Source: https://patents.google.com/patent/KR101767060B1/en
Timestamp: 2019-10-23 02:55:31
Document Index: 164421298

Matched Legal Cases: ['Application No. 61', 'Application No. 61', 'Application No. 61', 'Application No. 61', 'art 22', 'art 24', 'art 22', 'art 22', 'art 24', 'art 22', 'art 22', 'art 24', 'art 24', 'art 24', 'art 22', 'art 54', 'art 56', 'art 24', 'art 56', 'art 56', 'art 54', 'art 56', 'art 54', 'art 56', 'art 56', 'art 22', 'art 22']

KR101767060B1 - Surgical tool with a compact wrist - Google Patents
KR101767060B1
KR101767060B1 KR1020127015018A KR20127015018A KR101767060B1 KR 101767060 B1 KR101767060 B1 KR 101767060B1 KR 1020127015018 A KR1020127015018 A KR 1020127015018A KR 20127015018 A KR20127015018 A KR 20127015018A KR 101767060 B1 KR101767060 B1 KR 101767060B1
KR1020127015018A
KR20120095964A (en
그레고리 닥스2세
토드 머피
2009-11-13 Priority to US61/260,915 priority Critical
2009-11-13 Priority to US61/260,903 priority
2009-11-13 Priority to US26090309P priority
2009-11-13 Priority to US61/260,910 priority
2010-11-12 Priority to PCT/US2010/056607 priority patent/WO2011060315A2/en
2012-08-29 Publication of KR20120095964A publication Critical patent/KR20120095964A/en
2017-08-10 Publication of KR101767060B1 publication Critical patent/KR101767060B1/en
A two-degree of freedom wrist 70, a wrist articulation by the linked traction members 218, 220, 222 and 224, a mechanism 372 and 390 for transmitting the torque through the angle, and a minimally invasive surgery A tool is disclosed. An elongate intermediate wrist member 80 is pivotally connected to the distal end of the instrument shaft 74 to rotate about a first axis transverse to the shaft and an end actuator body 72 is pivotably connected to the intermediate member And can rotate about a second axis transverse to the first axis. Linked traction members 218, 220, 222, 224 interact with attachment features 180, 182, 184, 186 to articulate the wrist. The torque-transfer mechanisms 372 and 390 include connecting members 384 and 394, connecting pins 398 and 400, a driving shaft 392, and a driven shaft 396. A drive shaft is connected to the driven shaft, whereby the relative orientation of the drive shaft, the connecting member, and the driven shaft can be controlled.
[0001] SURGICAL TOOL WITH A COMPACT WRIST [0002]
This application claims priority from U.S. Provisional Application No. 61 / 260,903 entitled " Wrist Jointing by Linked Retraction Members "(Attorney Docket No. No. ISRG02320 PROV), filed November 13, 2009; U.S. Provisional Application No. 61 / 260,910 entitled " Dual Universal Joint "(Attorney Docket No. No. ISRG02340PROV), filed November 13, 2009; And U.S. Provisional Application No. 61 / 260,915, filed on November 13, 2009, entitled "Surgical Tool With Two Degrees of Freedom" (Attorney Docket No. ISRG02350PROV), the entire contents of which are incorporated herein by reference &Lt; / RTI &gt; The present invention is related to U.S. Provisional Application No. 61 / 260,907 entitled "End Actuator with Extra Closure Mechanism" (Attorney Docket No. ISRG02330 PROV), filed November 13, 2009; And 61 / 260,919, filed November 13, 2009, entitled &quot; Motor Interface for Parallel Drive Shafts in Independently Rotating Members "(Attorney Docket No. No. ISRG02360PROV) The contents of which are incorporated herein by reference.
Minimally invasive surgical techniques aim to reduce patient recovery time, discomfort, and harmful side effects by reducing the amount of external tissue damaged during diagnosis or surgery. As a result, the use of minimally invasive surgical techniques can shorten the mean hospital stay in standard surgery. In addition, minimally invasive surgery can reduce patient recovery time, patient inconvenience, surgical side effects, and time to return to work.
A common form of minimally invasive surgery is endoscopy, and a common form of endoscopy is laparoscopy, which is a minimally invasive procedure and / or surgery performed in the abdominal cavity. In standard laparoscopic surgery, a patient's stomach can be inflated with gas, and the cannula sleeve can be passed through a small (about 1/2 inch or less) incision to provide the entrance to the laparoscopic instrument.
A laparoscopic surgical instrument generally includes an endoscope (e.g., laparoscope) for viewing the surgical site and a tool for working at the surgical site. Work tools are typically similar to those used in conventional (laparotomy) operations, except that the working end or end effector of each tool is pushed by an elongated tube (e.g., a tool shaft or a main shaft) As shown in Fig. The end effector may include, for example, a clamp, a grasser, a scissors, a stapler, a cautery tool, a straight cutter, or a needle holder.
To perform the surgical procedure, the surgeon sends the surgical tool through the cannula sleeve to the internal surgical site and manipulates the surgical tool from the outside of the abdomen. The surgeon looks at the surgical procedure from a monitor that displays an image of the surgical site taken by the endoscope. Similar endoscopic techniques are used, for example, in arthroscopy, posterior peritoneal, pelvic, elongate, cystoscopy, brain landscape, paranasal sinuses, cervix, and urethra.
A minimally invasive remote surgical robot system is being developed to increase the physician 's hand workability when working in the internal surgical site and to enable the doctor to operate the patient from a remote location (outside the sterilization site). In the remote surgical system, the surgeon's image is usually provided to the surgeon in the control console. While viewing the three-dimensional image of the surgical site in a suitable viewer or display, the doctor manipulates the main input device or control device of the control console to perform the surgical procedure on the patient. Each main input device controls the operation of a surgical instrument that is actuated / articulated in a servo mechanism manner. During the surgical procedure, the remote surgical system can provide mechanical operation and control for a variety of surgical instruments and instruments. Most remote surgical instruments have a gripper or other articulated end effector that performs various functions for the physician, for example, they may hold or release the needle in response to manipulation of the main input device, grab the blood vessel, And the like. Tools with a distal wrist joint allow the physician to orient the tool within the internal surgical site, thereby significantly increasing the freedom of the physician to interact (and treat) with the tissue in real time.
Remote surgical systems are finding increasing use by physicians for various treatments that are growing. New tools will help keep this growth going, especially tools such as staplers, straight cutters, etc. (which can impart significant clamping forces and other forces to internal tissues). Unfortunately, it can be a difficult task to deliver the desired telesurgical end-end actuator force through the existing tool wrists, especially with the time, accuracy, flexibility, and reliability in the tools preferred for remote surgical operations.
For example, non-robotic surgical instruments including straight clamping, cutting and stapling devices have been used in many different surgical procedures. These tools can be used to exclude cancerous or abnormal tissue from the gastrointestinal tract. Unfortunately, many conventional surgical tools, including conventional straight clamping, cutting and stapling tools, require a desired torque (e.g., tissue clamping torque) or force across a compact articulated wrist (e.g., ), Which may reduce the efficiency of the surgical tool. Alternative tools with shaft drive clamping mechanisms also fail to provide rotational motion of the end effector that mimics the natural motion of the physician's wrist.
It would be desirable to provide an improved surgical and / or robotic wrist structure for the reasons described above. It would also be desirable to provide an improved minimally invasive surgical tool that includes a wrist mechanism that mimics the natural movement of the physician's wrist while allowing for enhanced end-effector forces and response times appropriate for remote surgical control.
A surgical tool having a wrist of 2 degrees of freedom, and related methods are provided. The disclosed surgical instrument may be particularly beneficial when used in minimally invasive surgery. In many embodiments, the intermediate wrist member is pivotally connected to the distal end of the instrument shaft so as to be rotatable about a first axis transverse to the shaft, and the end effector body rotates about a second axis transverse to the first axis And is pivotally connected to the intermediate member. This two degrees of freedom wrist can be used to articulate the end effector body in a manner that mimics the natural motion of the physician &apos; s wrist, thereby providing a desired magnitude of maneuverability to the end effector body. In many embodiments, the intermediate member has an elongated shape. The elongated shape includes a movable component, for example, a movable component that articulates the end effector body with respect to the instrument shaft, and a movable component that articulates one or more end effector features to the end effector body (e.g., , The drive shaft). In many embodiments, the wrist of two degrees of freedom includes an internal passageway that guides the control cable. This internal passageway can be configured to suppress changes in the control cable tension while pivoting about the first and second axes.
A typical embodiment provides wrist articulation through a linked traction member. In many embodiments, the end effector is coupled to the distal end of the elongate shaft through a joint of two degrees of freedom, thereby allowing the end effector to be oriented within the internal surgical space. In an exemplary embodiment, the opposing movement of the traction member is such that the end actuator is angled relative to the shaft, and the connecting surface slides between the traction member and the end actuator to change the position of the traction member relative to the orientation of the end actuator An undesirable change in the tension of the pulling member can be suppressed. When the traction members are used as a linked pair by restraining such changes in the tension of the traction member, for example when the opposite traction members share a common linear drive mechanism (e.g., a motorized capstan) Harmful control cable slack and / or overstress of the element can be avoided. By activating the traction member in a linked pair, it is possible to provide a smooth, instantaneous reaction jointing of the end effector to the shaft. In addition, wrist articulation with the linked traction member can be used to reduce the length of the surgical tool on the circle of the shaft, which improves accessibility to limited body space, angle of approach to body structure, and visibility of body structure .
There is also provided a minimally invasive surgical instrument comprising a mechanism for transmitting torque through an angle, a mechanism for transmitting torque through an angle, and an associated method. The disclosed mechanism can be used, for example, to transmit torque to a shaft-driven actuation mechanism of a surgical end actuator mounted on a mechanism shaft via a wrist of two degrees of freedom. A surgical end actuator (not shown) mounted to the distal end of the instrument shaft through a wrist of two degrees of freedom to mimic the (relatively fast) natural motion of the physician &apos; s wrist in many surgical applications (e.g., May be advantageous to use. By actuating the end effector with a rotary shaft drive, a high level of force can be applied to the tissue through the narrow shaft. For example, such a shaft drive mechanism may be used to actuate the clamping jaws of the end actuators, thereby creating a high clamping force. A typical embodiment can deliver sufficient torque through the angled wrist of a minimally invasive surgical tool using a relatively simple dual ball / socket joint system wherein the ends of the ball are connected together to constrain the socket angle, This torque is transmitted. This simple arrangement aids in miniaturization which is suitable for use in, for example, surgical instruments. In addition, this simple arrangement can improve the reliability of the tool transmitting torque through an angle exceeding 60 degrees, thereby allowing a substantial reorientation of the end effector relative to the instrument shaft. In many embodiments, the rotational speeds of the drive shaft and the driven shaft are substantially the same even when the drive shaft and the driven shaft are not parallel, which can help to provide a smooth transfer of torque through the angle.
In a first aspect, a minimally invasive surgical tool is provided. The surgical tool comprises a tubular instrument shaft having a proximal end, a proximal end and an aperture therebetween; An end actuator including an end actuator body; An intermediate wrist member pivotally connected to the distal end of the shaft and pivotally connected to the end actuator body; And a moveable system extending distally through the hole in the shaft to orient the end effector body and actuate the end effector. The mechanism shaft has a mechanism shaft axis. Turning the intermediate body relative to the shaft and orienting the intermediate member about the first axis relative to the shaft. The end actuator body is pivoted relative to the intermediate member to orient the end actuator body about the second axis with respect to the intermediate member. The first axis traverses the shaft axis. The second axis traverses the first axis. The intermediate member has an outer width along the first axis and an outer length along the second axis. The length is significantly different from the width, whereby the intermediate member has an elongated cross section. A portion of the movable system is spaced outwardly from an elongate cross-section of the intermediate member between the shaft and the end actuator body.
The intermediate member may include one or more additional features and / or features. For example, the width of the intermediate member may be less than 1/4 of the length of the intermediate member. The first axis and the second axis may be within 2 mm on the same plane. The first axis and the second axis may be coplanar. The intermediate member may comprise an internal passage for guiding the control cable of the actuating system between the mechanism shaft and the end actuator body.
The surgical tool may include one or more additional features and / or features. For example, the surgical tool may include a first joint pivotally connecting the shaft to the intermediate member and a second joint pivotally connecting the intermediate member to the end actuator body. The first joint may include a single pivot shaft extending along the first axis within the width of the intermediate member such that the first joint is disposed within a central region between the distinct shaft of the outer disengaged portion of the movable system and the end actuator body . The second joint may include first and second coaxial pivot shafts separated along the second axis. The intermediate member may comprise an internal passage for guiding the control cable of the actuating system between the instrument shaft and the end actuator body and between the coaxial turning shafts of the second joint. The surgical tool may include a support member fixedly connected to the instrument shaft and pivotally connected to the intermediate member for rotation about a first axis. The support member may include an internal passageway for guiding the control cable of the moveable system between the aperture of the instrument shaft and the end actuator body. The guiding surface can restrain the control cable such that changes in cable tension are suppressed while pivoting about the first and second axes.
The moving system may include one or more additional features and / or features. For example, the outer separated portion of the movable system may include a first rotatable drive shaft for driving a first actuation mechanism of the end effector. The first drive shaft may extend between the end actuator body and the aperture so as to pass adjacent the first side of the intermediate member. The outer disengaged portion of the movable system may include a second rotatable drive shaft for driving a second actuation mechanism of the end effector. The second drive shaft may extend between the end actuator body and the aperture so as to pass adjacent the second side of the intermediate member, and the second side faces the first side. The oriented portion of the movable system can be operated to change the orientation of the end actuator body relative to the mechanism shaft about the first and second axes. The orientation portion is reversible so that force applied to alter its orientation in the end effector body is transmitted proximally through the aperture by the actuation system. Operation of the end effector may include articulation of the joint of the end effector.
In another aspect, a method of manufacturing a minimally invasive surgical tool is provided. The method includes the steps of pivotally connecting an intermediate member to an instrument shaft so as to rotate about a first axis oriented not parallel to the longitudinal direction of the instrument shaft, a step of pivotally connecting a first axis and a second axis oriented non- , Pivotally connecting the end effector to the instrument shaft, and coupling the actuation mechanism with the end effector. The actuation mechanism can be actuated to change the orientation of the end effector in two dimensions in the longitudinal direction. At least a portion of the actuation mechanism extends between the end actuator and the aperture of the instrument shaft so as to pass outwardly away from at least one side of the intermediate member.
In the method of manufacturing a minimally invasive surgical tool, the intermediate member connected to the instrument shaft to which the end effector is connected may comprise one or more additional features and / or features. For example, the first axis may be normal to the second axis. At least one of the first axis or the second axis may be normal to the longitudinal direction of the instrument-shaft. The intermediate member has an outer width in the first axial direction and a maximum outer length in the second axial direction, and the maximum outer length is larger than the width in the first axial direction. The intermediate member may have a maximum outer width in the first axial direction, which is less than 1/3 of the outer length. The intermediate member may include an internal passageway for guiding the control cable that extends between the end actuator and the aperture of the instrument shaft. The guiding surface can restrain the control cable such that changes in cable tension are suppressed while pivoting about the first and second axes.
The method may include additional steps. For example, the method may further comprise connecting the end actuator control cable through the intermediate member internal passageway. The method may further comprise reversing the actuation mechanism by changing the orientation of the end effector relative to the instrument shaft such that the force applied to alter its orientation to the end effector is transmitted by the actuation system through the hole Can be delivered proximal. The actuation of the end effector may include articulating the joint of the end effector.
In another aspect, a minimally invasive surgical method is provided. The method includes the steps of inserting a surgical end effector of the tool through the minimally invasive opening or natural opening into the internal surgical site, rotating the intermediate member of the tool about the shaft of the tool about the first joint, Orienting the end effector about a second axis with respect to the intermediate member by pivoting the end effector relative to the intermediate member about the second joint, Mechanical actuation of the end effector by a move-system component passing between the outer branched end actuator and the aperture. One of the first and second joints includes a center joint, which is a centered joint disposed within the center of the cross section of the tool. In this method, the operation of the end effector includes articulating the joint of the end effector.
In another aspect, a minimally invasive surgical tool is provided. The surgical tool includes an elongated first link, a second link, four attachment features disposed on the second link, and four pull members. The elongated first link has a distal end, a proximal end, and a first link axis defined therebetween. The first link has a shaft hole. The second link is pivotally connected to the distal end of the first link, thereby orienting the second link about the first axis and the second axis. The first and second axes are not parallel to the first link axis. The first axis is not parallel to the second axis. The four traction elements extend distally from within the hole of the first link to the attachment feature such that the opposite axial movement of the traction element causes the second link to angularly orient about the first link about the first axis, can do. The connecting surface between the traction member and the attachment feature changes the position of the traction member relative to the second link relative to the angled orientation of the second link relative to the first link, have.
The first and second axes may have one or more additional features. For example, the first and second axes may not intersect. The first and second shafts can be separated by various distances, for example, 2 mm or less. The first axis may traverse the first link axis and the second axis may traverse the first axis.
Each traction member may interact with a corresponding attachment feature to selectively constrain movement of the traction member. For example, each traction member may pivot about a first associated center relative to one of the attachment features as the second link pivots about the first axis. Each traction member may pivot about a second associated center relative to one of the attachment features as the second link pivots about the second axis. The pulling member can be slidably engaged with the attachment feature. The connecting surface may include a curved cylindrical surface having a circular cross section and a concatenated shaft of the curved line, the circular cross section defining the center of the cross section, and the concatenated shaft of the curve defining the center of curvature. The first and second associated centers may correspond to a cross-sectional center or a curvature center, respectively.
The attachment feature can include a curved portion. For example, each attachment feature may include a curved portion. Each traction member may include an attachment lug configured to receive one of the curved portions slidably such that when the second link is pivoted about one of the first and second axes, It slides in opposite direction and moves. Each curved portion may include a centerline lying in a plane perpendicular to the first axis or the second axis. Each curved portion may have a first radius of curvature about its curvilinear centerline and a fixed center of curvature for its curvilinear centerline. The fixed center of curvature may be in a plane containing at least one of the first axis or the second axis, respectively. The curved portion centerline may be tangent to a plane containing at least one of the first axis or the second axis, respectively.
The attachment features may include attachment lugs. For example, each attachment feature may include attachment lugs. Each traction member may include a curved portion configured to be slidably received in one of the attachment lugs such that the curved portion is received within the attachment lug as the second link pivots about one of the first and second shafts Slip in. Each attachment lug may have a connection hole axis oriented parallel to the first axis or the second axis. Each connection hole axis may be placed in a plane containing at least one of the first axis and the second axis. Each curved portion may include a curved centerline lying in a plane perpendicular to the first or second axis. Each curved portion may have a first radius of curvature about its curvilinear centerline and a fixed center of curvature for its curvilinear centerline. The fixed center of curvature may be in a plane containing at least one of the first axis or the second axis, respectively. The curved portion centerline may be tangent to a plane containing at least one of the first axis or the second axis, respectively.
The diagonally opposed tow members can be paired together and operated at the same time. For example, each attachment feature may be diverted from the first and second axes as viewed along the first link axis, one of the attachment features defining an angle defined by the first and second axes as viewed along the first link axis Lt; / RTI &gt; The first diagonally opposed pair of towing members may be actuated by at least one cable extending from the first diagonally opposed pair of first towing members to the first diagonally opposed pair of second towing members, The cable is wrapped around the first capstan. By varying the position of the first diagonally opposed pair of tow members with respect to the second link, the tension of at least one cable that can be imparted when the tow member is connected to the attachment feature with spherical center joint is suppressed . A second diagonally opposed pair of towing members may be actuated by at least one cable extending from a second diagonally opposed pair of first tow members to a second diagonally opposed pair of second tow members, The cable is wrapped around the second capstan. By varying the position of the second diagonally opposed pair of tow members with respect to the second link, the tension of at least one cable that can be imparted when the tow member is connected to the attachment feature with spherical center joint, . The first diagonally opposed pair of towing members is different from the second diagonally opposed pair of towing members, and the second capstan is different from the first capstan.
In another aspect, a surgical tool is provided. The surgical tool includes an elongated first link, a plurality of control cables, a second link, and a plurality of synaptic assemblies. The elongated first link has a distal end, a proximal end, and a first link axis defined therebetween. The first link has a shaft hole. A plurality of control cables extend distally from the control cable moving assembly disposed adjacent the proximal end of the first link in the aperture of the first link. The second link is pivotally connected to the distal end of the first link, thereby orienting the second link about the first axis and the second axis. The first and second axes are not parallel to the first link axis. The first axis is not parallel to the second axis. Each conjoined assembly connects one of the control cables to the second link such that axial movement of the control cable can angularly orient the second link relative to the first link about the first and second axes. One of the articulating assemblies includes an attachment lug having a curved portion of a certain length and an attachment lug hole sized to receive the curved portion slidably. The attachment lug rotates around a curved portion when the second link rotates about the first axis and slides along the curve portion when the second link rotates about the second axis.
In many embodiments, the plurality of control cables include four control cables. Each conjoint assembly may include an attachment lug having a curved portion of a length and an attachment lug hole sized to receive the curve portion slidably, whereby the attachment lug is configured such that the second link is rotated about a first axis It is possible to rotate about the curved portion, and when the second link rotates about the second axis, it can slide and move along the curved portion.
In another aspect, a method of manufacturing a surgical tool is provided. The method includes rotating the first link about a first axis oriented not parallel to the longitudinal direction of the first link and rotating about a second axis oriented not parallel to both the longitudinal direction of the first link and the first axis, Pivotally connecting the link to the first link, connecting the traction member to each of the four attachment features disposed on the second link, connecting each traction member to the first link by two- With the actuating mechanism operable to control the angular orientation of the second link relative to the second link. Each attachment feature branches from the first and second axes as viewed along the longitudinal direction of the first link. One of the attachment features is disposed in each quadrant defined by the first and second axes as viewed along the longitudinal direction of the first link. Wherein each traction member extends distally from within the aperture of the first link to one of the attachment features of the second link such that axial movement of the traction member causes the second link to be angled about the first link, can do. The connecting surface between the traction member and the attachment feature changes the position of the traction member relative to the second link relative to the angled orientation of the second link relative to the first link, thereby preventing a change in the tension of the traction member have.
The step of connecting the respective traction member and the actuation mechanism may include additional steps such as, for example, connecting the first traction member and the first control cable of the traction member. The second traction member of the traction member may be connected to the second control cable, in which case the second traction member is disposed diagonally opposite the first traction member. The first and second control cables may be connected to the first capstan of the actuating mechanism. The third traction member of the traction member may be connected to the third control cable. A fourth traction member of the traction member may be connected to the fourth control cable, wherein the fourth traction member is disposed diagonally opposite the third traction member. The third and fourth control cables may be connected to the second capstan of the actuating mechanism.
In another aspect, a surgical instrument is provided. The surgical instrument includes a first link, a second link including an attachment feature, a joint connecting the first link and the second link, and a traction member including an attachment lug. The attachment feature includes a curved portion. The joint rotates about a first axis defined in the first plane and about a second axis defined in the second plane. The first and second planes are parallel and branch from each other. The attachment lug is connected to the attachment feature. The attachment lug rotates about the curved portion when the traction member rotates the joint about the first axis. The attachment lug slides and moves along the curved portion as the movable member rotates the joint about the second axis.
In another aspect, a mechanism is provided for transmitting torque through an angle. The mechanism includes a connecting member including a first end, a second end and a connecting shaft defined therebetween, a connecting pin, a driving shaft having a driving shaft and a distal end, and a driven shaft having a proximal end and a driven shaft. The first end of the connecting member includes a receiving portion. The connecting pin extends across the receiving portion. The drive shaft end portion is accommodated in the accommodating portion. The distal end of the drive shaft includes a slot for receiving a connecting pin across the angular range between the connecting axis and the driving axis, whereby rotation of the driving shaft causes rotation of the connecting member through the connecting pin. The proximal end of the drive shaft is connected to the second end of the linking member, whereby rotation of the linking member about the linking axis causes rotation of the drive shaft about the driven axis. The drive shaft is connected to the driven shaft so that the angle between the drive shaft and the coupling axis and the corresponding angle between the driven shaft and coupling axis are maintained when the angle between the drive shaft and the driven shaft changes during rotation of the shaft .
The mechanism for transmitting torque through an angle may include one or more additional features, and / or may have one or more additional features. For example, the mechanism may further include a cross pin for connecting the drive shaft and the connection pin. The cross pin can be oriented across the connecting pin and mounted rotatably relative to the driving shaft. The outer surface of the drive shaft distal portion may include a spherical surface. The outer surface of the drive shaft can be in engagement with the receiving portion of the connecting member such that the drive shaft and receiving portion can be axially constrained relative to each other while spherically pivoting therebetween. The receiving portion may include a spherical surface that is connected to the driving shaft spherical surface. The distal end of the drive shaft may include a set of spherical gear teeth and the proximal end of the driven shaft may include a set of spherical gear teeth in engagement with the drive shaft gear teeth so that the angle between the drive shaft and the connecting shaft, The angle between the axis and the connecting axis is kept substantially equal. In many embodiments, at least one of the drive shaft, the drive shaft gear tooth, or the driven shaft and the driven shaft gear tooth is integrally formed. In many embodiments, the mechanism can be operated to deliver torque through angles in excess of 60 degrees.
In another aspect, a mechanism is provided for transmitting torque through an angle. The mechanism includes a drive shaft having a distal end and a drive shaft, a driven shaft having a proximal end and a driven shaft, and a connecting member connected to each of the drive shaft distal end and the driven shaft proximal end, The rotation causes rotation of the driven shaft around the driven shaft. At least one of the drive shaft distal end or the driven shaft proximal end includes a protrusion. The connecting member includes a tubular structure that defines a driving receiving portion and a driven receiving portion, and a connecting shaft is defined therebetween. At least one of the drive receiving portion and the driven receiving portion receives at least one protrusion and includes a slot configured to receive at least one protrusion through an angular range between the drive shaft and the driven shaft. The protrusion may interact with the slot to transmit rotational movement between the drive shaft and the driven shaft. The distal end of the drive shaft engages the proximal end of the driven shaft such that the angle between the drive shaft and the connecting axis when the angle between the driving axis and the driven axis changes during rotation of the shaft and the corresponding angle between the driven axis and the connecting axis do. In many embodiments, the mechanism can be operated to deliver torque through angles in excess of 60 degrees.
In many embodiments, the drive shaft and the driven shaft are in engagement with the connecting member, whereby the driving shaft and the driven shaft are constrained to the connecting member. For example, the distal end of the drive shaft and the proximal end of the driven shaft may each include an outer surface that is in engagement with the drive receiving portion and the driven receiving portion, respectively, such that an intersection defined between the shaft axis and the connecting axis And is axially fixed along the shaft axis and the connection axis. The outer surface of the drive shaft distal portion and the driven shaft proximal end may include a spherical surface. The drive receiving portion and the driven receiving portion may include spherical surfaces.
In many embodiments, the drive shaft distal end and the driven shaft proximal end include gear teeth that engage. For example, the drive shaft distal portion may include a drive shaft gear tooth surface extending around the drive shaft, and a proximal driven shaft end portion may include a driven shaft gear tooth surface extending around the driven shaft, The shaft gear tooth surfaces can be engaged with the driven shaft gear tooth surfaces so that the angles can be maintained correspondingly. In many embodiments, at least one of the drive shaft, the drive shaft gear tooth surface or the driven shaft and the driven shaft gear tooth surface to be driven is integrally formed. In many embodiments, the drive shaft gear tooth surface is defined by a drive shaft gear tooth contour extending radially from the drive shaft, and the driven shaft gear tooth surface is formed with a toothed shaft gear tooth contour extending radially from the driven shaft And the drive shaft gear tooth surface is engaged with the driven shaft gear tooth surface so that the drive / linkage angle and the driven / linkage angle can be maintained substantially equal. In many embodiments, the drive shaft gear tooth surface includes a revolving surface defined by rotating a drive shaft gear tooth contour about a drive shaft, and the driven shaft gear tooth surface includes a driven shaft gear tooth contour rotated about a driven axis And the like.
In another aspect, a minimally invasive surgical tool is provided. The surgical tool includes a mechanism shaft, a drive shaft having a distal end and a drive shaft, a driven shaft having a proximal end and a driven shaft, a drive shaft and a driven shaft, and a drive shaft and a driven shaft when the driven shaft is not parallel. A connecting member for substantially equalizing the rotational speed of the shaft, and an end actuator connected to the instrument shaft so that the orientation of the end effector can be changed in two dimensions with respect to the instrument shaft. The drive shaft is mounted for rotation within the tool shaft. The end effector includes an articulated feature connected to the driven shaft, whereby rotation of the driven shaft about the driven axis causes articulation of the feature.
In many embodiments, the drive shaft is rotatably connected to the coupling member on an axis, the driven shaft is rotatably connected to the coupling member on an axis, and the drive shaft is engaged with the driven shaft. For example, the connecting member may include a first end and a second end, a connecting shaft is defined therebetween, and the first end of the driving shaft is rotatably connected to the first end of the connecting member, Rotation of one drive shaft causes rotation of the linking member about the linking shaft. The proximal end of the driven shaft may be rotatably connected with the second end of the connecting member such that rotation of the connecting member about the connecting axis may cause rotation of the driven shaft about the driven axis. The distal end of the drive shaft can be engaged with the proximal end of the driven shaft such that the angle between the drive shaft and the connecting axis when the angle between the driving axis and the driven axis changes during rotation of the shaft and the angle between the driven axis and the connecting axis Can be correspondingly maintained. The drive shaft proximal portion may include spherical gear teeth and the driven shaft proximal portion may include spherical gear teeth engaging drive shaft gear teeth. In many embodiments, at least one of the drive shaft, the drive shaft gear tooth, or the driven shaft and the driven shaft gear tooth is integrally formed.
In many embodiments, the tool further comprises a connecting pin connecting the connecting member and the drive shaft, whereby the rotational movement between the drive shaft and the connecting member can be transmitted. For example, the tool may include a connecting member first end receiving portion, a connecting pin transverse to the receiving portion, an outer surface of the driving shaft distal portion in engagement with the receiving portion, And a drive shaft distal end slot formed in the drive shaft. Interaction between the connecting pin and the slot can connect the driving shaft and the connecting member, whereby rotation of the driving shaft causes rotation of the connecting member. The mechanism may further include a cross pin for connecting the drive shaft to the connection pin. The cross pin can be oriented across the connecting pin and mounted rotatably relative to the driving shaft.
In many embodiments, at least one of the drive shaft distal portion or the driven shaft proximal portion includes a protrusion. The connecting member may include a tubular structure that defines the driving receiving portion and the driven receiving portion along the connecting shaft, at least one of the driving receiving portion and the driven receiving portion receives the projection, and the angle between the driving shaft and the driven shaft Lt; RTI ID = 0.0 &gt; a &lt; / RTI &gt; slot. The protrusion may interact with the slot to transmit rotational movement between the connecting member and at least one of the drive shaft or the driven shaft.
For a more complete understanding of the nature and advantages of the present invention, reference should be made to the following detailed description and accompanying drawings. Other aspects, objects and advantages of the present invention will become apparent from the following drawings and detailed description.
4 is a simplified schematic diagram of a robotic surgical system, in accordance with many embodiments.
Figure 6 is a perspective view of a two-degree-of-freedom wrist connecting the end effector body and instrument shaft, in accordance with many embodiments.
Figure 7 is a perspective view of the two-degree-of-freedom wrist of Figure 6 illustrating the rotational freedom between the intermediate member of the wrist and the support member of the wrist and the rotational freedom between the intermediate member and the end actuator body, in accordance with many embodiments.
8A is a simplified schematic diagram of a support member cable guide surface and an intermediate member cable guide surface, in accordance with many embodiments.
8B is a simplified schematic diagram of an intermediate member cable guide surface, in accordance with many embodiments.
Fig. 9 is an end view of the support member of Figs. 6 and 7 illustrating an entry into an internal passageway for guiding a control cable, in accordance with many embodiments. Fig.
Figure 10 is a cross-sectional view of the two-degree-of-freedom wrist of Figures 6 and 7 illustrating the path of the movable system components adjacent the opposite sides of the two-degree-of-freedom wrist and the path of the control cables through the two- Perspective view.
11A is a side view illustrating an angled orientation limiting the close contact between the support member and the intermediate member of the two-degree-of-freedom wrist of Figs. 6 and 7, in accordance with many embodiments.
11B is a side view illustrating angled orientation limiting the close contact between the end effector body and the intermediate member of the two-degree-of-freedom wrist of Figs. 6 and 7, in accordance with many embodiments.
12 is a simplified schematic diagram of a surgical assembly, in accordance with many embodiments.
Figure 13A is a simplified schematic diagram of a surgical instrument in which a first link and a second link are connected through a two degree of freedom joint, according to many embodiments, the second link includes a curved segment attachment feature coupled with a linked traction member , And the viewing direction is parallel to the second axis of the 2 DOF joint.
Figure 13b schematically illustrates an attachment feature having a curved portion with a fixed center of curvature for a conventional centerline, in accordance with many embodiments.
Figure 13C shows section AA of Figure 13B.
13D is a simplified schematic diagram of the surgical instrument of FIG. 13A, showing a second link rotated about a second axis, in accordance with many embodiments.
Figure 13e is a simplified schematic diagram of the surgical instrument of Figures 13a and 13d, in accordance with many embodiments, wherein the viewing direction is parallel to the first axis of the two degrees of freedom joint.
Figure 13f is a simplified schematic diagram of the surgical tool of Figures 13a, 13d, and 13e, showing a second link rotated about a first axis, in accordance with many embodiments.
FIG. 13G is a perspective view of a surgical tool having a second link connected to a first link through a two degree of freedom joint, according to many embodiments, and the second link includes a curved portion attachment feature coupled with a linked pulling member.
13H is a side view of the surgical instrument of FIG. 13G, showing a 60 degree orientation of the second link about a first axis of two degrees of freedom joint, in accordance with many embodiments.
Figure 13i is a side view of the surgical instrument of Figures 13g and 13h, illustrating the 30 degree orientation of the second link about a second axis of the two degrees of freedom joint, in accordance with many embodiments.
14A is a simplified schematic diagram of a surgical tool having a second link coupled to a first link through a two degree of freedom joint, in accordance with many embodiments, Lug, and the viewing direction is parallel to the second axis of the 2 DOF joint.
14B is a simplified schematic diagram of the surgical instrument of FIG. 14A, showing a second link rotated about a second axis, in accordance with many embodiments.
14C is a simplified schematic diagram of the surgical instrument of FIGS. 14A and 14B, in accordance with many embodiments, the viewing direction being parallel to the first axis of the 2 DOF joint.
14D is a simplified schematic diagram of the surgical instrument of Figs. 14A, 14B and 14C, showing a second link rotated about a first axis, in accordance with many embodiments.
14E is a perspective view of a surgical tool having a second link connected to a first link through a two degree of freedom joint, according to many embodiments, and the second link includes an attachment lug associated with a linked pulling member having a curved portion end do.
15 is a simplified flow diagram of a method for manufacturing a surgical tool, according to many embodiments.
16 is a simplified schematic diagram of a surgical assembly, in accordance with many embodiments.
17 is a simplified schematic diagram of a tool assembly with a mechanism for transmitting torque through an angle, in accordance with many embodiments.
18 is a side view of a mechanism for transmitting torque through an angle in a configuration in which a drive shaft and a driven shaft are in line, according to many embodiments.
19A is a cross-sectional view of the mechanism of FIG. 18 illustrating engagement between the drive shaft and the engaged spherical gear tooth of the driven shaft in a row configuration, in accordance with many embodiments.
Figure 19b is a cross-sectional view of the mechanism of Figures 18 and 19a illustrating the engagement between the drive shaft and the engaged spherical gear tooth of the driven shaft in angled configuration, in accordance with many embodiments.
Figure 19c illustrates a different shaft angle constraining configuration, in accordance with many embodiments.
19D is a cross-sectional view of the mechanism of Figs. 18, 19A and 19B illustrating a configuration of a pin receiving transverse slot in a drive shaft and a driven shaft, according to many embodiments.
Fig. 20 is a view showing a perspective view of the drive shaft and the driven shaft of Figs. 18, 19a, 19b and 19d.
21A is a side view of the mechanism of Figs. 18, 19A, 19B, and 19C viewed in a direction normal to the connecting pin, in accordance with many embodiments.
Figure 21B is a side view of the mechanism of Figures 18, 19a, 19b, 19c and 21a viewed in a direction parallel to the connecting pin, in accordance with many embodiments.
Figure 22A is a perspective view of a drive shaft and a driven shaft with rows of spherical gear teeth configured to provide shaft angular constraint, in accordance with many embodiments.
22B is a cross-sectional / perspective view of the drive shaft and driven shaft of FIG. 22A illustrating a gear tooth cross-section and a spherical arrangement of gear teeth.
Figure 23A is a side view of a mechanism for delivering torque through an angle with a double cross pin design, in accordance with many embodiments.
23B is a side view of the mechanism of FIG. 23A without a connecting member.
23C is a cross-sectional view of the mechanism of Figs. 23A and 23B.
23D is a perspective view of the drive shaft and the driven shaft of Figs. 23A, 23B and 23C showing a cross pin receiving hole in the drive shaft and the driven shaft, respectively.
23E is a perspective view of the drive shaft and driven shaft of Figs. 23A, 23B, 23C and 23D illustrating the configuration of a pin receiving transverse slot in the drive shaft and the driven shaft, respectively.
24A is a simplified schematic diagram of a mechanism for transmitting torque through an angle, in accordance with many embodiments, wherein a protrusion interacting with a slot is provided between the drive shaft and the linking member for rotational movement and between the linking member and the driven shaft And transmits the rotation operation.
24B is a view of the mechanism of Fig. 24A viewed in a direction parallel to the protrusion, in accordance with many embodiments.
24C is a view of the mechanism of Figs. 24A and 24B viewed from the direction normal to the projection, illustrating in detail the two-piece connecting member in accordance with many embodiments.
Figure 24d illustrates the mechanism of Figures 24a, 24b and 24c in angled configuration, in accordance with many embodiments.
25A and 25B are simplified schematic diagrams of a mechanism for transmitting torque through an angle, according to many embodiments, wherein the modified U-joint connecting member comprises a rotational movement between the drive shaft and the connecting member, And transmits the rotation operation between the shafts.
Figure 26 illustrates a compact wrist design with a wrist according to many embodiments having a two degree of freedom wrist articulated by a linked traction member and a dual universal joint that transmits torque through an angle across the wrist .
In the following description, various embodiments of the present invention are described. For purposes of explanation, specific configurations and details are set forth, which may provide a thorough understanding of embodiments. It will be apparent, however, to one skilled in the art that the present invention may be practiced without the specific details. In addition, well-known features may be omitted or simplified in order to clarify the embodiments described.
A surgical tool having a two degree of freedom wrist mechanism, and related methods are provided. In many embodiments, the two-degree-of-freedom wrist includes an elongate intermediate wrist member pivotally connected to both the distal end of the instrument shaft and the end effector body. The intermediate member can be pivotally connected to the instrument shaft, thereby rotating about a first axis transverse to the longitudinal direction of the instrument shaft. The end effector body can be pivotally connected to the intermediate member, thereby rotating about a second axis transverse to the first axis. Dimensionally re-orienting the end effector body relative to the instrument shaft by pivoting the end effector body about the intermediate body about the second axis while pivoting the intermediate member about the instrument shaft about the first axis. The ability to reorient the end effector body in two dimensions can be used to mimic the natural motion of the physician wrist, thereby providing the end effector body with the desired level of maneuverability.
In many embodiments, it is beneficial to incorporate a two degree of freedom wrist into the minimally invasive surgical instrument. For example, the intermediate wrist member may have a length approximately equal to the diameter of the instrument shaft and a width considerably less than this length, for example the width is less than one-third of the length, In some cases it is less than 1/4 of the length. In many embodiments, a centrally located pivotal shaft is used, which provides rotation of the intermediate member relative to the shaft or end actuator about an axis oriented transversely to the longitudinal direction of the intermediate body, and two coaxial, When the shaft is used, rotation of the intermediate member relative to the shaft or end actuator body is provided about an axis oriented parallel to the longitudinal direction of the intermediate body. The operation of the dimensions and results of the intermediate member leaves an adjacent region open to connect the end effector articulating and moving components. Advantageously, the articulating components may be spaced apart from and connected to the first and second shafts in the cross-section of the minimally invasive tool, thereby enabling the use of an axial articulating component, for example a tension articulating component do. Typical embodiments may use both a rotating drive shaft and a cable that are branched from the intermediate wrist member, wherein the outer diameter of the tool (including the articulating component, end effector, and wrist joint system) is preferably less than one inch, It is typically less than about 1/2 inch. The intermediate wrist member may include a connection preparation portion having a guide feature for connecting one or more control cables through the intermediate wrist member. The wrist may be configured to transmit a roll axis torque (e.g., 0.33 Nm) across the wrist. The wrist may be configured with a hard spot that limits the range of motion of the device to prevent damage to other components due to angled excess movement. The wrist can have a compact length, and the pitch axis to yaw axis distance can be adjusted down to a zero branch.
In many embodiments, the two-degree-of-freedom wrist includes an internal passageway that guides the control cable. The internal passageway may be configured to suppress changes in the control cable tension while pivoting about the first and second axes.
There is also provided an improved surgical and / or robotic wrist structure that utilizes wrist articulation by a linked traction member. In many embodiments, a linked traction member may be used to articulate a second link coupled to the first link through a two degree of freedom joint. The linked traction member may be connected to the second link via an attachment feature disposed on the second link. The geometry of the two-degree-of-freedom joint, the linked traction member, and the attachment feature is selected such that the opposite axial movement of the traction member angularly aligns the second link with respect to the first link such that the tension change of the traction member can be suppressed . In many embodiments, the diagonally opposite tow members are paired and actuated by the actuation mechanism. For example, the diagonally opposite tow members may be connected to at least one control cable, and at least one control cable may be operated by the motor-driven capstan.
The disclosed wrist articulation through the linked traction member can be advantageously used in a surgical tool having a second link connected to the elongate first link through a two degree of freedom joint. The disclosed wrist articulation can be particularly beneficial when used in minimally invasive surgical instruments. A minimally invasive surgical instrument with reliable and smooth operating characteristics is desirable. By suppressing the change in tension in the linked traction member, detrimental control cable slack and / or overstress of the tool components can be avoided. The operation of the linear traction mechanism, for example the linked traction member via the motor-driven capstan, can provide smooth operating characteristics. In addition, the disclosed wrist articulation can reduce the length of the surgical instrument on the circle of the first link to improve accessibility to limited body space, angle of approach to the body structure, and visibility of the body structure. The disclosed wrist articulation is possible without additional interference due to additional mechanisms passing through the wrist, for example a drive shaft. In addition, the disclosed wrist articulation can provide increased life span by not using a wired linear cable. The disclosed wrist articulation can also be used to provide a wrist articulation angle of 60 degrees. In addition, the disclosed wrist articulation can use small diameter (e.g., subcutaneous) tubing, which is beneficial because it can be easily attached to a flexible cable driven by a motorized capstan.
In many embodiments, a minimally invasive surgical tool with wrist articulation through a linked traction member may include a second link pivotally mounted to the first link through a two degree of freedom joint. The joint may have a first rotational axis transverse to the first link and a second rotational axis transverse to the first rotational axis. The second link is connected to the four linked pulling members, whereby the second link can be articulated relative to the first link. The four traction members can be spaced from the two axes of the two degrees of freedom joint by placing the traction members one by one in each quadrant defined by the two axes in the cross section of the minimally invasive tool. In an exemplary embodiment, the outer diameter of the tool (including the linked traction member, control cable, and other end-effector actuator components such as drive shaft, end effector, and wrist joint system) is preferably less than 1 inch, / Less than 2 inches.
There is also provided a minimally invasive surgical instrument comprising a mechanism for transmitting torque through an angle, a mechanism for transmitting torque through an angle, and an associated method. This mechanism has a relatively simple design, which can increase the reliability of the mechanism by reducing the number of possible points of failure. For example, in many embodiments, the mechanism for transferring torque through an angle may have a reduced number of components compared to conventional mechanisms.
The disclosed mechanism can provide a smooth transfer of torque through a range of angles. In many embodiments, the mechanism for transmitting torque through an angle can be operated to deliver torque through an angle exceeding 60 degrees. In many embodiments, the rotational speed of the output shaft (e.g., the driven shaft) is substantially equal to the rotational speed of the input shaft (e.g., the drive shaft), and even when the input shaft and output shaft are not parallel However, this can provide a smooth transfer of torque through the angles by avoiding the occurrence of vibratory forces associated with unequal rotational speeds. The outer diameter of the mechanism (including the shaft, end effector and joint system) is preferably less than 1 inch, preferably less than 1/2 inch, and ideally less than or equal to 8 mm (or in some cases less than 5 mm). To enable multiple shaft drive systems to be mounted in a single wrist, the drive shafts, driven shafts, and the linkages of the mechanisms described herein are preferably mounted within a diameter of 5 mm or less, ideally 3 mm or less in diameter do. The torque transmitted across the joint is usually greater than 0.2 Nm, ideally greater than 0.3 Nm. To perform the desired operation by the end actuator within a desired amount of time, the shaft and joint system typically rotate at a speed of at least 100 rpm, ideally at least a few thousand rpm. The joint preferably has an operating life of at least several minutes, ideally at least several hours when driven at maximum torque and wrist angles. A typical drive shaft-driven shaft articulation assembly includes no more than 10 individual manufactured and / or operated components except for the shaft itself, and in many embodiments includes only three individually manufactured and / or operated components do.
The components of the disclosed mechanism can be made using available materials. In many embodiments, the drive shaft, driven shaft, and connecting device may be fabricated, for example, with 465 stainless steel, condition H950. The drive shaft and the driven shaft end may be integrated into the shaft. The cross pin can be made of, for example, Nitronic 60 stainless steel, 30 percent cold working.
The disclosed mechanism may be particularly beneficial when used as part of a minimally invasive surgical tool. As discussed above, a minimally invasive surgical tool is typically introduced into a patient through a cannula sleeve that limits the diameter of the tool. The relatively simple design of the disclosed mechanism may have a size that can be used within a minimally invasive surgical tool. Also, a relatively simple design can reduce possible points of failure, and this reduction can increase the reliability of the minimally invasive surgical tool. The ability to configure the disclosed mechanism to deliver torque through angles in excess of 60 degrees allows a relatively large degree of articulation to be used between the end effector of the minimally invasive surgical tool and the instrument shaft. Further, the disclosed mechanism of smoothly transferring torque through an angle through the use of the same rotational speed can be beneficial by avoiding the risk to patients and / or surgical instruments that may be caused by the generation of vibratory movements and / or forces have.
BRIEF DESCRIPTION OF THE DRAWINGS In connection with the drawings, in which like reference numerals refer to like parts throughout the several views, FIGS. 1-5B illustrate aspects of a minimally invasive robotic surgery system, and FIGS. FIGS. 13A-16 illustrate aspects of wrist articulation by a linked traction member, and FIGS. 17-25B illustrate aspects of a mechanism that transmits torque through an angle. As will be apparent, the features described above may be used individually or in any combination. For example, Figures 10, 13g, 13h, 13i, and 26 illustrate a compact wrist design with a two-degree-of-freedom wrist articulated by the linked traction members disclosed herein, Illustrate the use of dual universal joints capable of delivering torque.
Figure 1 is a top view illustrating a minimally invasive robotic surgery (MIRS) system 10, which is typically used to perform a minimally invasive diagnostic or surgical procedure on a patient 12 lying on a surgical table 14. The system may include a pseudo console 16 used by the physician 18 during the procedure. Also, one or more assistants 20 may participate in the procedure. The MIRS system 10 may further include a patient side cart 22 (surgical robot), and an electronic cart 24. [ The patient side cart 22 includes at least one detachably connected tool assembly 26 (hereinafter simply referred to as a "tool ") through the minimally invasive incision of the body of the patient 12 while the doctor 18 is viewing the surgical site through the console 16. [ ") Can be operated. An image of the surgical site can be obtained by the endoscope 28 such as a stereoscopic endoscope and the endoscope 28 can be oriented by operating the patient side cart 22. [ The electronic cart 24 can be used to process the image of the surgical site and display it to the doctor 18 through the pseudo console 16. [ The number of surgical instruments 26 used at one time will generally depend on diagnostic or surgical procedures and limiting factors in the operating room among various factors. The assistant 20 removes the tool 26 from the patient side cart 22 and dispenses it to another tool placed on the tray 30 of the operating room when it is necessary to replace one or more of the tools 26 used during the procedure (26).
2 is a perspective view of the pseudo console 16. Fig. The physician console 16 includes a left eye display 32 and a right eye display 34 for presenting to the physician 18 a coordinate stereoscopic view of the surgical site that enables in-depth viewing. The console 16 further includes one or more input control devices 36 whereby the patient cart 22 (shown in Figure 1) can operate one or more tools. The input control device 36 provides the same degree of freedom as the associated tool 26 (shown in Figure 1), thereby enabling the physician to recognize that the telepresence, or input control device 36 is integrated with the tool 26 So that the physician has a strong sense of direct control of the tool 26. [ To do this, the position, force, and tactile feedback sensor (not shown) may be used to communicate the position, force, and tactile sensation from the tool 26 back to the physician's hand through the input controller 36.
The physician console 16 is generally located in the same room as the patient so that the physician can directly monitor the procedure, physically exist if necessary, and speak directly to the assistant, not through a telephone or other communication medium . However, the physician may be in another room, in a completely different building, or in another remote location away from the patient (ie working outside the sterilization chamber) that allows for a remote surgical procedure.
3 is a perspective view of the electronic cart 24. Fig. The electronic cart 24 includes a processor that can be connected to the endoscope 28 and processes and displays the captured image, which may be provided to a physician, for example, at a physician's console, or at a location near and / Lt; RTI ID = 0.0 &gt; and / or &lt; / RTI &gt; For example, when a stereoscopic endoscope is used, the electronic cart 24 processes the captured image and presents a coordinate stereoscopic image of the surgical site to a doctor. Such coordinates may include alignment between opposing images and may include adjusting stereoscopic working distance of the stereoscopic endoscope. As another example, the image processing may include the use of predetermined camera calibration variables, thereby compensating for image errors of the image-capturing device, such as optical aberration.
FIG. 4 illustrates schematically a robotic surgery system 50 (such as the MIRS system 10 of FIG. 1). As discussed above, when a physician uses the physician console 52 (such as the pseudo console 16 of Fig. 1) and the patient side cart (surgical robot) 54 (the patient side cart 22 of Fig. 1) Can be controlled. The patient side cart 54 captures an image of the operation site using an imaging device such as a stereoscopic endoscope, and outputs the captured image to the electronic cart 56 (such as the electronic cart 24 of FIG. 1). As discussed above, the electronic cart 56 can process and display images captured in a variety of ways. For example, the electronic cart 56 may overlay the captured image with a virtual control interface and then display the combined image to the physician via the pseudo console 52. [ The patient side cart 54 outputs the captured image and processes it outside the electronic cart 56. For example, the patient side cart 54 may output the captured image to the processor 58, and may use the processor to process the captured image. In addition, the images can be processed by a combination of electronic cart 56 and processor 58, which can be connected together to process images captured simultaneously, sequentially and / or in combination. In addition, one or more separate displays 60 may be coupled to the processor 58 and / or the electronic cart 56 such that images of the treatment site, or images such as any other associated images, Can be displayed.
5A and 5B show the patient side cart 22 and the surgical tool 62, respectively. The surgical tool 62 is an example of the surgical tool 26. The illustrated patient side cart 22 provides three surgical tools 26 and an imaging device 28, for example, manipulation of a stereoscopic endoscope used to capture images of a treatment site. The manipulation is provided by a robot mechanism having a plurality of robot joints. The imaging device 28 and the surgical tool 26 can be positioned and manipulated through the incision of the patient so that the kinematic remote center is maintained in the incision so that the size of the incision can be minimized. The images of the surgical site may include images of the distal end of the surgical tool 26 when they are positioned within the field of view of the imaging device 28.
2 degrees of freedom wrist
6 is a perspective view of a two-degree-of-freedom wrist 70 connecting the end effector body 72 with a mechanism shaft 74 according to many embodiments. The wrist 70 includes a support member 76, a first hinge point 78, an intermediate member 80, a second hinge point 82, and a third hinge point 84. The support member 76 is fixedly mounted to the instrument shaft 74 through four attachment features 86 (e.g., mechanical features), and can be positioned within the aperture of the mechanism shaft 74 as illustrated thereby. have. The intermediate member 80 is pivotally connected to the support member 76 so as to be able to rotate about the first axis 88 through a first hinge point 78 located centrally. The end actuator body 72 includes an intermediate member 80 so as to rotate about a second axis 90 through a second hinge point 82 located on the outer periphery and a third hinge point 84 located on the outer periphery, Respectively. The second hinge point 82 and the third hinge point 84 are coaxial and aligned with the second axis 90. The second shaft 90 pivots with the intermediate member about the first axis 88.
The first axis 88 and the second axis 90 can be positioned to provide a compact two degree of freedom wrist with desirable kinematic and / or spatial characteristics. For example, the first axis 88 and the second axis 90 may be coplanar, thereby providing a compact wrist member with ball-joint type kinematics. In many embodiments, the first axis 88 and the second axis 90 are separated by a desired distance along the length of the instrument shaft 74. With this separation, the kinematics of the wrist mechanism can be approximated and / or matched to the kinematics of the moving system components used to orient the end actuator body 72 relative to the mechanism shaft 74 via the two-degree of freedom wrist . In many embodiments, the first axis 88 and the second axis 90 have a compactness that approximately corresponds to the kinematics of the moving system components used to orient the end actuator body 72 relative to the instrument shaft 74 Is separated by a desired distance along the length of the instrument shaft 74 so as to provide a two degree of freedom wrist with a desired combination of kinematics. For example, if a 4 mm separation between the first axis 88 and the second axis 90 is consistent with the kinematics of the moving system alignment component used, the two-degree-of-freedom wrist may have a smaller separation (e.g., 2 mm) So that a more compact wrist can be provided. In many embodiments, such separation distance compromise can be used without inducing any significant detrimental operating characteristics due to inconsistency with the kinematics of the moving system alignment component used. The first axis 88 and the second axis 90 can be positioned to provide a compact two degree of freedom wrist having the desired spatial characteristics. For example, the first axis 88 and the second axis 90 may be separate to provide additional space for the movable system components and associated attachment features.
The support member 76 provides a transition mount between the mechanism shaft 74 and the first hinge point 78. The support member 76 includes a rectangular main portion 92 and a cantilevered distal portion 100. The thickness of the rectangular main portion 92 is less than the inner diameter of the instrument shaft bore, which leaves two adjacent areas of the hole open to connect the articulating and / or moving components (not shown). The support-member main portion 92 includes two internal passageways 94, which can be used to guide an end actuator control cable within the mechanism shaft bore. The inner passageway 94 extends between the proximal end 96 of the main portion 92 and the distal end 98 of the main portion 92 and is generally aligned with the longitudinal direction of the mechanism shaft 74. As discussed further below, in many embodiments, the inner passageway 94 cooperates with the cable guide surface of the intermediate member to maintain a constant control cable path length, thereby providing a change in control cable tension during orbit around the first and second axes . The cantilevered distal portion 100 has attachment lugs for receiving a single pivot shaft of the first hinge point 78. The use of a single swivel shaft is merely exemplary, and other swivel joint component diagrams may be used in place of the first hinge point 78, for example two swivel pins aligned on the same axis may be used. The support member 76 is configured to receive the end actuator body 72 relative to the mechanism shaft 74 such that the first hinge point 78 is located at a desired location relative to the mechanism shaft 74 and the end actuator body 72. [ To provide an interval between the end actuator body 72 and the instrument shaft 74 that is required for reorientation of the desired range of motion.
The intermediate member 80 provides a transition mount between the first hinge point 78 and the second hinge point 82 and the third hinge point 84. The intermediate member 80 includes an elongated rectangular main portion whose thickness is less than the inner diameter of the instrument shaft bore (e. G., Similar to the thickness of the main portion 92) Leaving two adjacent regions open to connect the elements (not shown). The intermediate member 80 includes a central slot 102 configured to receive attachment lugs of the support-member distal portion 100. The central slot 102 is configured to receive the attachment lugs of the distal portion 100 throughout the rotational range of the intermediate member 80 about the first axis 88. In addition, the central slot 102 may be configured to receive an end actuator control cable (not shown) that extends through the support-member internal passageway 94. In addition, the central slot 102 may comprise a surface configured to guide the end actuator control cable. As discussed further below, in many embodiments, the mid-slot cable-guiding surface is configured to suppress changes in control cable tension while pivoting about the first and second axes by maintaining a substantially constant control cable path length . In many embodiments, the center-slot cable guide surface cooperates with the inner passage 94 to maintain a constant control cable path length while pivoting about the first and second axes. The central slot 102 also provides opposing attachment flanges that receive a single swivel shaft of the first hinge point 78. The second hinge point 82 includes a pivot shaft extending cantilevered from the first end of the intermediate member 80. The third hinge point 84 includes a turning shaft cantilevered from the opposite second end of the intermediate member 80. The use of a cantilevered swivel shaft is merely exemplary, and other suitable swivel joints may be used. The position and orientation of the second and third hinge points 82 and 84 (and hence the position and orientation of the second axis 90) is greater than that of the second axis 90 relative to the first axis 88 Lt; RTI ID = 0.0 &gt; and / or &lt; / RTI &gt; For example, in many embodiments, the first axis and the second axis are not coplanar. In many embodiments, the first axis and the second axis are coplanar. In many embodiments, the position and / or orientation of the second axis 90 relative to the first axis 88 is selected to provide the desired kinematics for the movement of the end actuator body 72 relative to the instrument shaft 74.
Figure 7 shows the degree of freedom of rotation between the intermediate member 80 and the support member 76 about the first axis 88 and the degree of freedom of rotation between the end actuator body 86 about the second axis 90 6 is a perspective view of the two-degree-of-freedom wrist 70 of FIG. 6 illustrating the degree of freedom of rotation between the intermediate member 80 (not shown) and the intermediate member 80; The support member 76 may be positioned such that the first hinge point 78 is located at a desired location in the circle from the distal end of the instrument shaft 74, for example by providing a gap between the end actuator body and the instrument shaft, And is mounted on the mechanism shaft 74 so as to provide a space for articulation. The intermediate member central slot 102 may be open at the side of the intermediate member 80 adjacent the end actuator body to accommodate an end actuator control cable (not shown). 7, only one internal passageway 94 of the support member 76 is visible, and the remaining internal passageway 94 is hidden in the figure. In many embodiments, a single control cable runs through each of the two internal passageways 94. These two control cables each extend through the middle-member central slot 102, one on each side of the first axis 88.
8A is a schematic cross-sectional view of the wrist 70 taken through a second axis 90 that is normal to the first axis 88 and illustrates exemplary support and intermediate member cable guide surfaces. The support member end portion 100 includes a first sheave surface 104 having a curved arc shape, and the center line of the curved arc shape is aligned with the first axis 88. The inner surface of the intermediate member slot 102 defines a second sheave surface 106 and a third sheave surface 108 having a curved arcuate shape and a center line of curved arcuate Centerline 112) are diverged from first axis 88 in parallel. The illustrated pulley surface has a constant curvature, but this is only an example, and other suitable surfaces may be used. The first sheave surface 104, the second sheave surface 106 and the third sheave surface 108 rotate about the first axis 88 (and thus the first axis 88) To provide a smooth cable-guiding surface that can guide the control cable for rotation of the central end actuator body. In many embodiments, the first sheave surface 104, the second sheave surface 106, and the third sheave surface 108 maintain a constant control cable path length so that the change in control cable tension during a revolution about the first axis . In many embodiments, the first sheave surface 104, the second sheave surface 106, and the third sheave surface 108 cooperate with the inner passageway 94 to provide a constant control cable path length Lt; / RTI &gt;
8B is a simplified schematic diagram of an additional intermediate-member cable-guiding surface according to many embodiments. Figure 8b illustrates section AA of Figure 8a. The inner surface of the intermediate-member slot 102 has a fourth sheave surface 114 and a fifth sheave surface 116 having a curved arc shape with a curved arc-shaped center line diverging in parallel from the second axis 90 (The fourth pulley center line 118 and the fifth pulley center line 120). The illustrated pulley surface has a constant curvature, but this is only an example, and other suitable surfaces may be used. The fourth sheave surface 114 and the fifth sheave surface 116 are connected to a smooth cable-guide (not shown) that can guide the control cable for rotation of the end actuator body about the intermediate body 80 about a second axis 90 Surface. In many embodiments, the fourth sheave surface 114 and the fifth sheave surface 116 maintain a substantially constant control cable path length thereby suppressing changes in the control cable tension while turning around the second axis. In many embodiments, fourth sheave surface 114 and fifth sheave surface 116 cooperate with inner passage 94 to maintain a constant control cable path length while pivoting about a second axis.
9 is a near-end view of the support member 76 of Figs. 6 and 7 illustrating an inlet to an internal passageway 94 for guiding a control cable of a movable system in accordance with many embodiments. The support member inner passage 94 can be used to constrain the cross-sectional position of the control cable at the distal end of the mechanism shaft.
10 shows an exemplary path of the movable system component along two sides of the two-degree of freedom wrist 70 and an exemplary path of the control cables 122 and 124 through the two-degree of freedom wrist 70 6 is a perspective view of the two-degree-of-freedom wrist 70 of Figs. 6, 7 and 8, shown. The general plan configuration of the two-degree-of-freedom wrist, and the central position of the wrist within the shaft that supports it, leave open adjacent areas to connect these moving system components. In the illustrated embodiment, these movable system components include a first drive shaft assembly 126 that extends over the wrist, a second drive shaft assembly 128 that extends below the wrist, an end effector articulation pull rod 130 , 132, 134, and 136), and control cables 122, 124 that extend through the wrist through the inner passageway and mid-member slot 102 of the support member discussed above.
The two degree of freedom wrist 70 is rotated about the center of the first axis 88 (through the first joint 78) and about the center of the second axis 90 (between the second joint 82 and the third joint 84 ) To provide angular orientation that limits all of the tight contact. This angled orientation, which restricts close contact, serves to prevent the wrist crossing component from being damaged due to angled excess movement. 11A shows a close contact between the intermediate member 80 of the two-degree-of-freedom wrist 70 and the support member 76 in a rotation about the first axis 88 (via the first joint 78) &Lt; / RTI &gt; A similar angular orientation is created which restricts the close contact between the intermediate member 80 and the support member 76 when the intermediate member 80 is rotated in the opposite direction about the first joint 78. [ 11B shows a side view of the intermediate member 80 of the two-degree of freedom wrist 70 and the end effector body 70 of the two degrees of freedom wrist 70 in the rotation about the second axis 90 (through the second joint 82 and the third joint 84) Lt; RTI ID = 0.0 &gt; 72 &lt; / RTI &gt; A similar angular orientation is created which limits the contact between the intermediate member 80 and the end actuator body 72 when the end actuator body 72 is rotated in the opposite direction about the second axis 90. [
12 is a simplified schematic diagram of a tool assembly 140 having a two degree of freedom wrist 70 according to many embodiments. The tool assembly 140 includes a proximal moveable assembly 142, a main shaft 144, an articulated end actuator base of the end effector 146, and a two degree of freedom wrist 70. In many embodiments, the proximal moveable assembly 142 may be operably connected to the end actuator base to selectively redirect the end actuator base relative to the main shaft 144 in two dimensions, And may articulate one or more end effector features relative to the end effector base. The movable assembly 142 and the end actuator 146 may be connected using various moving components, such as control cables, cable / hypotube combinations, drive shafts, pull rods, and push rods. In many embodiments, the movable component extends between the moveable assembly 142 and the end actuator 146 through a hole in the main shaft 144.
The tool assembly 140 may be configured for use in a variety of applications, for example as a manually and / or automatically powered handheld device used in the proximal motion mechanism 142. As such, the tool assembly 140 may be used beyond a minimally invasive robotic surgery and may include, for example, non-robotic minimally invasive surgery, non-minimally invasive robotic surgery, non-robotic non- minimally invasive surgery, It can also be used in other applications where the use of a freedom-of-freedom wrist is beneficial.
Wrist with linked traction member Articulation
13A is a simplified schematic diagram of a surgical tool 170 with wrist articulation by a linked traction member in accordance with many embodiments. The surgical tool 170 includes a second link 172 pivotally connected to the first link 174 through a two degree of freedom joint. The joint provides a rotational movement about a first axis 176 and a second axis 178 between the second link 172 and the first link 174. The first axis 176 is fixed with respect to the first link 174 and the second axis 178 is fixed with respect to the second link 172. Four attachment features 180, 182, 184 and 186 are disposed on the second link 172. [ Each attachment feature 180, 182, 184, 186 is connected to a pulling member 188, 190, 192, 194, respectively. The tow members 188, 190, 192 and 194 extend through the holes of the first link 174 and are connected to the actuating mechanism 196 via the control cables 198, 200, 202 and 204. In many embodiments, the traction members 188, 190, 192, 194 are configured to minimize stretching and reduce cost under operating loads (e.g., 17 inch length, 0.04 inch outer diameter, 0.02 inch inner diameter ; 15.2 inches long, 0.06-inch outer diameter, 0.02-inch inner diameter). In many embodiments, the attachment features 180, 182, 184, 186, the traction members 188, 190, 192, 194, the first axis 176, and the second axis 178, The axial movement is configured to angularly orient the second link 172 with respect to the first link 174 to suppress the change in tension in the traction member. In the illustrated embodiment, the actuation mechanism 196 includes a first motor drive capstan 206 and a second motor drive capstan 208. A first diagonally oriented pair of control cables (e.g., control cables 198, 202) surrounds the first motorized capstan 206 such that the first motorized capstan 206 rotates clockwise The control cable 198 is retracted and the control cable 198 is extended by the same amount and when the first motor drive capstan 206 rotates counterclockwise, the control cable 198 is retracted and the same amount The control cable 202 is extended. In addition, a second diagonally oriented pair of control cables (e.g., control cables 200, 204) surrounds the second motor driven capstator 208 such that the second motorized capstan 208 is rotated clockwise The control cable 204 is retracted and the control cable 204 is extended by the same amount as the control cable 200 is retracted. When the second motor drive capstan 208 rotates counterclockwise, the control cable 204 is retracted, The control cable 200 is extended by the amount.
Figures 13b and 13c illustrate schematically one of the attachment features 180, 182, 184, 186. The attachment features 180,182,184 and 186 are defined by a fixed curvature center 212 of the curved regular centerline 214 and a curved portion 216 having a first radius of curvature 216 centered on the curved regular centerline 214. [ (210). Each fixed center of curvature may be located in a two-dimensional plane containing a second axis 178. [ The curved normal centerline may be placed in a two-dimensional plane normal to the second axis 178. The four curved normal centerlines may be tangential to the two-dimensional plane containing the first axis 176. Each traction member 188, 190, 192, 194 has attachment lugs 218, 220, 222, 224 having an axis of hole orientation normal to the traction member length. The attachment lug holes are sized to accommodate the corresponding attachment feature curved portions slidably. The attachment lug is configured to rotate about and / or slide along the curved portion during the articulation of the second link 172 with respect to the first link 174.
As the second link 172 rotates about the second axis 178, the attachment lugs 218, 220, 222, and 224 move the corresponding curved portions of the attachment features 180, 182, 184, It slides along. 13D is a simplified schematic diagram of the surgical tool 170 of FIG. 13A, showing a second link 172 rotated about a second axis 178 in accordance with many embodiments. Each attachment lug 218, 220, 222, 224 slides along a corresponding attachment feature curved portion so that each traction member is aligned with the fixed curvature center of its corresponding attachment feature curved portion compartment do. As a result, the upper pull members 190, 194 extend by the same amount as the lower pull members 188, 192 are retracted (compared to the natural second link orientation depicted in FIG. 13A). Using this balanced extension / retraction of the traction member, more than one pair of traction members can be linked and actuated by a common actuation mechanism. For example, diagonally oriented traction members can be connected to at least one control cable, and at least one control cable can be actuated by a motor-driven capstan. The rotation of the motorized capstan (e.g., servo-controlled type) can be used to extend the control cable section connected to the first pair of traction members and retract the control cable section connected to the second pair of traction members have. This simultaneous and identical extension / retraction of the control cable can suppress the change in tension in the linked traction members, which can help avoid any detrimental control cable slack and / or overstress of the tool components have.
FIG. 13E illustrates the surgical tool 170 of FIGS. 13A and 13D viewed in a direction parallel to the first axis 176 of the two-DOF joint according to many embodiments. As discussed above, the attachment feature 180, 182, 184, 186 includes a curved subdivision with a regular centerline and a fixed center of curvature. Each regular centerline is tangent to a plane containing the first axis 176 of the two degrees of freedom joint. Each fixed center of curvature lies in a plane containing a second axis 178 of two degrees of freedom joint.
As the second link 172 rotates about the first axis 176, the attachment lugs 218, 220, 222, and 224 rotate about the corresponding attachment feature curved partial regular centerline. 13F is a simplified schematic diagram of the surgical tool 170 of FIGS. 13A, 13D, and 13E showing a second link 172 rotated about a first axis 176 in accordance with many embodiments. Each of the attachment lugs 218,220, 222,224 rotates about the corresponding curved portion normal centerline of the attachment feature 180,182,184,186 such that each pulling member is aligned with the corresponding centerline do. As a result, the upper pull members 188, 190 extend by the same amount as the lower pull members 192, 194 are retracted (compared to the natural second link orientation depicted in Figure 13e). As discussed above, using this balanced extension / retraction of the traction member, more than one pair of traction members can be linked and actuated by a common actuation mechanism. For example, a first pair of four traction members, including two diagonally oriented traction members 188, 194, may be actuated by a first motor drive capstan, and the remaining two traction members 190 , 192) can be actuated by the second motor drive capstan. The first and second motorized capstan can be used to articulate the second link 172 relative to the first link 174 within the orientation range provided by the two degrees of freedom joint.
13G is a partial perspective view of a surgical tool 230 having a second link 232 connected to a first link 234 via a two degree of freedom joint according to many embodiments. The illustrated two degree of freedom joint includes an intermediate member 236 pivotably connected to support member 238 so as to be rotatable about a first axis. The second link 232 is pivotally connected to the intermediate member 236 and is rotatable about the second axis with respect to the intermediate member 236. The second link 232 includes four attachment features 240, 242, 244 (246 is hidden in the figure), which include a curved portion section. Four traction elements 248, 250 and 252 (254 is hidden in the figure) are connected to the four attachment features 240, 242, 244 and 246.
The illustrated surgical tool 230 is configured similar to the surgical tool 170 illustrated in Figures 13A, 13D, 13E, and 13F and discussed above. Thus, the above discussion of the surgical tool 170 also applies to the surgical tool 230 illustrated in FIG. 13G, which further illustrates wrist articulation through the linked traction member. 13H is a side view of the surgical tool 230 of FIG. 13G, showing the 60 degree orientation of the second link 232 about the first axis of the two degrees of freedom joint according to many embodiments. From the aligned orientation illustrated in FIG. 13G to the orientation illustrated in FIG. 13H, the traction member attachment lug is pivoted about the normal centerline of the curved portion section of the attachment feature, thereby aligning the traction member with the normal centerline of the curved portion section / RTI &gt; FIG. 13I is a side view of the surgical tool 230 of FIG. 13G showing the 30 degree orientation of the second link about a second axis of the 2 DOF joint according to many embodiments. From the aligned orientation illustrated in Fig. 13G to the orientation illustrated in Fig. 13i, the traction member attachment lug slides along the curved segment section of the attachment feature, thereby aligning the traction member with the fixed curvature center of the curved segment segment / RTI &gt;
14A is a simplified schematic diagram of a surgical tool 260 with wrist articulation by a linked traction member in accordance with many embodiments. The surgical tool 260 includes a second link 262 pivotally connected to the first link 264 through a two degree of freedom joint. The joint provides rotational movement between the second link 262 and the first link 264 about the first axis 266 and the second axis 268. [ The first axis 266 is fixed with respect to the first link 264 and the second axis 268 is fixed with respect to the second link 262. Four attachment features 270, 272, 274, and 276 are disposed on the second link 262. Each attachment feature 270, 272, 274, 276 is connected to a pulling member 278, 280, 282, 284, respectively. The traction members 278,280, 282 and 284 extend through the apertures of the first link 264 to engage and disengage the movable mechanism (not shown, e. G., Actuating the remote control surgical instrument of the remote robot surgical system described above Associated operating mechanism). In many embodiments, the attachment features 270, 272, 274, 276, the traction members 278, 280, 282, 284, the first axis 266 and the second axis 268, So that the movement can orientate the second link 262 angularly with respect to the first link 264 to suppress the change in tension in the traction member.
Each attachment feature 270, 272, 274, 276 includes an attachment lug having a bore axis oriented parallel to the second axis 268. Each traction member 278,280, 282,284 may comprise a section of a curved section, the curved section section having a first radius of curvature about its regular centerline and a fixed curvature center &lt; RTI ID = 0.0 &gt; . The curvilinear centerline may lie in a normal-oriented two-dimensional plane with the first axis 266. Attachment feature The lug hole is sized to accommodate the traction member curve slip. The attachment feature lug is configured to be able to rotate about the traction member curve portion and / or to slide along the traction member curve portion during articulation of the second link 262 relative to the first link 264.
As the second link 262 rotates about the second axis 268, the curved portions of the pulling members each slidably move against the corresponding attachment feature lugs. 14B is a simplified schematic diagram of the surgical tool 260 of FIG. 14A, showing a second link 262 rotated about a first axis 266 in accordance with many embodiments. The curved portions of the traction member each slid against the corresponding attachment feature lugs. As a result, the upper pull members 280, 284 extend by the same amount as the lower pull members 278, 282 are retracted (compared to the natural second link orientation depicted in FIG. 14A). This provides a balanced extension / retraction of the traction member similar to the surgical tool 170 discussed above. Thus, additional aspects and advantages of this balanced extension / retraction of the traction member discussed above with respect to the surgical tool 170 also apply to the surgical tool 260 and are not repeated here.
Fig. 14C illustrates the surgical tool 260 of Figs. 14A and 14B viewed in a direction parallel to the second axis 268 of the 2 DOF joint according to many embodiments. As discussed above, each attachment feature 270, 272, 274, 276 includes an attachment lug with a bore axis oriented parallel to the second axis 268. [ Each traction member includes a curved portion segment having a regular centerline and a fixed center of curvature.
As the second link 262 rotates about the second axis 268, the trailing member curve portion pivots within the attachment feature lug. 14D is a simplified schematic diagram of the surgical tool 260 of FIGS. 14A, 14B and 14C showing a second link 262 rotated about a second axis 268 in accordance with many embodiments. Each traction member curve portion pivots within the corresponding attachment feature lug bore, such that each traction member remains aligned with the corresponding attachment feature lug bore. As a result, the upper pull members 278, 280 extend by the same amount as the lower pull members 282, 284 are retracted (compared to the natural second link orientation depicted in FIG. 14C). As discussed above, using this balanced extension / retraction of the traction member, more than one pair of traction members can be linked and actuated by a common actuation mechanism. Thus, additional aspects and advantages of this balanced extension / retraction of the traction member discussed above with respect to the surgical tool 170 also apply to the surgical tool 260 and are not repeated here.
14E is a partial perspective view of a surgical tool 290 having a second link 292 connected to a first link (not shown) through a two degree of freedom joint according to many embodiments. The illustrated two degree of freedom joint includes an intermediate member 294 pivotably connected to the support member 296 so as to be rotatable about a first axis. The second link 292 is pivotally connected and can rotate about the second axis with respect to the intermediate member 294. The second link 292 includes four attachment features 298, 300, 302 (304 is hidden in the figure), which each include attachment lugs. Four towing members 306, 308, 310 and 312 are connected to the four attachment features 298, 300, 302 and 304. The four traction elements 306, 308, 310, 312 each comprise a curved segment compartment that is received slidably by corresponding attachment feature lugs. The illustrated surgical tool 290 is configured similar to the surgical tool 260 illustrated in Figures 14A, 14B, 14C, and 14D and discussed above. Thus, the above discussion of the surgical tool 260 also applies to the surgical tool 290 illustrated in FIG. 14e, which further illustrates wrist articulation through the linked traction member.
15 is a simplified flow diagram of a method 320 for fabricating a surgical tool in accordance with many embodiments. In step 322, the second link is coupled to the first link and rotates about the first and second axes. For example, a second degree of freedom joint mechanism may be used to connect the second link and the first link. The 2 DOF joint may include an intermediate member pivotally connected to the second link so as to be rotatable about the first link about the first axis. The second link is pivotally connected to the intermediate member and is rotatable about the intermediate member about a second axis. The first link may have a distal end, a proximal end, and a first link axis defined therebetween. The first link may have a shaft hole. The first and second axes may not be parallel to the first link axis. The first axis may not be parallel to the second axis. The second link may include four attachment features. Each attachment feature may branch from the first and second axes as viewed along the first link axis. One of the attachment features may be disposed in each quadrant defined by the first and second axes as viewed along the first link axis.
At step 324, a traction member is connected to each second link attachment feature. Each traction member may extend distally from within the bore of the first link to one of the attachment features of the second link such that the axial movement of the traction member angles the second link about the first link about the axis . The tangent between the traction member and the attachment feature can inhibit a change in the tension of the traction member by changing the position of the traction member relative to the second link relative to the angular orientation of the second link relative to the first link.
At step 326, each traction member is connected to the actuating mechanism, and the actuating mechanism can be actuated to control the angular orientation of the second link with respect to the first link in two dimensions by actuating the traction member. For example, the first of the four traction members may be coupled to the first control cable, and the second of the traction members may be coupled to the second control cable. The first and second traction members may be diagonally oriented traction members. The first and second control cables may be connected to the first capstan of the actuating mechanism. The third of the four traction members can be connected to the third control cable, and the fourth of the traction members can be connected to the fourth control cable. The third and fourth traction members may be diagonally oriented traction members. The third and fourth control cables may be connected to the second capstan of the actuating mechanism.
16 is a simplified schematic diagram of a tool assembly 330 with a wrist articulated by a linked traction member in accordance with many embodiments. The tool assembly 330 includes a proximal moveable assembly 332, a main shaft 334, an articulated end effector base of the end effector 336, and a two degree of freedom wrist 338. In many embodiments, the proximal moveable assembly 332 is operatively connected to the end effector base such that it is bi-dimensionally coupled to the main shaft 334 via the traction member linked as described above with respect to the surgical tools 170, And can be articulated to one or more end actuator features relative to the end actuator base by being operatively connected to the end actuator 336. The end effector &lt; RTI ID = 0.0 &gt; 336 &lt; / RTI &gt; The movable assembly 332 and the end actuator 336 may be connected using various moving components, such as a control cable, a drive shaft, and an end actuator base attachment feature corresponding to the linked pull member described above. In many embodiments, the movable components extend between the moveable assembly 332 and the end effector 336 through an aperture in the main shaft 334.
The tool assembly 330 may be configured as a handheld and / or an automatically powered handheld device for use in, for example, the proximal motion mechanism 332, for use in a variety of applications. As such, the tool assembly 330 may be used beyond a minimally invasive robotic surgery and may be used in various applications such as non-robotic minimally invasive surgery, non-minimally invasive robotic surgery, non-robotic non- minimally invasive surgery, May also be used in other applications where the use of a two-degree-of-freedom wrist that is articulated by a traction member is beneficial.
Mechanism to transmit torque through angle
17 is a simplified schematic diagram of a tool assembly 370 having a mechanism 372 for transmitting torque through an angle in accordance with many embodiments. The tool assembly 370 includes a proximal torque source 374, a main shaft 376, an articulated end actuator base of the end effector 378, and a torque transfer mechanism 372. The torque transfer mechanism 372 includes a drive shaft 380, a driven shaft 382 and a connecting member 384 connected to both the drive shaft 380 and the driven shaft 382, The driven shaft 382 rotates correspondingly. In many embodiments, the drive shaft 380 is mounted for rotation relative to the main shaft 376 and extends through the hole (centerline or bifurcation) of the main shaft 376. In many embodiments, the torque transfer mechanism 372 is configured such that the rotational speed of the driven shaft 382 substantially coincides with the rotational speed of the drive shaft 380 in any relative angular orientation between the shafts. In operation, a proximal torque source 374 rotates drive shaft 380, which rotates connecting member 384, which rotates driven shaft 382, thereby rotating main shaft 376 and end actuator 378, respectively. In many embodiments, the driven shaft 382 actuates the shaft drive mechanism of the end actuator 378. For example, the end effector shaft drive mechanism can articulate the clamping forceps to the articulated end effector base and / or actuate a surgical device (e.g., a stapler device, a cutter device, a cauterization device) . These shaft drive mechanisms are exemplary only. The driven shaft may also be used to actuate other suitable shaft drive mechanisms. In addition, the tool assembly 370 is shown with one torque transfer mechanism 372, but this is also only an example. One or more torque transfer mechanisms 372 may be used, for example, to transmit torque from the proximal torque source 374 to the corresponding one or more end effector mechanisms.
The tool assembly 370 may be configured as a handheld and / or an automatically powered handheld device for use in, for example, a proximal torque source 374, for use in a variety of applications. As such, the tool assembly 370 may have applications beyond a minimally invasive robotic surgery and may be used in various applications such as non-robotic minimally invasive surgery, non-minimally invasive robotic surgery, non-robotic non- minimally invasive surgery, Lt; / RTI &gt; may be used in other applications where the use of the disclosed mechanism of delivering torque through the &lt; RTI ID = 0.0 &gt;
Figure 18 is a side view of a mechanism 390 for transferring torque through an angle in accordance with many embodiments. The torque transfer mechanism 390 includes a drive shaft 392, a connecting member 394, a driven shaft 396, a first connecting pin 398, and a second connecting pin 400. FIG. 18 illustrates a torque transfer mechanism 390 in a linear configuration.
The drive shaft 392 is rotatably connected to the connecting member 394 on the shaft. The drive shaft 392 has a distal end portion 402 that is received in the first receiving portion 404 of the connecting member 394. The drive shaft distal portion 402 includes a transverse slot 406. The first connecting pin 398 engages with the connecting member 394 and crosses the first receiving portion 404. The first connection pin 398 is received in the drive shaft transverse slot 406. The driving shaft distal end portion 402 and the connecting member first receiving portion 404 may have a concave coupling surface (s), for example, spherical (s). The interaction between the first connection pin 398 and the drive shaft transverse slot 404 rotatably connects the drive shaft 392 and the linking member 394 on an axis. In addition, the interaction between the drive shaft distal portion 402 and the connecting surfaces of the connecting member first receiving portion 404 can further constrain the driving shaft 392 relative to the connecting member 394. [
Similarly, the driven shaft 396 is rotatably connected to the connecting member 394 on the shaft. The driven shaft 396 has a proximal end portion 408 received in the second receiving portion 410 of the connecting member 394. [ The driven shaft proximal end 408 includes a transverse slot 412. The second connecting pin 400 is engaged with the connecting member 394 and crosses the second receiving portion 410. The second connecting pin 400 is received in the driven shaft transverse slot 412. The driven shaft proximal end portion 408 and the connecting member second receiving portion 410 may have a concave shaped coupling surface (s), e.g., spherical (s). The interaction between the second connecting pin 400 and the driven shaft transverse slot 412 rotatably connects the driven shaft 396 and the connecting member 394 on an axis. In addition, the interaction between the driven shaft proximal end 408 and the connecting surfaces of the connecting member second receiving portion 410 can further constrain the driven shaft 396 relative to the connecting member 394. [
19A illustrates the torque transfer mechanism of Fig. 18 (Fig. 19B) illustrating the engagement between the spherical gear teeth 414 of the drive shaft 392 and the engaged spherical gear teeth 416 of the driven shaft 396 390). Gear teeth are referred to as "spherical" because they generally take the form of a geometrically small circle on the surface of a sphere. The illustrated cross-section includes the center line of the drive shaft 392, the driven shaft 396 and the connecting member 394, respectively, which are parallel to the first connecting pin 398 and the second connecting pin 400 As shown in Fig. In the illustrated tiered configuration, the linking member 394, drive shaft 392, and driven shaft 396 are aligned. The connecting member 394 rotates about the connecting member shaft 418. [ The connecting member shaft 418 is a longitudinal center line between the two receiving portions 404, 410. The drive shaft 392 rotates about the drive shaft 420. The driven shaft 396 rotates about the driven shaft 422. The drive shaft 392 is constrained to pivot about the first connection pin 398 (and thus constrained to pivot relative to the coupling member 394). Similarly, the driven shaft 396 is constrained to pivot about the second connection pin 400 (and thus constrained to pivot relative to the coupling member 394). The further constraint between the drive shaft 392 and the driven shaft 396 provided by the engagement between the drive shaft gear teeth 414 and the driven shaft gear teeth 416 causes the drive shaft 392 and the coupling member 394 with the relative angular orientation between the driven shaft 396 and the connecting member 394.
19A illustrates a spherical outer surface of the driving shaft that is connected to the inner spherical surface 426 of the connecting member first receiving portion 404. Similarly, the driven shaft outer spherical surface 428 is connected to the inner spherical surface 430 of the connecting member second receiving portion 410. As described above, the constraint provided by the first coupling pin 398 rotatably couples the drive shaft 392 and the coupling member 394 on the shaft, and the constraint provided by the second coupling pin 400, The shaft 396 and the connecting member 394 are rotatably connected on the shaft. Additionally, the constraint provided by the adjoining spherical surface may further constrain the drive shaft 392 and driven shaft 396 relative to the linking member 394.
19B is a cross-sectional view of the torque transfer mechanism 390 of Figs. 18 and 19A illustrating the engagement between drive shaft gear teeth 414 and driven shaft gear teeth 416 in an angled configuration according to many embodiments . The illustrated cross-sectional view includes a drive shaft 420, a driven shaft 422, and a connecting member shaft 418, which are viewed in a direction parallel to the first connecting pin 398 and the second connecting pin 400 .
In the illustrated angled configuration, driven shaft 422 deviates from drive shaft 420 by 70 degrees. The constraint provided by the engagement between the drive shaft gear teeth 414 and the driven shaft gear teeth 416 results in an offset of 70 degrees which is offset by 35 degrees between drive shaft 420 and connection shaft 418, And a deviation of 35 degrees between the connection shaft 418 and the driven shaft 422. [ By restricting the connecting member to be oriented at an equivalent relative angle to both the driving shaft and the driven shaft, any rotational speed difference between the driving shaft and the connecting member is effectively canceled when the rotation of the connecting member is transmitted to the driven shaft, Whereby any rotational speed difference between the drive shaft and the driven shaft is substantially eliminated.
The drive shaft gear teeth 414 and the driven shaft gear teeth 416 are spherically oriented so that any of the angular orientations of the torque transfer mechanism 390 can be used to drive the drive shaft 392 and the driven shaft 396, Restraint can be provided. The rotation of the drive shaft 392 and the corresponding rotation of the driven shaft 396 are such that different portions of the drive shaft distal portion 402 and the driven shaft proximal portion 408 are connected by a connecting shaft 418 Intersect. The use of spherical gear teeth continues to provide the angular constraints needed to orient the connecting member relative to the drive shaft while allowing such movement of the shafts.
Other suitable shaft angle constraining configurations may also be used. For example, as illustrated in FIG. 19C, a drive shaft feature (e.g., a feature comprising a cantilevered sphere from the drive shaft distal end) may include a driven shaft feature (e.g., And a cylindrical hole 434 that receives a cantilevered drive shaft feature including a spherical surface extending cantilevered from the proximal end). The use of any shaft angular constraint may cause some level of variation between the relative angle between the drive shaft 420 and the connection shaft 418 and the relative angle between the connection shaft 418 and the driven shaft 422, The rotational speed fluctuation of the result between the driven shaft 392 and the driven shaft 396 can be allowed in some applications.
Other spherical gear tooth contours may also be used to provide suitable shaft angle constraints. For example, the drive shaft distal portion 402 may include a gear tooth surface extending around the drive shaft 420, and the driven shaft proximal portion 408 may include a complementary gear tooth extending around the driven shaft 422, Surface so that the drive shaft gear tooth surface engages the driven shaft gear tooth surface to provide shaft angle constraint. The driven shaft gear tooth surface may be defined by a drive shaft gear tooth profile radially extending from the drive shaft 420 and the driven shaft gear tooth surface may be defined by a driven shaft gear tooth profile radially extending from the driven shaft 422 Thereby providing a shaft angle constraint in which the drive / linkage angle and the driven / linkage angle are maintained substantially equal. The drive shaft gear tooth surface may include a limited outer surface by rotating the drive shaft gear tooth contour about the drive shaft 420 and the driven shaft gear tooth surface may include a driven shaft gear tooth contour on the driven shaft 422, Lt; RTI ID = 0.0 &gt; a &lt; / RTI &gt; For example, in FIG. 19C, the cantilevered spherical surface 432 has a circumferential surface defined by rotating a gear tooth contour radially extending from the drive shaft (its circular cross-section) and its gear tooth contour about a drive shaft 420 . The cylindrical bore surface 434 includes an exoskeletal surface defined by rotating a complementary gear tooth surface radially extending from its driven shaft 422 (its straight cross section) and its gear tooth contour about the driven axis 422 do. Other gear tooth contours may also be constructed in a similar manner, for example the gear tooth contour may have an intermediate shape of the gear tooth contour illustrated in Figure 19a and the gear tooth contour illustrated in Figure 19c.
19D is a cross-sectional view of the torque transfer mechanism 390 of Figs. 18, 19A and 19B illustrating a configuration of a drive shaft transverse slot 406 and a similar driven shaft transverse slot 412 according to many embodiments. The transverse slot 406 of the drive shaft is configured to receive the first connection pin 398 throughout the angular range between the drive shaft 420 and the connection axis 418. Similarly, the transverse slot 412 of the driven shaft is configured to receive the second connecting pin 400 in the entire angular range between the driven shaft 422 and the connecting shaft 418. The position of the first connection pin 398 within the drive shaft transverse slot 406 when the torque transfer mechanism 390 is operated in an angular configuration provides a single oscillating cycle for each 360 degree rotation of the drive shaft 392 It will be rough. Likewise, the position of the second connection pin 400 in the driven shaft transverse slot 412 will undergo a single oscillatory cycle for each 360 degree rotation of the driven shaft 396.
20 shows a collection of perspective views of the drive shaft 392 and the driven shaft 396. Fig. These perspective views illustrate in detail the drive shaft and the driven shaft viewed from different directions and illustratively include the spherical gear teeth 414 of the drive shaft 392, the spherical gear teeth 416 of the driven shaft 396, A transverse slot 406 of the driven shaft, a transverse slot 412 of the driven shaft, a drive shaft outer spherical surface 424, and a driven shaft outer spherical surface 428.
The vibrations of the connecting pins 398 and 400 in the transverse slots 406 and 412 can be described with reference to Figs. 21A and 21B. 21A is a view of the torque transfer mechanism 390 viewed from the direction normal to the connecting pins 398 and 400. Fig. 21B is a view of the torque transfer mechanism 390 viewed in a direction parallel to the connecting pins 398, 21A and 21B, the coupling member 394 is transparent to illustrate the interaction between the mechanism components. 21A, a first connecting pin 398 is placed obliquely in the drive shaft transverse slot to accommodate the angle between the drive shaft 392 and the connecting member 394. (This is illustrated in Fig. 21A, Lt; RTI ID = 0.0 &gt; 19d &lt; / RTI &gt; In Fig. 21B, the connecting member 394 has an angular orientation of 90 degrees from the connecting member orientation of Fig. 21A, whereby the connecting pins 398,400 are aligned in the viewing direction. In the orientation shown in Figure 21B, the connecting pins 398,400 do not lie diagonally within the transverse slots 406,412 (similar to Figure 19d). The position of the connecting pins 398 and 400 in the transverse slots 406 and 412 will complete the oscillating cycle while the torque transfer mechanism 390 revolves 360 degrees.
Relative to each other in the torque transmission mechanism 390, the rotary shaft and connection have a " pitch "degree of freedom about a line that is perpendicular to the longitudinal centerline of the pin and the " yaw" The two "yaw" axes are parallel and the "pitch" axes are constrained by engagement between the rotating shafts to one half of the total angle between the drive shaft and the driven shaft, respectively.
Multiple rows of spherical gear teeth can be used to provide shaft angle restraint by connecting drive shaft and driven shaft. For example, FIG. 22A illustrates a plurality of rows of concatenated spherical gear teeth. Figure 22b illustrates a cross-sectional profile and a spherical arrangement of the gear teeth of Figure 22a.
23A is a side view of a mechanism 440 for transmitting torque through an angle in accordance with many embodiments. The torque transfer mechanism 440 is similar to the mechanism 390 described above, but has a dual cross pin configuration. For example, the mechanism 440 uses the same connecting member 394 and the same connecting pin 398, 400 as the mechanism 390, but the driving shaft 444 and the connecting pin 398 for connecting the driving shaft 444 and the connecting pin 398, And a driven shaft cross pin 446 for connecting the cross pin 442, the driven shaft 448 and the connecting pin 400 are integrated. In Fig. 23A, the "sighted" linking member 394 is shown to further illustrate a double cross pin configuration.
23B illustrates a "sighted" driven shaft 448 for better illustrating the mechanism 440 and the driven shaft cross pin 446 with the connecting member 394 removed. The driven shaft cross pin 446 is accommodated in the hole of the driven shaft 448 and is rotatable in the driven shaft hole. The connecting pin 400 is received in the hole of the driven shaft cross pin 446. The relative rotation between the driven shaft 448 and the connecting member 394 about the center line of the connecting pin 400 is prevented by the rotation of the connecting pin 400 relative to the connecting member 394 and / 446, respectively. Similarly, the drive shaft cross pin 442 is received within the aperture of the drive shaft 444 and is rotatable within the drive shaft aperture. The connecting pin 398 is received in the hole of the driving shaft cross pin 442. The relative rotation between the drive shaft 444 and the connecting member 394 about the center line of the connecting pin 398 is transmitted to the rotation of the connecting pin 398 relative to the connecting member 394 and / Lt; RTI ID = 0.0 &gt; 398 &lt; / RTI &gt;
23C is a cross-sectional view of the mechanism 440 of FIGS. 23A and 23B taken through the centerline of the connecting pins 398 and 400. FIG. The drive shaft transverse slot 406 extends through the connecting pin 394 over the entire angular range between the drive shaft 444 and the connecting member 394 that occurs through rotation of the drive shaft 444 relative to the centerline of the drive shaft cross pin 442 398, respectively. Similarly, the driven shaft transverse slot 412 is formed between the driven shaft 448 and the connecting member 394, which is generated through the rotation of the driven shaft 448 relative to the center line of the driven shaft cross pin 446 And is configured to receive the connecting pin 400 throughout the angular range. As can be seen by comparing FIGS. 23C and 19D, the dual cross pin configuration of the mechanism 440 reduces the free role of the mechanism along the drive shaft and the driven shaft compared to the single cross pin configuration of the mechanism 390 . This reduced free play can provide a more consistent connection between drive shaft gear teeth 414 and driven shaft gear teeth 416.
23D now shows a cross-shaped pin receiving hole 452 of the drive shaft 444 and a similar cross-shaped pin receiving hole 452 of the driven shaft 448. As shown in FIG. Figure 23E shows drive shaft transverse slot 406 and driven shaft transverse slot 412.
24A is a simplified schematic diagram of a mechanism 460 for transferring torque through an angle that transmits a rotational motion by interacting with a coupling member slot in accordance with many embodiments. The torque transfer mechanism 460 includes a drive shaft 462, a linking member 464, and a driven shaft 466.
The drive shaft 462 is configured to be rotatably connected to the connecting member 464 on the shaft. The drive shaft 462 has a proximal end 468, a distal end 470, and a drive shaft 472 defined therebetween. The drive shaft 462 includes a first cylindrical protrusion 474 protruding from the drive shaft distal portion 470 and a second cylindrical protrusion 476 protruding from the opposite side of the drive shaft distal portion 470. The drive shaft distal portion 470 has a spherical surface 478 and a spherical gear tooth 480.
Similarly, the driven shaft 466 is configured to be rotatably connected to the connecting member 464 on the shaft. The driven shaft 466 has a distal portion 482, a proximal portion 484, and a driven shaft 486 defined therebetween. The driven shaft 466 includes a third cylindrical projection 488 projecting from the driven shaft proximal end 484 and a fourth cylindrical projection 490 projecting from the opposite side of the driven shaft near end 484. The driven shaft proximal end 484 has a spherical surface 492 and a spherical gear tooth 494.
The connecting member 464 is configured to be coupled on an axis with both the drive shaft distal portion 470 and the driven shaft proximal portion 484. The connecting member 464 has a tubular structure that defines a driving receiving portion 496, a driven receiving portion 498, and a connecting shaft 500 defined therebetween. The drive receiving portion 496 is formed to be able to be connected to the drive shaft distal portion 470 and generates ball articulated restraint between the drive shaft distal portion 470 and the drive receiving portion 496. For example, the drive receiving portion 496 may include one or more surfaces configured to be in continuous engagement with the drive shaft distal spherical surface 478. In many embodiments, the drive receiving portion 496 includes a spherical surface 502 configured to be in continuous engagement with the drive shaft distal spherical surface 478. Similarly, the driven receiving portion 498 is a shape that can be connected to the driven shaft proximal portion 484, and generates a ball articulated restraint between the driven shaft proximal portion 484 and the driven receiving portion 498 . For example, the driven receiving portion 498 may include one or more surfaces configured to be in continuous engagement with the driven shaft proximal spherical surface 492. In many embodiments, the driven receiving portion 498 includes a spherical surface 504 configured to be in continuous engagement with the driven shaft proximal spherical surface 492. As described in more detail below, connecting member 464 may include one or more individual pieces, e.g., two pieces.
The connecting member 464 is also configured to be rotatably connected to both the drive shaft distal portion 470 and the driven shaft proximal portion 484. The connecting member first receiving portion 496 includes a first slot 506 and a second slot 508. The first slot 506 and the second slot 508 respectively receive the first projection 474 and the second projection 476 and extend in the entire angular range between the drive shaft 462 and the driven shaft 466 And configured to receive these projections 474 and 476 (as illustrated in Figure 24D). Similarly,
The connecting member second receiving portion 498 includes a third slot 510 and a fourth slot 512. The third slot 510 and the fourth slot 512 receive the third protrusion 488 and the fourth protrusion 490 and extend in the entire angular range between the drive shaft 462 and the driven shaft 466 And are configured to receive these protrusions 488, 490. The interaction between the drive shaft projections 474 and 476 and the first receiving slot 506 and 508 transfers rotational motion from the drive shaft 462 to the connecting member 464. [ Similarly, the interaction between the second receiving slot 510, 512 and the driven shaft protrusion 488, 490 transfers the rotational motion from the connecting member 464 to the driven shaft 466.
Torque transfer mechanism 460 utilizes engagement between drive shaft distal portion 470 and driven shaft proximal portion 484 to provide relative angular orientation of drive shaft 462, connecting member 464, and driven shaft 466 . It is possible to control the relative orientation of the drive shaft 462, the connecting member 464 and the driven shaft 466 using the engagement feature, for example spherical gear teeth 480, 494. Shaft angular constraint is provided between drive shaft 462 and driven shaft 466 by engaging spherical gear teeth 480, 494 in torque transfer mechanism 460, but the use of spherical gear teeth is exemplary only. Other suitable shaft angular constraints may also be used, e.g. shaft angular constraint of the torque transfer mechanism 390 described above may also be used in the torque transfer mechanism 460. [ In addition, the gear tooth definition that may be applied to the torque transfer mechanism 390 discussed above may also be applied to the torque transfer mechanism 460.
24B is a view of the torque transfer mechanism 460 of FIG. 24A viewed in a direction parallel to the projection according to many embodiments. The hidden lines illustrate the first protrusion 474 in the first slot 506 and the third protrusion 488 in the third slot 510. The elongated shape of the slot allows the drive shaft 462 and the driven shaft 466 to rotate with respect to the connecting member 464 while the driving shaft 462 and the connecting member 464, the connecting member 464, and the driven shaft 466 To transmit the rotational motion between the two.
24C is a view of the torque transfer mechanism 460 of Figs. 24A and 24B viewed in a direction normal to the projection, illustrating in detail the two-piece connecting member 464 according to many embodiments. The connecting member 464 includes a first piece 514 and a second piece 516. The first piece 514 and the second piece 516 include attachment flanges with fastener holes for attachment fixtures (not shown). Although the connecting member 464 is illustrated as including a first piece 514 and a second piece 516 shown as being connected through an attachment flange 518, this approach is exemplary only, and other suitable approaches may also be used . For example, the connecting member 464 can be divided into a central tubular piece and two adjacent end caps, wherein the end caps are located in the center of the central shaft after the drive shaft 462 and driven shaft 466 are positioned relative to the central tubular piece, Can be assembled into tubular pieces.
FIG. 24D illustrates torque transfer mechanism 460 of FIGS. 24A, 24B and 24C in an angled configuration according to many embodiments. The spherical gear teeth 480 and 494 are formed by the positional restraint provided by the connection between the drive shaft distal portion 470 and the connecting member first receiving portion 496 and the positional restraint provided by the driven shaft proximal portion 484 and the connecting member second receiving portion 496. [ The angle between the drive shaft 472 and the connection shaft 500 is determined by the distance between the connection shaft 500 and the driven shaft 486 Is substantially the same as the angle of the base plate. The rotation of the drive shaft 462 about the drive shaft 472 causes the interaction between the first projection 474 and the first slot 506 and the interaction between the second projection 476 and the second slot 508 The rotation of the connecting member 464 about the connecting shaft 500 is caused. In operation, the position of the protrusions 474, 476 in the slots 506. 508 is similar to the vibration of the connection pins 398, 400 discussed above with reference to the torque transfer mechanism 390 of Figures 18-21b, . Similarly, the rotation of the connecting member 464 about the connecting shaft 500 causes rotation of the driven shaft 466 about the driven shaft 486. [
25A and 25B show a modified U-joint connecting member according to many embodiments having a mechanism 520 for transmitting torque through an angle that transmits the rotational movement between the drive shaft and the connecting member, the connecting member and the driven shaft It is a simplified schematic diagram. Torque transfer mechanism 520 includes a drive shaft 522, a first deformed U-joint connection 524, a connecting member 526, a second deformed U-joint connection 528, and a driven shaft 530. [ . The torque transfer mechanism 520 includes a drive shaft and a driven shaft engaging feature 560 that can restrain the relative orientation of the drive shaft 522, the linking member 526 and the driven shaft 530, (E.g., spherical gear teeth 532, 534).
The deformed U-joint connections 524 and 528 rotatably connect the drive shaft 522 and the connecting member 526 and the connecting member 526 and the driven shaft 530 respectively on the shaft. The first modified U-joint connection 524 includes a first pin 536 and a second pin 538. The first pin 536 is mounted to rotate about the connecting member 526 about the first pin shaft 540. The second pin 538 is transverse to the first pin 536 and is connected to the first pin 536. The drive shaft 522 can be connected to the second pin 538 and rotated about the second pin shaft 542. [ The second pin shaft 542 rotates itself about the first pin shaft 540. The drive shaft 522 includes an opening 544 configured to receive the first pin 536. [ Similarly, the second modified U-joint connection 528 includes a third pin 546 and a fourth pin 548. The third pin 546 is mounted to rotate about the connecting member 526 about the third pin shaft 550. The fourth pin 548 is transverse to the third pin 546 and is connected to the third pin 546. The driven shaft 530 is connected to the fourth pin 548 and rotates about the fourth pin shaft 552. The fourth pin shaft 552 rotates about the third pin shaft 550 itself. The driven shaft 530 includes an opening 554 configured to receive the third pin 546. [ The connecting member 526 may include an aperture 556 that provides for the installation of a second pin 538 and a fourth pin 548. [
In operation, the torque transfer mechanism 520 functions similarly to the torque transfer mechanism 390, 460 described above. The drive shaft and driven shaft engaging features (e.g., spherical gear teeth 532 and 534) constrain the relative orientation of drive shaft 522, linking member 526 and driven shaft 530, The relative angles between the shaft 522 and the connecting member 526 and between the connecting member 526 and the driven shaft 530 are substantially the same. In operation, rotation of the driving shaft 522 causes the first deformed U The rotation of the linking member 526 causes rotation of the linking member 526 through the second modified U-joint connection 528. The rotation of the linking member 526 causes the rotation of the linking member 526, &Lt; / RTI &gt;
FIG. 26 shows a compact wrist 600 with a two-degree-of-freedom wrist articulated by the linked traction member disclosed herein, and a two-degree-of-freedom wrist 600 having a dual degree of freedom as described herein for delivering torque through an angle across a two- Use is illustrated. The compact wrist 600 incorporates a two-degree-of-freedom wrist, wrist articulation by a linked traction member, and torque transmission through an angle by a dual universal joint. While all three aspects are included in the compact wrist 600, the wrist can be used either individually or in any suitable combination of aspects disclosed herein. The advantage of these three combined aspects is the ability to deliver centerline branching torque through a two degree of freedom wrist with a large angular displacement capability (e.g., up to about 60 degrees in any direction) and a relatively short length. In a minimally invasive surgical environment (e.g., during intestinal surgery), such a short length of wrist mechanism allows the surgical end actuator requiring torque transmission for operation to be steered (pitch, yaw, roll) in tight space The outer distance between the articulated end effector and the distal end of the support shaft is minimized. The above description has focused on describing certain aspects and features. It should be understood, however, that the various aspects and features may be combined at any time in practice. That is, the particular aspects and features described above with reference to one embodiment may be incorporated into one or more other embodiments even though other embodiments are not specifically shown.
It is understood that the embodiments and embodiments are merely illustrative purposes and that various modifications and changes in light of these are suggested to those skilled in the art and are included within the scope of the appended claims and the spirit and scope of the present application. Numerous different combinations are possible, and such combinations are contemplated as part of the present invention.
A tubular instrument shaft having a proximal end, a proximal end and an aperture therebetween and having a instrument shaft axis;
An end actuator including an end actuator body;
An intermediate wrist member pivotally connected to the distal end of the instrument shaft and pivotally connected to the end actuator body, the intermediate member being pivotable relative to the instrument shaft to orient the intermediate member about a first axis about the instrument shaft, Wherein the intermediate member has an outer width along the first axis and a second axis that is perpendicular to the first axis, And an outer length along the second axis, the length being significantly different from the width, whereby the intermediate member has an intermediate cross-section;
A movable system extending distally through the aperture of the instrument shaft to orient the end effector body and to actuate the end effector, wherein a portion of the actuation system is movable between a mechanical shaft and the end effector body, ;
A first joint pivotally connecting the mechanism shaft to the intermediate member; And
And a second joint pivotally connecting the intermediate member to the end actuator body,
The first joint includes a single pivot shaft extending along the first axis within the width of the intermediate member such that the first joint is disposed in a central region between the instrument shaft and the end effector body and remote from a portion separated by the side of the actuation system And the second joint comprises first and second coaxial turning shafts separated along a second axis.
The tool according to claim 1, wherein the width of the intermediate member is less than 1/4 of the length of the intermediate member.
The tool according to claim 1, wherein the first axis and the second axis are within 2 mm in the same plane.
4. The tool according to claim 3, wherein the first axis and the second axis are coplanar.
2. The tool of claim 1, wherein the intermediate member comprises an internal passageway for guiding the control cable of the actuating system between the tool shaft and the end actuator body and between the coaxial turning shafts of the second joint.
7. The apparatus of claim 6, further comprising a support member fixedly connected to the instrument shaft and pivotally connected to the intermediate member for rotation about a first axis, the support member comprising a movable member And an internal passageway for guiding a control cable of the system, wherein the guide surface restrains the control cable such that changes in cable tension are suppressed while pivoting about the first and second axes.
2. The apparatus of claim 1, wherein the outer disengaged portion of the movable system includes a first rotatable drive shaft for driving a first actuating mechanism of the end effector, wherein the first drive shaft passes adjacent to the first side of the intermediate member Said end-piece actuator body extending between said body and said orifice.
9. The system of claim 8, wherein the outer separated portion of the movable system further comprises a second rotatable drive shaft for driving a second actuating mechanism of the end effector, the second drive shaft is adjacent to a second side of the intermediate member Wherein the second side extends between the end actuator body and the hole so as to pass therethrough, the second side facing the first side.
2. A method according to claim 1 wherein the oriented portion of the movable system is operated to change the orientation of the end effector body relative to the mechanism shaft about the first and second axes and the orientation portion is reversibly drivable, Wherein a force applied to change the orientation of the tool is transmitted proximally through the aperture by the moveable system.
2. The tool according to claim 1, wherein the actuation of the end effector comprises articulating the joint of the end effector.
Pivotally connecting the intermediate member to the instrument shaft so as to rotate about a first axis oriented not parallel to the longitudinal direction of the instrument shaft,
Pivotally connecting the end actuator to the intermediate member to rotate about a first axis and a second axis oriented not parallel to the longitudinal direction, and
Connecting the actuation mechanism with the end actuator, the actuation mechanism being actuated to change the orientation of the end effector in two dimensions in the longitudinal direction, wherein at least a portion of the actuation mechanism is separated from at least one side of the intermediate member and passed outward And a step between the end end actuator and the aperture of the instrument shaft,
Wherein the intermediate member has an outer width in a first axial direction and a maximum outer length in a second axial direction and wherein the maximum outer length is greater than the width in the first axial direction.
13. The method of claim 12, wherein the first axis is normal to the second axis and at least one of the first axis or the second axis is normal to the machine-shaft length direction.
13. The method according to claim 12, wherein the intermediate member has a maximum outer width in a first axial direction, and a maximum outer width is less than 1/3 of an outer length.
13. The apparatus of claim 12, wherein the intermediate member comprises an inner passage for guiding a control cable extending between the end actuator and the aperture of the instrument shaft, wherein a change in cable tension during rotation of the guide surface about the first and second axes Restricting the control cable to be restrained, the method further comprising the step of connecting the end actuator control cable through the internal passage of the intermediate member.
13. A method according to claim 12, further comprising the step of reversing the orientation of the end effector relative to the instrument shaft, whereby the force applied to alter its orientation to the end effector / RTI &gt; is delivered to the proximal side through the second chamber.
13. A method according to claim 12, wherein the actuation of the end effector comprises articulating the joint of the end effector.
A mechanism shaft having an aperture penetrating the mechanism shaft;
A surgical end actuator including an end effector body;
The wrist connecting the instrument shaft and the end actuator body such that the end effector body moves relative to the instrument shaft about the first wrist pivot axis and the second wrist pivot axis, the wrist comprising a support member and an intermediate member, And a slot in the intermediate member along an axis between the first end and the second end, the support member pivotally connected to the intermediate member within the slot to define a first wrist pivot, A wrist having a second wrist pivot axis defined between a first end and a second end of the intermediate member; And
A movable system extending distally through an aperture in the instrument shaft to orient the end effector body and to actuate the end effector, wherein a portion of the movable system includes a movable system laterally separated from the intermediate member between the instrument shaft and the end effector body Surgical instrument.
KR1020127015018A 2009-11-13 2010-11-12 Surgical tool with a compact wrist KR101767060B1 (en)
US61/260,910 2009-11-13
US61/260,915 2009-11-13
US61/260,903 2009-11-13
PCT/US2010/056607 WO2011060315A2 (en) 2009-11-13 2010-11-12 Surgical tool with a compact wrist
KR20120095964A KR20120095964A (en) 2012-08-29
KR101767060B1 true KR101767060B1 (en) 2017-08-10
KR1020177021794A KR101847990B1 (en) 2009-11-13 2010-11-12 Surgical tool with a compact wrist
KR1020187009628A KR101955296B1 (en) 2009-11-13 2010-11-12 Surgical tool with a compact wrist
KR1020197006044A KR20190025059A (en) 2009-11-13 2010-11-12 Surgical tool with a compact wrist
KR1020127015018A KR101767060B1 (en) 2009-11-13 2010-11-12 Surgical tool with a compact wrist
EP (6) EP3381622A1 (en)
KR (4) KR101847990B1 (en)
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2018-02-20 JP JP2018027859A patent/JP6563053B2/en active Active
EP2489324A3 (en) 2016-11-23
JP6563053B2 (en) 2019-08-21
JP5969960B2 (en) 2016-08-17 Minimally invasive surgical instrument with end effector
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2017-05-12 E701 Decision to grant or registration of patent right