The present disclosure relates to a forceps device used for a manipulator of a surgical robot.
Medical treatments using robots (manipulators) have recently been proposed in order to reduce the burden on operators and save manpower in medical facilities. In the field of surgery, proposals have been made for surgical manipulator systems for operators to treat patients by operating remotely-controllable surgical manipulators. Various surgical tools may be attached to leading ends of surgical manipulators. Known surgical tools include, for example, forceps for grasping human tissue during surgery.
It is an aspect to provide a novel technology for improving the controllability of the operation of the forceps device.
According to an aspect of one or more embodiments, there is provided a forceps device comprising a grasping part; a support that holds the grasping part; a bearing mounted in a hole extending through the support; a first rotating shaft that is inserted in the bearing and turnably supports the support; a base member that holds the first rotating shaft; a plurality of grasping-portion wires that transmit driving forces to move the grasping part; a support wire that transmits a driving force to turn the support about the first rotating shaft; a plurality of first guide pulleys arranged coaxially with the first rotating shaft, the plurality of grasping-portion wires running over the plurality of first guide pulleys; and a support pulley formed as part of the support coaxially with the first rotating shaft, the support wire running over the support pulley.
According to another aspect of one or more embodiments, there is provided a forceps device comprising a plurality of grasping portions; a support that holds the plurality of grasping portions; a bearing in a hole extending through the support; a first rotating shaft that is in the bearing and that turnably supports the support; a base member that holds the first rotating shaft; a plurality of grasping-portion wires that transmit driving forces to move the plurality of grasping portions; a support wire that transmits a driving force to turn the support about the first rotating shaft; a plurality of first guide pulleys arranged coaxially with the first rotating shaft, the plurality of grasping-portion wires running over the plurality of first guide pulleys; and a support pulley formed as part of the support coaxially with the first rotating shaft, the support wire running over the support pulley.
According to yet another aspect of one or more embodiments, there is provided a forceps device comprising a plurality of grasping portions; a bearing in a hole extending through the support; a first rotating shaft in the bearing that turnably supports the support; a base member that holds the first rotating shaft; a support that holds the plurality of grasping portions and comprises a support pulley coaxial with the first rotating shaft; a plurality of wires that transmit driving forces to move the plurality of grasping portions; a support wire that transmits a driving force to turn the support about the first rotating shaft; and a plurality of first guide pulleys coaxial with the first rotating shaft, the plurality of wires running over the plurality of first guide pulleys, respectively. The support wire runs over the support pulley.
The above and other aspects will be described more fully below with reference to the drawings, in which:
A related art forceps device may include a first rotating shaft that turnably supports a support holding a grasping part, a base member that holds the first rotating shaft, a plurality of first guide pulleys arranged coaxially with the first rotating shaft, a plurality of grasping-portion wires that transmits driving forces to move the grasping part, the grasping-portion wires running between the plurality of first guide pulleys and the grasping part without other pulleys, and a second rotating shaft that turnably supports second guide pulleys located upstream of the first guide pulleys.
However, there are several disadvantages to the related art technology. For example, if the tensions of the grasping-portion wires are increased so as to increase the grasping force of the grasping part of the aforementioned forceps device, the frictional force between the first rotating shaft and the support increases, which lowers the controllability of the bending movement of the support including the grasping part about the first rotating shaft.
It is thus an aspect to provide a novel technology for improving the controllability of the operation of the forceps device.
To address the aforementioned disadvantages, a forceps device according to one or more embodiments may include a grasping part; a support that holds the grasping part; a bearing mounted in a hole extending through the support; a first rotating shaft that is inserted in the bearing and turnably supports the support; a base member that holds the first rotating shaft; a plurality of grasping-portion wires that transmit driving forces to move the grasping part; a support wire that transmits a driving force to turn the support about the first rotating shaft; first guide pulleys arranged coaxially with the first rotating shaft, the grasping-portion wires running over the first guide pulleys; and a support pulley formed as part of the support coaxially with the first rotating shaft, the support wire running over the support pulley.
According to this configuration, the frictional force between the first rotating shaft and the support is reduced.
In some embodiments, the bearing may be a rolling bearing. This configuration further reduces the frictional force between the first rotating shaft and the support. In some embodiments, the bearing may be a plain bearing.
In some embodiments, the rolling bearing may have a diameter of 3.6 to 4.5 mm, and the first guide pulleys may have a diameter of 3.0 to 3.6 mm. The rolling bearing may have a diameter larger than that of the first guide pulleys.
A method, a device, a system, and the like consistent with the above described embodiments may also be provided.
According to various embodiments, the controllability of the operation of the forceps device may be improved.
Various embodiments will now be described with reference to the drawings. Components, members, and processes that are the same as or equivalent to each other illustrated in the drawings are represented by the same reference numerals, and redundant explanation will not be repeated for conciseness. The various embodiments are not limited to those described herein, but rather are examples, and in the various embodiments, it is to be understood that any feature or any combination of features described are not necessarily essential to the invention.
The forceps device 10 illustrated in the drawings includes a pair of grasping portions 12a and 12b (collectively a grasping part 12), a support 14 that holds the pair of grasping portions 12a and 12b, a first rotating shaft 16 that turnably supports the support 14, a base member 18 that holds the first rotating shaft 16, four guide pulleys 20 arranged coaxially with the first rotating shaft 16, a second rotating shaft 22 that turnably supports the pair of grasping portions 12a and 12b and is held by the support 14, four jaw pulleys 24 supported coaxially with the second rotating shaft 22, four wires 26, 28, 30 and 32 running over the four guide pulleys 20 and the four jaw pulleys 24, and support wires 38 and 40 for turning the support 14 about the first rotating shaft 16.
Next, the base member 18 will be described. As illustrated in
The arms 18a and 18b each have a base part 18c holding the third rotating shaft 36, and a distal end part 18d that holds the first rotating shaft 16 and that is thinner than the base part 18c. In other words, the distance between the distal end parts 18d is larger than the distance between the base parts 18c. Thus, as illustrated in
Furthermore, the circumferential width W1 of the distal end part 18d of the arm 18a (the arm 18b) is smaller than the circumferential width W2 of the base part 18c thereof. Thus, a U-shaped recess is formed at the distal end part 18d at which interference with a wire may be addressed, and the circumferential width of the distal end part 18d is made larger than the circumferential width of the base part 18c, which minimizes deterioration of the stiffness of the arm.
In some embodiments, as illustrated in
As illustrated in
In the forceps device 10 having such a structure, the support 14 in a state in which a plurality of guide pulleys 20 are supported by the outer circumference of the first rotating shaft 16 is held by the base member 18 with the first rotating shaft 16 therebetween. This configuration facilitates improvement in the easiness of assembly as compared with a case where the support 14 is held directly by the base member 18.
In some embodiments, the base member 18 has the pair of arms 18a and 18b facing each other. The first rotating shaft 16 is firmly fixed in such a manner that the axial ends thereof are press-fitted to the pair of arms 18a and 18b. As a result, because the distal ends of the pair of arms 18a and 18b, which can be free ends, are fixed by the rotating shaft, the stiffness of the whole base member 18 increases.
Each of the wires 26, 28, 30 and 32 transmits a driving force to the grasping portion 12a or the grasping portion 12b to move the grasping portion 12a or the grasping portion 12b. Specifically, the wire 26 and the wire 32 run over the jaw pulleys 24 for the grasping portion 12b, and the grasping portion 12b moves in an opening direction when the wire 26 is pulled and moves in a closing direction when the wire 32 is pulled. The wire 28 and the wire 30 run over the jaw pulleys 24 for the grasping portion 12a, and the grasping portion 12a moves in a closing direction when the wire 28 is pulled and moves in an opening direction when the wire 30 is pulled.
In some embodiments, each of the four guide pulleys 20 has a corresponding one of the wires 26, 28, 30 and 32 placed thereover. As illustrated in
A support pulley 42, over which the wires 38 and 40 for transmitting a driving force for turning the support about the first rotating shaft 16 run, is formed integrally with part of the support 14. The support pulley 42 is arranged coaxially with the first rotating shaft 16. Thus, when one of the wires 38 and 40 is pulled to turn the support 14, the tension of the wire 38 or 40 running over the support pulley 42 presses the support 14 toward the first rotating shaft 16. A normal force received by the support 14 from the first rotating shaft 16 is thus generated, which contributes to an increase in frictional force. In some embodiments, when one of the wires 26, 28, 30, and 32 is pulled to turn the grasping portions 12a and 12b, the tension of the wires 26, 28, 30, and 32 is applied to the second rotating shaft 22 via the jaw pulleys 24. The force applied to the inner circumference of the through-hole of the support 14 for supporting the second rotating shaft 22 is then transmitted to the circular through-hole 14a in which the bearing 15 is mounted, and the support 14 is thus pressed toward the first rotating shaft 16. In this case as well, a normal force received by the support 14 from the first rotating shaft 16 is generated, which contributes to an increase in frictional force.
In the forceps device 10, however, the bearing is provided between the support 14 and the first rotating shaft 16, which reduces the frictional force between the first rotating shaft 16 and the support 14. Note that, when the bearing 15 is a rolling bearing, the frictional force between the first rotating shaft 16 and the support 14 can further be reduced. Consequently, the movement of the grasping portions 12a and 12b becomes smoother, and the controllability of the forceps device 10 improves. Note that the bearing may be a plain bearing. The bearing 15 may have a diameter of 3.6 to 4.5 mm, and the guide pulleys 20 may have a diameter of 3.0 to 3.6 mm. The bearing 15 may have a diameter larger than that of the guide pulleys 20.
Next, jaw parts constituting the grasping portions will be described in detail.
As illustrated in
Next, the manner in which the wires 26, 28, 30 and 32 run over the pulleys will be described in detail. The wire 26 runs between the guide pulley 20A and the jaw pulley 24c. The wire 28 runs between the guide pulley 20B and the jaw pulley 24a. The wire 30 runs between the guide pulley 20D and the jaw pulley 24b. The wire 32 runs between the guide pulley 20C and the jaw pulley 24d.
As illustrated in
In some embodiments, as illustrated in
In some embodiments, the forceps device 10 includes the guide pulley 34a on the upstream side of the guide pulley 20A (on the side opposite the grasping portions) and on the second side S2 with respect to the vertical cross section V, the guide pulley 34b on the upstream side of the guide pulley 20B and on the second side S2 with respect to the vertical cross section V, the guide pulley 34c on the upstream side of the guide pulley 20C and on the first side S1 with respect to the vertical cross section V, and the guide pulley 34d on the upstream side of the guide pulley 20D and on the first side S1 with respect to the vertical cross section V.
As a result, when the support 14 is bent in either direction about the first rotating shaft 16, one or more of the wires 26, 28, 30 and 32 come in contact with the associated one or more of the guide pulleys 20A to 20D, which stabilizes the controllability when the support 14 is turned. More specifically, when the support 14 is bent from the state illustrated in
Because the grasping portions 12a and 12b of the forceps device 10 are operated inside the abdominal cavity of a patient, it is advantageous to devise a way to prevent gas around the grasping portions 12a and 12b from leaking out through the forceps device 10 so that the air pressure in the abdominal cavity, which is increased to be higher than the atmospheric pressure, does not lower. In some embodiments, sealing is therefore provided in a region including the base member 18.
The base member 18 includes a partition part 18g having a plurality of grasping-portion-wire holes 56, 58, 60 and 62 through which the wires 26, 28, 30 and 32, respectively, pass, and the pair of arms 18a and 18b which extend from an outer edge of the partition part 18g toward the grasping part (upward in
The partition part 18g is a partition formed between a cylindrical part 18h and the pair of arms 18a and 18b. The grasping-portion-wire holes 56 and 58 are a pair of grasping-portion-wire holes that are adjacent to each other at the closet distance, and the grasping-portion-wire holes 60 and 62 are a pair of grasping-portion-wire holes that are adjacent to each other at the closest distance.
As illustrated in
Hence, in the forceps device 10, the wire 26 is guided by the guide pulley 52a, so that the wire 26 is separated from the wire 28. Similarly, the wire 30 is guided by the guide pulley 52b, so that the wire 30 is separated from the wire 32. In this manner, the grasping-portion-wire hole 56 through which the wire 26 passes and the grasping-portion-wire hole 58 through which the wire 28 passes can be separated from each other. Similarly, the grasping-portion-wire hole 60 through which the wire 30 passes and the grasping-portion-wire hole 62 through which the wire 32 passes can be separated from each other.
In some embodiments, the base member 18 includes an elastic sealing member (having a type A durometer hardness of 30 to 70) arranged on one side (on one side opposite the side in which the grasping portions 12a and 12b are located) with respect to the partition part 18g. The sealing member is a silicone resin film having a thickness of about 0.5 to 2 mm, for example.
The sealing member has a plurality of sealing holes at positions corresponding to those of the grasping-portion-wire holes 56, 58, 60 and 62. This configuration enables sealing with the sealing member, with the wires 26, 28, 30 and 32 passing through the partition part 18g of the base member 18. The wires have a diameter q of 0.4 to 0.5 mm, and the diameter of the grasping-portion-wire holes is preferably slightly larger than the wire diameter.
The sealing holes have a diameter that is smaller than the diameter of the grasping-portion-wire holes and smaller than the diameter (wire diameter q) of the grasping-portion wires. As a result, even when a gap is present between a grasping-portion-wire hole and a grasping-portion wire, the sealing hole and the grasping-portion wire are in close contact with each other, which reduces leakage of gas from the grasping part side to the outside of the forceps device 10 via the base member 18.
As illustrated in the drawings, the four grasping-portion-wire holes may be formed through the partition part 18g at certain distances from each other. Thus, the sealing holes formed at positions corresponding to those of the grasping-portion-wire holes are also separated from the adjacent sealing holes.
In some embodiments, the forceps device 10 includes the pair of wires 38 and 40 for turning the support 14 about the first rotating shaft 16 In some embodiments to the wires 26, 28, 30 and 32, which are grasping-portion wires. The partition part 18g of the base member 18 therefore has support-wire holes 74 and 76 through which the wires 38 and 40, respectively, pass. The support-wire holes 74 and 76 are formed at point-symmetric positions with respect to the center Z of the partition part 18g (the central axis of the cylindrical part 18h).
In some embodiments, the sealing member has a plurality of sealing holes formed at positions corresponding to those of the support-wire holes 74 and 76. This enables sealing with the sealing member, with the wires 38 and 40 passing through the partition part 18g of the base member 18. The diameter of the support-wire holes is preferably slightly larger than the wire diameter. In some embodiments, the arrangement of the pulleys of the forceps device 10 is devised so that a plurality of holes for wires formed in the partition part 18g of the base member 18 can be suitably separated from each other. This configuration reduces such a problem as unintended integration of holes for wires in forming the sealing member having a plurality of holes for wires.
In the forceps device 10 illustrated in
Thus, the forceps device 10 includes a turning restricting mechanism for restricting turning of the support to prevent the turning support 14 from touching the grasping-portion wires 26, 28, 30, and 32. The turning restricting mechanism includes a stopper having a face with which part of the turning support comes into contact.
The stopper 82 is a block-like rectangular parallelepiped member having a flat face 82a, which faces the support 14, serving as the face with which the turning support comes into contact. When a contact face 14b of the support 14 comes into contact with the flat face 82a (see
As described above, because the support 14 and the stopper 82 directly come in contact with each other, the turning restricting mechanism can more reliably prevent contact between the support and the grasping-portion wires.
In some embodiments, as illustrated in
Note that, in some embodiments, the contact angle β may be 70° or larger. In some embodiments, the contact angle β may be larger than 90°. This configuration enables control of the turning of the support at least up to 70°. If the contact angle β is too large, however, the support 14 may touch the grasping-portion wires before the support 14 comes into contact with the stopper 82. In an embodiment, the contact angle β may be therefore smaller than a turning angle at which the support 14 touches a grasping-portion wire. Specifically, in an embodiment, the contact angle β may be smaller than 110°. In some embodiments, the contact angle β may be smaller than 100°.
Note that, if the contact angle β varies, the support 14 may unintentionally touch a grasping-portion wire. Positioning of the stopper 82 is therefore important. The stopper 82 is positioned relative to the base member 18. As a result, both the support 14 and the stopper 82 are at predetermined positions relative to the base member 18, which improves the accuracy of relative positions of the support 14 and the stopper 82.
Specific positioning in the embodiment will be explained. As illustrated in
In some embodiments, the partition part 18g at the base part of the arms 18a and 18b of the base member 18 has a plurality of projections 86a, 86b, and 88 used for positioning of the stopper 82. The shapes and the arrangement of the projections 86a and 86b are set for positioning in a direction Ay intersecting the central axis Ax when the projections 86a and 86b come in contact with a pair of side faces 82c, which are opposite each other, of the stopper 82. In some embodiments, the shape and the arrangement of the projection 88 are set for positioning in a direction Az intersecting the central axis Ax and the direction Ay when the projection 88 is fitted into a groove 82d formed at a lower portion of the stopper 82. Thus, the stopper 82 can be accurately positioned in the directions Ay and Az intersecting the axial direction Ax of the base member 18.
In some embodiments, as illustrated in
In the forceps device 10, the arrangement of the pulleys is devised so as to improve the durability of the wires while allowing some degree of wire winding angle. Specifically, as illustrated in
This configuration enables comfortable operation control with the turning angle of the support 14, which holds the grasping portions 12a and 12b, being at least within a range of +65°. Note that the winding angle γ may be 89° or larger. This configuration enables comfortable operation control with the turning angle of the support, which holds the grasping portions 12a and 12b, being at least within a range of ±89°.
The guide pulley 52a is located upstream of the guide pulleys 34a and 34b, and the grasping-portion wire 26 runs over the guide pulley 52a. The guide pulley 52a is shifted toward one side (toward S2) relative to immediately below the guide pulleys 20A and 20B and shifted toward the other side (toward S1) relative to immediately below the guide pulleys 34a and 34b when the first rotating shaft 16 is viewed in front in the axial direction in the state in which the leading ends of the grasping portions 12a and 12b point upward. This configuration increases the radius of curvature of an S-shaped curve of the grasping-portion wire 26 running over the guide pulley 34a and the guide pulley 52a. Furthermore, as a result of the increase in the radius of curvature of the S-shaped curve of the grasping-portion wire 26, bending stress generated in the grasping-portion wire 26 is lowered, and the durability of the grasping-portion wires relating to opening and closing movements of the grasping portions 12a and 12b is improved.
Similarly, as illustrated in
The guide pulley 52b is located upstream of the guide pulleys 34d and 34c, and the grasping-portion wire 30 runs over the guide pulley 52b. The guide pulley 52b is shifted toward one side (toward S1) relative to immediately below the guide pulleys 20D and 20C and shifted toward the other side (toward S2) relative to immediately below the guide pulleys 34d and 34c when the first rotating shaft 16 is viewed in front in the axial direction in the state in which the leading ends of the grasping portions 12a and 12b point upward. This configuration increases the radius of curvature of an S-shaped curve of the grasping-portion wire 30 running over the guide pulley 34d and the guide pulley 52b. Furthermore, as a result of the increase in the radius of curvature of the S-shaped curve of the grasping-portion wire 30, bending stress generated in the grasping-portion wire 30 is lowered, and the durability of the grasping-portion wires relating to opening and closing movements of the grasping portions 12a and 12b is improved.
Note that, as illustrated in
Note that the base member 18 is a cylindrical part having an outer diameter of 7 to 9 mm. Furthermore, the guide pulleys 20A to 20D have a diameter of 3.0 to 3.6 mm, the guide pulleys 34a to 34d have a diameter of 3.0 to 3.6 mm, and the guide pulleys 52a and 52b have a diameter of 3.0 to 3.6 mm. As a result, in a forceps device having a very small outer diameter, the radius of curvature of each S-shaped curve can be increased while appropriate winding angles are achieved.
While various embodiments have been described above with reference to the drawings, the various embodiments are not limited to the description above, and any combination or substitution of components as appropriate is included in the scope of the appended claims. In addition, modifications such as combinations, changes in the order of processes, and various changes in design may be made on an embodiment on the basis of knowledge of a person skilled in the art, and such modified embodiments may be within the scope of the appended claims.
This Application is a Continuation Application of International Application No. PCT/JP2022/001340, filed on Jan. 17, 2022 in the Japan Patent Office, the contents of which being herein incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | PCT/JP2022/001340 | Jan 2022 | WO |
Child | 18773791 | US |