DE102006045865B4 - Surgical manipulation instrument - Google Patents

Abstract

A surgical manipulation instrument (10) having a coupling (22) releasably connecting an extracorporeal drive member (12) to a manipulator member (14) having a partial intracorporeal end effector (40), and a manipulator-side coupling member (20) and a drive-side coupling member (18) is formed, wherein
the coupling parts (18, 20) have rotatable coupling bodies (24, 26) which can be separated from one another, which are coupled together axially aligned with one another and form a positive connection for transmitting rotational movement from the drive part (12) to the end effector (40), and
associated with the coupling parts (18, 20) is a radial guide (80) which permits only a radial engagement and disengagement movement for closing and opening the form-fitting coupling body connection to the rotational movement longitudinal axis (43),
characterized in that
the coupling body each having in a longitudinal plane and lying on a longitudinal axis coupling levels, wherein the coupled coupling body touching each other over the entire surface and form a positive connection in a positive locking plane.

Description

The invention relates to a surgical manipulation instrument, with a coupling which connects an extracorporeal drive part with a partially intracorporeal manipulator part separable.

Surgical instruments designed not for single use but for multiple use must be sterilized after each use. The sterilization can be carried out by means of non-thermal or thermal methods. In clinical practice, sterilization is essentially by thermal processes, in particular by so-called autoclaving. During autoclaving, the instrument to be sterilized is exposed to spiked water vapor over a certain period of time, which must wet all surfaces to be sterilized. The instrument to be sterilized is exposed in the autoclave temperatures of up to 156 ° C and pressures up to 2 bar over a period of up to 40 min. Autoclaving must be repeated after each use of the instrument so that up to several hundreds of autoclaves can be performed during instrument life.

Since the 1980s, so-called minimally invasive surgery has become increasingly important. Here, long, slender manipulation instruments are advanced through only small openings in the epidermis. The intracorporeal surgical field is observed by means of a rod-shaped camera introduced in the same way and an extracorporeal monitor. In particular, minimally invasive surgery offers advantages for the patient, namely low trauma, short convalescence times, lower postoperative pain, less blood loss, less risk of infection, less risk of wound healing disorders, better cosmetic results, etc. Disadvantages of minimally invasive surgery include i.a. the limited freedom of movement of the surgical instruments. Due to the fixed passage through the epidermal and adipose tissue, which forms an invariant point, reversed movement conditions or a disturbed hand-eye coordination result to the monitor image. Two degrees of freedom of motion are bound by the invariant point, i. Not every point in the working space can be reached with any orientation of the functional instrument end.

Minimally invasive manipulation instruments, which provide additional degrees of freedom of movement intracorporeally, can lead to increased intracorporeal manipulability and thus represent an important improvement for minimally invasive surgery. The additional degrees of freedom must be moved purposefully. This is possible with manual operation, but this requires great skill and practice. A robot-assisted telemanipulated approach whereby the surgeon sits away from the patient on an ergonomically-shaped console and guides the surgical manipulation instrument through the monitor using a suitable human-machine interface, without having to think about the kinematics and their actuation, is therefore meaningful. The surgical manipulation instrument is actuated computer-assisted and performs the surgeon's desired movement accordingly.

However, the actuators for driving the surgical manipulation instrument can not be autoclaved in the rule. Therefore, a separability of the extracorporeal drive part of the partial intracorporeal manipulator part is required.

The surgical manipulation instrument is therefore separated into two parts and separable by a clutch in an extracorporeal drive part and a partial intracorporeal manipulator part.

Out US Pat. No. 6,491,701 B2 For example, a surgical manipulation instrument with a coupling for separating the drive part from the manipulator part is known. The coupling parts each have rotatable coupling bodies, which have axial pins or bores and are coupled together axially or separated from one another. Since the rotatable opposing coupling body are not coupled together, if they are not aligned exactly with each other, a search for all coupling body pairs must be performed during engagement. The coupling bodies rotate in each case until a position is found in which all coupling body pairs are in a mergeable coupling position. A similar clutch is off US 2001 003 1983 A1 known. The coupling parts here have semi-cylindrical shaped coupling body. For a smooth coupling process, it is necessary to provide a certain minimum clearance between the coupling bodies in the coupled state. However, this game has a detrimental effect during operation of the manipulator instrument or even makes automatic regulation possibly even impossible.

The publication DE 696 35 050 T2 refers to a two-part surgical manipulation instrument with an extracorporeal drive part and a detachable manipulator part. The coupling parts have separable rotatable coupling body, which are axially aligned with each other and constitute a positive connection for transmitting a rotational movement.

The Kübler, B. et al., "Development of Actuated and Sensor Integrated Forceps for Minimally Invasive Robotic Surgery" discloses a lateral clutch motion in a surgical manipulator instrument. However, at no point in this document is discussed or described in detail how the coupling body are formed.

The publication US 5018901 A discloses a clutch that provides only axial and rotational clutch movement. A radial coupling movement is not disclosed.

The object of the invention is in contrast to provide a surgical manipulation instrument with a coupling between a drive part and a manipulator part, which allows easy coupling and a play-free coupling.

This object is achieved by a surgical manipulator instrument with the features of claim 1. Further developments follow in the dependent claims.

In the surgical manipulation instrument according to the invention the two coupling parts forming the coupling is assigned a radial guide, which allows only one to the Drehbewegungsaxialen the coupling body radial engagement and disengagement for closing and opening the positive coupling body connection. The coupling body of a movement axis aligned axially coupled together and together form a positive connection for transmitting a rotational movement of the drive member to the end effector of the manipulator part. By a radial coupling movement, with a corresponding design of the coupling body in a simple manner, a unique positive connection can be made during coupling. According to the invention, the coupling bodies have a positive locking plane approximately in a longitudinal plane. The two coupling bodies, which have a longitudinal plane, align themselves parallel to one another during the radial merging until they touch each other over their full surface in the coupling position. A search to align the coupling body with each other is not required.

Because of the radial coupling movement and thereby practically unavoidable self-alignment of the coupling body with each other, the coupling is guaranteed even under unfavorable conditions, for example in the operating room and by double-gloved persons who are not technical experts, with high reliability and operational safety. In order to produce a play-free connection of a coupling body pair or a plurality of coupling body pairs, the operator only has to apply a certain bias in the radial direction, which, however, lies in the region of less Newton. The form-fitting plane is preferably on the axial of the rotatable coupling body. The radial guide can have an extended inlet to facilitate the threading of the two coupling parts at the beginning of the coupling movement.

Preferably, one of the two coupling bodies of a coupling body pair is assigned a radial adjusting element for adjusting a play-free coupling of the coupling bodies with one another. The Radialjustierelement allows the two coupling body to each other adjusted so that in the coupling position a play-free coupling of the two coupling body is secured together. This is particularly important when a plurality of coupling body pairs are provided for transmitting driving forces with respect to a plurality of end effector degrees of freedom. In this case, each coupling body pair should be assigned a corresponding Radialjustierelement. If the same and no other manipulator part are always operated with a drive part, the respective radial adjustment element can be provided on the drive-side coupling body. If several different manipulator parts can be operated with a single drive part, it is advantageous to provide the radial adjustment elements respectively on the manipulator-side coupling bodies.

According to a preferred embodiment, the drive-side coupling body is designed as a U-shaped bracket, whose one end side forms the coupling body or its form-fitting plane. and represents. The U-shaped bracket has a certain suspension characteristic, which ensures within narrow limits a certain elasticity on one side of the coupling. As a result, it is ensured in the case of a plurality of coupling body pairs coupled to one another that play-free coupling of a plurality of coupling body pairs is possible despite certain tolerances.

The Radialjustierelemente should be adjusted so that with a minimum of coupling force a defined backlash is ensured. By Radialjustierelement manufacturing and assembly tolerances can be compensated. Furthermore, misalignments occurring over time can be corrected and thus freedom from play can be ensured over the entire lifetime of the manipulator instrument.

Preferably, the coupling parts are multiaxial, so that a plurality of coupling body pairs are provided for driving a plurality of end effector degrees of freedom of the manipulator part.

According to a preferred embodiment, a respective torque sensor is assigned to the drive-side coupling part and to the manipulator-side end effector. Furthermore, a differential module is provided on the manipulator side which determines the difference between the torques measured by the two torque sensors.

For mechanical coupling of the manipulator-side coupling body with its associated end effector cables are often used. As cables are often used because of their compared to metal cables better flexibility to very small radii plastic cables. For example, cables of high modulus PE, known as "Vectran", are suitable for this purpose. These have no creep over long periods, but are very elastic. At forces of up to 100 Newton, as they can occur in practice, therefore occur on considerable length changes. The change in length is inversely proportional to the torque difference determined by the difference module. Since the cable elongation can be determined from the torque difference, the position of the end effector can be determined from the position of the drive motor or corrected according to the calculated cable elongation.

Preferably, the drive part has a drive motor for driving the drive-side coupling body. Although the drive part can in principle also be operated manually, in practice the robotic design of surgical manipulation instruments plays a dominant role.

Preferably, an end effector is provided on the manipulator part, which is driven by the associated manipulator-side coupling body. An end effector is to be understood as meaning all effectors which are used in a surgical manipulation instrument, in particular grippers, scissors, joints, etc.

Preferably, the angle of rotation of the coupling bodies is less than 180 °, i. less than ± 90 ° about a central position, more preferably less than or equal to 80 °, i. ± 40 ° around a central position. When limiting the angle of rotation of the coupling body of a coupling body pair to less than 180 °, it can be ensured that the form-fitting planes of the coupling bodies can always align with one another during radial coupling together, without tilting each other. This is particularly possible if, for example, the drive-side coupling body is placed in a middle position before coupling together. At an angle of rotation of the two coupling body of a coupling body pair of less than 80 ° to each other can be completely dispensed with alignment of one of the two coupling body in a central position before the coupling together.

In the following an embodiment of the invention will be explained in more detail with reference to the drawings.

• 1 eine schematische Darstellung eines chirurgischen Manipulationsinstrumentes,
• 2 eine perspektivische Ansicht eines antriebsseitigen Kupplungsteiles des Manipulationsinstrumentes in der 1,
• 3 eine perspektivische Ansicht eines manipulatorseitigen Kupplungsteiles des Manipulationsinstrumentes der 1,
• 4 eine perspektivische Ansicht eines Kupplungskörper-Paares, und
• 5 eine Darstellung eines antriebsseitigen Kupplungskörpers.

Show it:

• 1 a schematic representation of a surgical manipulation instrument,
• 2 a perspective view of a drive-side coupling part of the manipulation instrument in the 1 .
• 3 a perspective view of a manipulator-side coupling part of the manipulation instrument of 1 .
• 4 a perspective view of a coupling body pair, and
• 5 a representation of a drive-side coupling body.

In the schematic representation of a surgical manipulation instrument 10 the 1 is an extracorporeal drive part 12 and a (partially) intracorporeal manipulator part 14 shown along a dividing line 16 are separated from each other.

The drive part 12 has a drive-side coupling part 18 and the manipulator part 14 has a manipulator-side coupling part 20 put on a clutch together 22 form.

The coupling parts 18 . 20 each have separable from each other and rotatable about a longitudinal axis coupling body 24 . 26 on, the coupled together a positive connection for transmitting a rotational movement of the drive part 12 on the manipulator part 14 enable. In the coupled state, the longitudinal axes of the rotatable coupling body are aligned 24 . 26 together. The coupling body 24 . 26 each have coupling planes lying in a longitudinal plane and on the longitudinal axis 28 . 30 on, the coupled together touch each other over the entire surface and thus represent a positive connection in a form-fitting plane. The angle of rotation of the two coupling bodies 24 . 26 is in each case 2 × 20 °, ie in each case 40 °, wherein the center position of the two coupling parts 24,26 corresponds positively with one another.

The drive part 12 has a drive motor 32 on, through which a drive shaft 34 is driven directly or with the interposition of a corresponding transmission. At the drive shaft 34 is rigid as a U-shaped bracket 36 trained coupling body 24 attached. At the drive shaft 34 is a Radialjustierelement 38 provided, with which the drive-side coupling body 24 can be radially adjusted, precisely perpendicular to the form-fitting plane of the coupling body. With the radial adjustment element 38 , which may be formed for example as a threaded screw, is the radial position of the coupling body 24 adjusted so that this under low preload and with coupled coupling parts 18 . 20 the other coupling body 26 touched all over.

The manipulator part 14 has an end effector 40 on, which is pivotable and by a manipulator-side output shaft 42 via a cable 44 and an effector wave 46 is rotationally driven. The end effector 40 For example, a pair of pliers, a pair of scissors, or a joint drive of a joint of a manipulator arm.

To the drive side U-shaped coupling body bracket 36 At the center piece is a torque sensor 50 attached in the form of strain gauges, through which the of the drive-side coupling part 24 on the manipulator-side coupling part 26 transmitted torque is determined. This torque sensor 50 is via a signal line with an evaluation module 52 connected.

Also manipulator side is a torque sensor 54 provided at the end effector shaft 46 , Also this torque sensor 54 is formed by strain gauges. The torque sensor 54 is via a signal line with a manipulator-side connector 58 connected, in turn, in coupled coupling parts with a drive-side connector 60 is electrically connected, in turn, via a signal line to the evaluation module 52 connected is.

The evaluation module 52 So receives both from the torque sensor 50 the drive-side coupling part 24 as well as the torque sensor 54 , the end effector 40 is assigned, the respective torques transmitted. The evaluation module 52 From this, finally, a drive torque and a differential torque can be determined. The drive torque and the differential torque are sent to a control module via a signal line 70 transmitted.

Alternatively, the torque sensors 50 . 54 each also be formed with glass fibers or in other ways.

On the drive motor 32 is a position sensor 72 arranged, the absolute position of the motor shaft via a signal line to the control module 70 sends. The control module 70 determines the absolute position of the end effector from the shaft position, the drive-side torque and the torque difference 40 , The larger the drive-side torque, the larger is the cable of the cable 44 transmitted force in cable longitudinal direction, and the greater is also caused thereby elongation of the elastic cable 44 , The larger the torque difference, the more friction is present, which is taken into account in the determination of the absolute end effector position correcting. With the help of torque sensors 50 . 54 In addition, plausibility checks can be carried out, for example, to ascertain a broken cable pull, excessive system forces, computer hardware command errors, etc. The cable pull 44 preferably consists of a steel cable, but may also consist of plastic or other materials.

The two coupling parts 18 . 28 is a radial guide 80 assigned to the drive-side guide claws 82 . 82 ' . 82 " and manipulator-side guide claws 84 . 84 ' . 84 " is formed. The radial guide ensures easy threading and guidance when engaging in the radial direction and for a corresponding fixation in the engaged state of the clutch 22 ,

In the 2-5 is a structural design of the in the 1 schematically illustrated manipulation instrument 10 shown. The 3 shows a complete manipulator part 14 with a coupling plate 90 , the three manipulator-side coupling parts 20 . 20 ' . 20 " and three radial guidance claws 84 . 84 ' . 84 " having. Furthermore, manipulator-side locking elements 92 intended.

In the 2 is the drive-side counterpart to the manipulator-side clutch plate 90 shown, namely the drive-side clutch plate 100 , On the coupling plate 100 are three radial guide claws 82 . 82 ' . 82 " arranged. Furthermore, the coupling plate 100 three drive-side coupling parts 18 . 18 ' and 18 " on. On the coupling plate 100 is also a mechanical locking bracket 102 arranged, with manipulator-side locking elements 92 cooperates and a complete locking or unlocking of the two clutch plates 90 . 100 can cause each other or each other.

In the 4 is the arrangement of the torque sensor 50 on the outside of the U-shaped bracket 36 recognizable in the form of two strain gauges that can be designed as resistance or optical strain gauges. In the 4 and 5 are also three trained as threaded screws Radialjustierelemente 38 recognizable with which the coupling plane 28 radially adjusted precisely and can be clamped backlash-free. The threaded screws are a central lag screw and two side pressure screws.

Claims (8)

A surgical manipulation instrument (10) having a coupling (22) releasably connecting an extracorporeal drive member (12) to a manipulator member (14) having a partial intracorporeal end effector (40), and a manipulator-side coupling member (20) and a drive-side coupling member (18), the coupling parts (18, 20) having separable rotatable coupling bodies (24, 26) which are coupled together axially coupled with each other and a positive connection for transmitting rotary motion from the drive part (12) to the end effector (40 ), and the coupling parts (18,20) is associated with a radial guide (80) which allows only one to the rotational movement longitudinal axis (43) radial engagement and disengagement for closing and opening the positive coupling body connection, characterized in that the coupling bodies are each in a longitudinal plane and on a longitudinal axis D coupling planes have, wherein the coupled coupling body touching each other over the entire surface and form a positive connection in a positive locking plane. Surgical manipulation instrument (10) after Claim 1 wherein one of the two coupling bodies (24) is assigned a radial adjusting element (38) for adjusting a play-free coupling of the coupling bodies (24, 26) with one another. Surgical manipulation instrument (10) according to one of Claims 1 to 2 , wherein the angle of rotation of the coupling body (24,26) is less than 180 °, and more preferably less than 80 °. Surgical manipulation instrument (10) according to one of Claims 1 to 3 wherein the drive-side coupling part (18) has a U-shaped bracket (36), one end of which forms the coupling body (28). Surgical manipulation instrument (10) according to one of Claims 1 to 4 , wherein the coupling (22) is multi-axially formed and a plurality of pairs of mutually associated coupling body (18,20,18 ', 20', 18 ", 20") for driving a plurality of end effectors (40). Surgical manipulation instrument (10) according to one of Claims 1 to 5 wherein the drive part (12) has a drive motor (32) for driving the drive-side coupling body (24). Surgical manipulation instrument (10) according to one of Claims 1 to 6 wherein the drive-side coupling part (18) is associated with a torque sensor (50), and an evaluation module (52) is provided which determines the drive-side torque from the sensor signal. Surgical manipulation instrument (10) according to one of Claims 1 to 7 , wherein in each case a torque sensor (50,54) is assigned to the drive-side coupling part (18) and the end effector (40), and an evaluation module (52) is provided, which determines the difference of the torque measured by the torque sensors (50,54).

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