the manipulation wires, to which a traction force is to be applied.
A third aspect of the present invention provides a manipulator including a tubular manipulator body, a basal-end joint unit provided at a distal end of the manipulator body, and a distal-end joint unit connected in series to a distal end of the basal-end joint unit and equipped with at least one joint mechanism described above. The basal-end joint unit includes a swivel member connected to the manipulator body in a swivelable manner about a swivel axis, a tubular guide sheath whose opening at a distal end thereof is fixed to the manipulator body, and a manipulation wire that is introduced via the guide sheath and protrudes from the opening at the distal end of the guide sheath and a distal end of which is fixed to a position decentered from the swivel axis of the swivel member in a radial direction.
According to this aspect, in the basal-end joint unit located closest to the manipulator body, the swivel member can be made to swivel relative to the manipulator body by pulling the swivel member from the manipulator body side toward the basal end. Consequently, the number of guide sheaths extending through the basal-end joint unit can be reduced so that the rigidity can be reduced, whereby the basal-end joint unit can be bent with a small traction force.
A fourth aspect of the present invention provides a manipulator including a tubular manipulator body having a through-hole extending along a central axis; a swivel member disposed at a distal end of the manipulator body and swivelable relative to the manipulator body about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the manipulator body and a distal end of which is fixed to the swivel member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the swivel member and that causes the manipulation wire introduced from the manipulator body via the guide sheath to make a U-turn toward the manipulator body. A distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the manipulator body at a position decentered from the swivel axis in the radial direction.
According to this aspect, even in a manipulator having a single joint mechanism disposed at the distal end of the manipulator body, a traction force can be applied to a position sufficiently decentered from the swivel axis in the radial direction by causing the manipulation wire to make a U-turn and fixing the distal end thereof to the manipulator body, whereby the swivel member can be made to swivel with a small traction force.
A fifth aspect of the present invention provides a manipulator system including the above-described manipulator, a slave device equipped with a driver that drives the manipulator, a master device equipped with an operation section to be operated by an operator, and a controller that controls the driver of the slave device based on an input signal input via the operation section of the master device.
Advantageous Effects of InventionThe present invention is advantageous in that it achieves bendability with a small traction force, reduced device size, and improved controllability.
REFERENCE SIGNS LIST
- A surgeon (operator)
- 1 endoscope system (manipulator system)
- 2 master device
- 3 slave device
- 4 controller
- 5 endoscope (manipulator)
- 8 flexible section (manipulator body)
- 12a to 12d flexure joints (joint mechanism)
- 13a link member (first member)
- 13b link member (second member)
- 14a swivel axis
- 15a to 15d intermediate members
- 16a to 16e intermediate axes
- 17 through-hole
- 18 through-hole (sheath pass-through hole)
- 20a, 20b pulleys (turnaround sections)
- 21a, 21b guide sheaths
- 22a, 22b manipulation wires
- 24a through-hole (wire pass-through sections)
- 30a, 30b tubular members (turnaround sections)
- 32a, 32b long holes (wire pass-through sections)
- 33a, 33b grooves (wire pass-through sections)
Claims
1. A joint mechanism comprising:
- a tubular first member having a through-hole extending along a central axis;
- a second member disposed at a distal end of the first member and swivelable relative to the first member about a swivel axis intersecting the central axis;
- a flexible, tubular guide sheath extending near the central axis of the through-hole in the first member and a distal end of which is fixed to the second member;
- a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and
- a turnaround section that is provided in the second member at a position decentered from the swivel axis in a radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member,
- wherein a distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the first member at a position decentered from the swivel axis of the first member in the radial direction.
2. The joint mechanism according to claim 1, wherein the turnaround section is a pulley around which the manipulation wire is wound to cause the manipulation wire to make a U-turn.
3. The joint mechanism according to claim 1, wherein the turnaround section is a substantially U-shaped tubular member that allows the manipulation wire to extend therethrough so as to cause the manipulation wire to make a U-turn.
4. The joint mechanism according to claim 1, wherein the guide sheath, the manipulation wire, and the turnaround section include a pair of guide sheaths, a pair of manipulation wires, and a pair of turnaround sections, respectively, so as to cause the second member to swivel relative to the first member in two directions about the swivel axis.
5. The joint mechanism according to claim 4, wherein the pair of turnaround sections are provided to cause the pair of manipulation wires to make a U-turn at positions partially overlapping each other in the radial direction.
6. The joint mechanism according to claim 1, further comprising one or more intermediate members provided between the first member and the second member and connected in a swivelable manner about two or more intermediate axes that are parallel to each other.
7. The joint mechanism according to claim 6, wherein each intermediate member is provided with a sheath pass-through hole that allows the guide sheath to extend therethrough and a wire pass-through section that allows the manipulation wire to extend therethrough, and
- wherein the wire pass-through section is a long hole or a cutout extending in a direction orthogonal to the intermediate axes.
8. A manipulator including two or more series-connected joint mechanisms,
- wherein the two or more series-connected joint mechanisms each comprise: a tubular first member having a through-hole extending along a central axis; a second member disposed at a distal end of the first member and swivelable relative to the first member about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the first member and a distal end of which is fixed to the second member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the second member at a position decentered from the swivel axis in a radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member, wherein a distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the first member at a position decentered from the swivel axis of the first member in the radial direction.
9. The manipulator according to claim 8, wherein the turnaround sections provided in the respective joint mechanisms are disposed at substantially identical positions in the radial direction and a circumferential direction of the second members.
10. The manipulator according to claim 8, wherein the turnaround sections provided in the respective joint mechanisms are disposed at substantially identical positions in the radial direction of the second members but at different positions in a circumferential direction.
11. A manipulator comprising:
- a tubular manipulator body;
- a basal-end joint unit provided at a distal end of the manipulator body; and
- a distal-end joint unit connected in series to a distal end of the basal-end joint unit and equipped with at least one joint mechanism,
- wherein the at least one joint mechanism comprises: a tubular first member having a through-hole extending along a central axis; a second member disposed at a distal end of the first member and swivelable relative to the first member about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the first member and a distal end of which is fixed to the second member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the second member at a position decentered from the swivel axis in a radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member, wherein a distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the first member at a position decentered from the swivel axis of the first member in the radial direction, and
- wherein the basal-end joint unit comprises: a swivel member connected to the manipulator body in a swivelable manner about a swivel axis; a tubular guide sheath whose opening at a distal end thereof is fixed to the manipulator body; and a manipulation wire that is introduced via the guide sheath and protrudes from the opening at the distal end of the guide sheath and a distal end of which is fixed to a position decentered from the swivel axis of the swivel member in a radial direction.
12. A manipulator comprising:
- a tubular manipulator body having a through-hole extending along a central axis;
- a swivel member disposed at a distal end of the manipulator body and swivelable relative to the manipulator body about a swivel axis intersecting the central axis;
- a flexible, tubular guide sheath extending near the central axis of the through-hole in the manipulator body and a distal end of which is fixed to the swivel member;
- a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and
- a turnaround section that is provided in the swivel member and that causes the manipulation wire introduced from the manipulator body via the guide sheath to make a U-turn toward the manipulator body,
- wherein a distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the manipulator body at a position decentered from the swivel axis in the radial direction.
13. A manipulator system comprising:
- a manipulator including two or more series-connected joint mechanisms;
- a slave device equipped with a driver that drives the manipulator;
- a master device equipped with an operation section to be operated by an operator; and
- a controller that controls the driver of the slave device based on an input signal input via the operation section of the master device,
- wherein the two or more series-connected joint mechanisms each comprise: a tubular first member having a through-hole extending along a central axis; a second member disposed at a distal end of the first member and swivelable relative to the first member about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the first member and a distal end of which is fixed to the second member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the second member at a position decentered from the swivel axis in a radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member, wherein a distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the first member at a position decentered from the swivel axis of the first member in the radial direction.
14. A manipulator system comprising:
- a manipulator including a tubular manipulator body, a basal-end joint unit provided at a distal end of the manipulator body, and a distal-end joint unit connected in series to a distal end of the basal-end joint unit and equipped with at least one joint mechanism;
- a slave device equipped with a driver that drives the manipulator;
- a master device equipped with an operation section to be operated by an operator; and
- a controller that controls the driver of the slave device based on an input signal input via the operation section of the master device,
- wherein the at least one joint mechanism comprises: a tubular first member having a through-hole extending along a central axis; a second member disposed at a distal end of the first member and swivelable relative to the first member about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the first member and a distal end of which is fixed to the second member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and
- a turnaround section that is provided in the second member at a position decentered from the swivel axis in a radial direction and that causes the manipulation wire introduced from the first member via the guide sheath to make a U-turn toward the first member, wherein a distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the first member at a position decentered from the swivel axis of the first member in the radial direction, and wherein the basal-end joint unit comprises: a swivel member connected to the manipulator body in a swivelable manner about a swivel axis; a tubular guide sheath whose opening at a distal end thereof is fixed to the manipulator body; and a manipulation wire that is introduced via the guide sheath and protrudes from the opening at the distal end of the guide sheath and a distal end of which is fixed to a position decentered from the swivel axis of the swivel member in a radial direction.
15. A manipulator system comprising:
- a manipulator;
- a slave device equipped with a driver that drives the manipulator;
- a master device equipped with an operation section to be operated by an operator; and
- a controller that controls the driver of the slave device based on an input signal input via the operation section of the master device,
- wherein the manipulator comprises: a tubular manipulator body having a through-hole extending along a central axis; a swivel member disposed at a distal end of the manipulator body and swivelable relative to the manipulator body about a swivel axis intersecting the central axis; a flexible, tubular guide sheath extending near the central axis of the through-hole in the manipulator body and a distal end of which is fixed to the swivel member; a manipulation wire introduced toward the distal end of the guide sheath via the guide sheath; and a turnaround section that is provided in the swivel member and that causes the manipulation wire introduced from the manipulator body via the guide sheath to make a U-turn toward the manipulator body, wherein a distal end of the manipulation wire caused to make a U-turn at the turnaround section is fixed to the manipulator body at a position decentered from the swivel axis in the radial direction.
Type: Application
Filed: Jul 8, 2016
Publication Date: Nov 3, 2016
Applicant: OLYMPUS CORPORATION (Tokyo)
Inventors: Shingo NAKAYAMA (Tokyo), Kosuke KISHI (Tokyo)
Application Number: 15/205,591