CN204618396U - A kind of operation technique system - Google Patents

Abstract

The utility model discloses a kind of operation technique system, comprise external command transmitting device, action command actuating unit, endoscope apparatus; Endoscope apparatus comprises ducts of endoscope, endoscope's work station and endoscopic monitors, and external command transmitting device comprises operating robotic arm, external command receptor, command control station, end mechanical arm control station; Action command actuating unit comprises driver element, action execution unit, driver element comprises some micromachines and some power switching devices of arranging corresponding to micromachine, described action execution unit is two covers, often overlaps action execution unit and comprises arm action incoming end, serpentine neck, end mechanical arm; End mechanical arm control station is connected respectively by the driver element of signal and communication line and action command actuating unit and endoscope's work station.The precision of this utility model action executing is higher, and operating flexibility is strong, substantially reduces operation time.

Description

A kind of operation technique system

Technical field

This utility model relates to medicine technology field, is specifically related to a kind of operation technique system, particularly a kind of automatization endoscopic surgery operating system.

Background technology

At present, when doing open operation or laparoscopic surgery, the method usually adopted gets involved from abdominal cavity, cuts the wound of more than 20cm, even and Wicresoft's " laparoscopic surgery " also needs the Wicresoft's mouth cutting 3-5 2-3cm.All need stomach, intestinal tissue to cut when carrying out these operations, after extracing inner tumor or polyp, then sew up, post-operative recovery time is generally longer, there is the risk of complication.

Along with the progressively development of Medical Technology, traditional endoscopic surgery is progressively applied, endoscopic surgery normally gets involved through affected part by stomach or rectum, any wound can not be left like this to patient body-surface, do not need thoroughly to cut stomach, intestinal tissue, just directly can extract tumor or polyp from inside, Post operation is also without the need to sewing up, such post-operative recovery time is short, can leave hospital every other day.

But due to the operational restriction of conventional endoscope apparatus itself, operate comparatively complicated, need showmanship and prolonged exercise to carry out skilled operation, adopt traditional endoscopic instrument to perform the operation, the operation process time is longer, and early clinic application complication risk is also relatively high.

Along with further developing of Medical Technology, robot assisted endoscopic surgery starts to be applied to therapeutic treatment field gradually, currently used robot assisted endoscopic surgery operating system comprises the communication port at operating robotic arm, operation-interface, interface controller, interface end control station, connecting interface control station and robot controlling station, and robot controlling station controls mechanical arm respectively by control system and carries out operation technique.

In addition, described robot assisted endoscope surgery system also comprises the endoscopic system of auxiliary endoscopic surgery, realizes robot assisted endoscopic surgery like this by the combination of mechanical arm and endoscopic system.

At present, when practical operation robot carries out auxiliary endoscopic surgery, there is end mechanical arm malfunction, the operational order of external mechanical manipulation arm cannot precisely be quickly transferred to end effector arm, end effector arm action is caused to perform slow, unhandy drawback.In addition, it is inadequate to there is degree of freedom in the end mechanical arm of present adopted robot assisted system, the various operational orders that simulation staff operating side that cannot be fully effective inputs.In addition, currently used robot assisted endoscopic surgery mostly is and arranges single end mechanical arm in endoscope tip, cannot complete the both hands of simulating people completely and operate accordingly, have some limitations in actual use procedure.

Utility model content

This utility model provides a kind of automatization endoscopic surgery operating system, when which overcoming employing robot assisted endoscopic surgery, built-in function arm cannot effectively perform external mechanical manipulation arm command adapted thereto and the limitation due to end mechanical arm degree of freedom fast, built-in function arm cannot the problem of various operations that inputs of fully effective simulation staff operating side, it solve current robot assisted endoscope surgery system Problems existing, while remaining the various advantage of current robot assisted endoscope surgery system, make built-in function arm faster for the various actions response speed performed by peripheral operation arm, the precision of action executing is higher, the motility of end mechanical arm operation is stronger, greatly reduce the requirement to doctor's skill and training experience, performance accuracy is high, operation time can be substantially reduced.

In order to solve the problem, the technical scheme that this utility model adopts is: a kind of automatization endoscopic surgery operating system, comprises external command input equipment, action command actuating unit and endoscope apparatus;

Described endoscope apparatus comprises endoscope, endoscope's work station and endoscopic monitors, and described endoscope's work station connects endoscope and endoscopic monitors respectively by holding wire; Described endoscope comprises ducts of endoscope and is arranged on the endoscope body of ducts of endoscope bottom, and the end of described endoscope body is provided with camera head;

Described action command actuating unit comprises end mechanical arm control station, driver element, action execution unit, and described end mechanical arm control station is connected to driver element and endoscope's work station respectively by connection; Described driver element comprises some micromachines and some power switching devices of arranging corresponding to micromachine; Described power switching device is connected respectively in action execution unit;

Described action execution unit is two covers, and described often cover action execution unit comprises arm and drives link, serpentine neck, end mechanical arm; Described arm drives link, serpentine neck, end mechanical arm to be connected successively; One end that described serpentine neck connects end mechanical arm is stretched in the ducts of endoscope of endoscope apparatus, and the end mechanical arm being connected to serpentine neck end stretches out ducts of endoscope, described in stretch out ducts of endoscope end mechanical arm be fixed on the end of ducts of endoscope;

Described external command input equipment comprises operating robotic arm, external command receptor, command control station and input equipment monitor, be connected by holding wire successively between described operating robotic arm, external command receptor, command control station, described input equipment monitor is respectively by the endoscopic monitors of order wire link order transmission control station and endoscope apparatus;

Arrange communication port between described external command input equipment and action command actuating unit, described communication port connects the command control station of external command input equipment and the end mechanical arm control station of action command actuating unit.

Preferably, in automatization's endoscopic surgery operating system that this utility model provides, described end mechanical arm comprises finger actuation device and operation finger, and described finger actuation device comprises deflection mechanism and rotating mechanism, and described operation finger is arranged on finger actuation device.

In detailed description of the invention more of the present utility model, in automatization's endoscopic surgery operating system that this utility model provides, described deflection mechanism comprises bracing wire, slipping block, deflection gears structure, described bracing wire is two, slipping block is two, deflection gears structure is two pairs, described two secondary deflection gears structures are separately fixed on slipping block corresponding thereto, the teeth portion of two secondary deflection gears structures is intermeshed, and two described bracing wires are each passed through the slip hole that wherein slipping block both sides are arranged and are fixedly connected with the both sides of another slipping block.

In other detailed description of the invention of the present utility model, in automatization's endoscopic surgery operating system that this utility model provides, described deflection mechanism comprises bracing wire, understructure, pulley structure, described pulley structure is arranged on the bracing frame on understructure top, described bracing wire is two, two described bracing wires are each passed through understructure, walk around pulley and are fixed on pulley.

Preferably, in automatization's endoscopic surgery operating system that this utility model provides, described rotating mechanism comprises bracing wire, understructure, rotary joint, described bracing wire is two, two bracing wires are each passed through understructure and enter rotary joint inside, two described bracing wires all wind with one circuit along rotary joint inside, and described end of pulling is fixed on rotary joint.

Preferably, in automatization's endoscopic surgery operating system that this utility model provides, described operation finger refers to structure for two, and described pair refers to that structure comprises two holding fingers, and the inner side that described two holding fingers are relative arranges clamping tooth.

In detailed description of the invention more of the present utility model, in automatization's endoscopic surgery operating system that this utility model provides, described two finger structures comprise two and independently shear finger, and the both sides correspondence that the inside of shearing finger is relative is provided with section.

In other detailed description of the invention of the present utility model, in automatization's endoscopic surgery operating system that this utility model provides, described operation finger, for singly to refer to structure, singly refers to that the end of structure connects cutting tool or vacuum inhales rainbow equipment.

Preferably, in automatization's endoscopic surgery operating system that this utility model provides, deflection mechanism and the rotating mechanism one_to_one corresponding of the driver element of described action command actuating unit and the finger actuation device of described end mechanical arm are arranged, and deflection mechanism and the rotating mechanism of described driver element and finger actuation device are connected respectively by two bracing wires.

Preferably, in automatization's endoscopic surgery operating system that this utility model provides, the deflection mechanism of the finger actuation device of described end mechanical arm and rotating mechanism correspond respectively to two driver elements of action command actuating unit, deflection mechanism and being connected by bracing wire between rotating mechanism with the corresponding driver element arranged.

Preferably, in automatization's endoscopic surgery operating system that this utility model provides, the driver element of described action command actuating unit is also provided with force transducer, described force transducer is common pulling force sensor or spring pressure sensor.

Preferably, in automatization's endoscopic surgery operating system that this utility model provides, it is integrated camera that the end of described endoscope body arranges camera head.

As optimization, it is turning arm type photographic head that the end of described endoscope body arranges camera head, and described turning arm type photographic head is plugged in the shooting pipeline of endoscope body end setting.

The beneficial effects of the utility model are:

When a kind of automatization of this utility model endoscopic surgery operating system which overcomes and adopts robot assisted endoscopic surgery, built-in function arm cannot effectively perform external mechanical manipulation arm command adapted thereto and the limitation due to end mechanical arm degree of freedom fast, built-in function arm cannot the problem of various operations that inputs of fully effective simulation staff operating side, it solve current robot assisted endoscope surgery system Problems existing, while remaining the various advantage of current robot assisted endoscope surgery system, make built-in function arm faster for the various actions response speed performed by peripheral operation arm, the precision of action executing is higher, the motility of end mechanical arm operation is stronger, greatly reduce the requirement to doctor's skill and training experience, performance accuracy is high, operation time can be substantially reduced.

Accompanying drawing explanation

Fig. 1 is this utility model overall structure schematic diagram;

Fig. 2 is the structural representation of action execution unit;

Fig. 3 is the A-A profile of Fig. 2;

Fig. 4 driver element internal structure schematic diagram

Fig. 5 is the partial structurtes schematic diagram of deflection structure I;

Fig. 6 is the partial structurtes schematic diagram of deflection structure II;

Fig. 7 is the partial structurtes schematic diagram of rotational structure;

Fig. 8 is operation finger two finger structural representation with clamping tooth;

Fig. 9 has the operation finger two finger structural representation shearing finger;

Figure 10 be operation finger singly refer to structural representation;

Figure 11 is single driver element and finger actuation device combinative structure schematic diagram;

Figure 12 is Dual Drive unit and finger actuation device combinative structure schematic diagram;

Figure 13 is the structural representation that pulling force sensor and driver element combine when using;

Figure 14 is the structural representation that spring pressure sensor and driver element combine when using;

Figure 15 is the structural representation of the endoscope body end of integrated camera;

Figure 16 is the structural representation of the endoscope body end of independent camera arm;

In figure: the input equipment of 1-external command, 11-operating robotic arm, 12-external command receptor, 13-command control station, 14-input equipment monitor, 2-action command actuating unit, 21-driver element, 211-micromachine, 212-power switching device, 22-action execution unit, 221-arm drives link, 222-serpentine neck, 223-end mechanical arm, 23-end mechanical arm control station, 3-endoscope apparatus, 31-endoscope, 311-ducts of endoscope, 312-endoscope body, 313-integrated camera, 314-turning arm type photographic head, 32-endoscope work station, 33-endoscopic monitors, 4-communication port, 5-finger actuation device, 51-deflection mechanism I, 511-bracing wire I, 512-slipping block, 513-deflection gears structure, 52-deflection mechanism II, 521-bracing wire II, 522-understructure, 523-pulley structure, 53-rotating mechanism, 531-bracing wire, 532-understructure, 533-rotary joint, 6-operates finger, 61-holding finger, 611-clamps tooth, 62-shears hands and refers to, 621-cuts into slices, 7-force transducer, 71-pulling force sensor, 72-spring pressure sensor.

Detailed description of the invention

For the technical characterstic of this programme can be clearly demonstrated, below by a detailed description of the invention, and in conjunction with its accompanying drawing, this programme is set forth.

As illustrated in figs. 1-16, a kind of automatization of this utility model endoscopic surgery operating system, it comprises external command input equipment 1, action command actuating unit 2 and endoscope apparatus 3.

External command input equipment 1 comprises operating robotic arm 11, external command receptor 12, command control station 13 and input equipment monitor 14, described operating robotic arm 11, external command receptor 12, be connected by holding wire successively between command control station 13, input equipment monitor 14 is respectively by the endoscopic monitors of connection link order transmission control station 13 and endoscope apparatus 3, arrange input equipment monitor 14 to be mainly used in receiving the picture signal transmitted from endoscopic monitors, be convenient to doctor and carry out hands art according to the picture situation operating robotic arm of transmission, the command control station 13 of described external command input equipment 1 transmits corresponding actuating signal by communication port 4 to action command actuating unit 2.

Described action command actuating unit 2 comprises driver element 21, action execution unit 22 and end mechanical arm control station 23, and described end mechanical arm control station 23 is connected to endoscope's work station of driver element 21 and endoscope apparatus 3 respectively by connection; Described driver element 21 comprises some micromachines 211 and some power switching devices 212 of arranging corresponding to micromachine 211, described power switching device 212 is corresponding with action execution unit 22 to be arranged, described power conversion apparatus 212 is power converter, the power-conversion of micromachine 211 can be become linearly pulling of bracing wire by generator, completes corresponding operation with drive actions performance element 22 action.

Described action execution unit 22 is two covers, and two cover action execution unit 22 are connected respectively the power switching device 212 in driver element 21.Described often cover action execution unit 22 comprises arm and drives link 221, serpentine neck 222, end mechanical arm 223; Described arm drives link 221, serpentine neck 222, end mechanical arm 223 to be connected successively, one end that described serpentine neck 222 connects end mechanical arm 223 is stretched in the ducts of endoscope of endoscope apparatus 3, and the end mechanical arm 223 being connected to serpentine neck 222 end stretches out ducts of endoscope, described in stretch out ducts of endoscope end mechanical arm 223 be fixed on the end of ducts of endoscope.

Described endoscope apparatus 3 comprises endoscope 31, endoscope's work station 32 and endoscopic monitors 33, and described endoscope's work station 32 connects endoscope 31 and endoscopic monitors 33 respectively by holding wire.Described endoscope 31 comprises ducts of endoscope 311 and is arranged on the endoscope body 312 of ducts of endoscope 311 bottom, the end of described endoscope body 312 is provided with camera head, camera head is integrated camera 313, integrated camera 313 can adopt 2D's or 3D, and can be controlled by endoscope apparatus 3.

As optimization, described camera head also selects turning arm type photographic head 314 as required, described turning arm type photographic head 314 is plugged in the shooting pipeline that endoscope body end arranges, and adopts turning arm type shooting head arm can expand observation for surgical environments and tracking greatly.

Endoscope apparatus 3 is mainly used in observing chamber situation, and the information monitored is fed back to endoscope's work station 32 in time, signal transfers to endoscopic monitors 33 after endoscope's work station 32 processes, and facilitates in surgical process like this, observes chamber situation at any time.

Signal transmissions between described external command input equipment 1 and action command actuating unit 2 is transmitted by communication port 4, communication port 4 connects the command control station 13 of external command input equipment 1 and the end mechanical arm control station 23 of action command actuating unit 2, for sending and feeding back corresponding command information.

In addition, be connected by order wire between described input equipment monitor 14 and the endoscopic monitors of endoscope apparatus 3, such endoscopic monitors picture signal can be transferred to input equipment monitor 14 in time, is convenient to doctor and observes the inner implementation status for operating robotic arm 11 action at any time.

Described end mechanical arm 223 comprises finger actuation device 5 and operation finger 6, described operation finger is arranged on finger actuation device, described finger actuation device 5 comprises deflection mechanism I 51 and rotating mechanism 53, the combination of deflection mechanism I 51 and rotating mechanism 53 realizes the rotation and the deflection that operate finger 6 jointly, such design effectively can simulate the various functions of staff, strengthen the degree of freedom of operation finger 6 action, operate more flexible, the range of application of automatization's endoscopic surgery can be expanded greatly.

Described driver element 21 can have two kinds of forms for the driving of end mechanical arm 223.

End mechanical arm 223 1 kinds of type of drive are: the driver element 21 of action command actuating unit 2 is arranged with the deflection mechanism I 51 of the finger actuation device 5 of end mechanical arm 223 and rotating mechanism 53 one_to_one corresponding, deflection mechanism I 51 and the rotating mechanism 53 of described driver element 21 and finger actuation device 5 are connected respectively by two bracing wires, driver element 21 drives deflection structure 51 and rotating mechanism 53 action by bracing wire, thus realizes end mechanical arm 223 and deflect and rotate.

Its concrete condition is: micromachine 211 correspondence connects two bracing wires, the other end of two bracing wires is connected on corresponding end mechanical arm 223 driving mechanism, when micromachine 211 rotates, a bracing wire will be tightened up, the bracing wire of corresponding offside will be relaxed, by the tension of two side guys with loosen thus drive end mechanical arm 223 action.

In addition, also can be two driver elements 21 that the deflection mechanism II 52 of the finger actuation device 5 of end mechanical arm 223 and rotating mechanism 53 correspond respectively to action command actuating unit 2 as an alternative, the deflection mechanism I 51 of described finger actuation device 5 and being connected by a bracing wire between rotating mechanism 53 with driver element 21, the design of this kind of structure also can realize the operation of end mechanical arm 223 Multi-angle free equally.

Its concrete condition is: the micromachine 211 of two driver elements 21 is connected respectively the two ends in a bracing wire, the driving mechanism of end mechanical arm 223 is arranged on the middle part of bracing wire, driver element 21 can control the rotation of two micromachines 211 respectively according to the pulling force situation of transient measurement, controlled the driving mechanism of end mechanical arm 223 like this by two micromachines 211, control effects more accurately can be reached.

In addition, 5 deflection mechanisms I 51 of finger actuation device described above comprise bracing wire I 511, slipping block 512, deflection gears structure 513, described bracing wire I 511 is two, slipping block 512 is two, deflection gears structure 513 is two pairs, described two secondary deflection gears structures 513 are separately fixed on slipping block 512 corresponding thereto, and the teeth portion of two secondary deflection gears structures 513 is intermeshed, and can relatively rotate each other.Two described bracing wires I 511 are each passed through the slip hole that wherein slipping block both sides are arranged and are fixedly connected with the both sides of another slipping block.During use, be arranged on the bracing wire of side when pulled, the bracing wire of opposite side is loosened, and the slipping block of fixing end of pulling deflects relative to another slipping block.Contrary, a side guy loosens, and opposite side bracing wire is strained, and the slipping block of fixing end of pulling deflects to tight side, the deflection like this by regulating the elasticity of slipping block both sides elastic threads to realize operation finger.

Simultaneously, deflection mechanism also can be designed to another kind of form as required, described deflection mechanism II 52 comprises bracing wire II 521, understructure 522, pulley structure 523, described pulley structure 523 is arranged on the bracing frame on understructure 522 top, described bracing wire II 521 is two, two described bracing wires II 521 are each passed through understructure 522, walk around pulley and are fixed on pulley.

During use, a side guy tension, opposite side bracing wire is loosened, and pulley structure 523 drives operation finger 6 to deflect to tight side.Otherwise a side guy loosens, opposite side bracing wire is strained, and pulley structure 523 drives operation finger 6 to deflect to opposite side.

Described finger actuation device 5 also comprises rotating mechanism 53, described rotating mechanism 53 comprises bracing wire 531, understructure 532, rotary joint 533, described bracing wire is two, two bracing wires are each passed through understructure 532 and enter rotary joint 533 inside, two described bracing wires all wind with one circuit along rotary joint 533 inside, and the end of bracing wire is fixed on rotary joint 533.

Described two rotations be symmetrical arranged for driving rotary joint 533.During use, the bracing wire tension of side, opposite side bracing wire is loosened, and rotary joint 533 is to tension one sideway swivel; In addition, when a side guy loosens, opposite side bracing wire is strained, and now rotary joint reversely rotates.Bottom described rotary joint 533, active card is placed in understructure 532, can effectively avoid rotary joint 533 to misplace when rotating like this.

Described operation finger 6 is two finger structures, and described two finger structure comprises two holding fingers 61, and the inner side that described two holding fingers are relative arranges clamping tooth 611, and clamping tooth 611 can help holding finger 61 to capture.In addition, described two finger structures also can be arranged to two as required and independently shear fingers 62, and the both sides that the inside of shearing finger 62 is relative are provided with section 621.

Described operation finger 6 also can be set to singly refer to structure, described end connection cutting tool or the vacuum suction rainbow equipment singly referring to structure.Singly refer to that the end of structure also can connect different instruments as required.

The driver element 21 of action command actuating unit 2 is also provided with force transducer 7, and described force transducer 7 is pulling force sensor 71 or spring pressure sensor 72.

When adopting pulling force sensor to detect the size of bracing wire pulling force, the mode of what its measuring principle adopted is equivalent measurement, namely carrys out the size of equivalent measurement bracing wire pulling force by measuring the power that driver element bears.Because the sheath pipe overhead of bracing wire outer setting is on driver element external shell, so only need the power measured by pressure transducer on driver element external shell, will can indirectly measure the size of bracing wire pulling force, thus determine the elasticity of bracing wire; When adopting spring pressure sensor to detect the size of bracing wire pulling force, be arranged on spring pressure sensor overhead on driver element in bracing wire, bracing wire forms a tensile force under spring force, by measuring the change of this tensile force thus realizing measurement to bracing wire pulling force size.

After obtaining the bracing wire pulling force size controlling the action of end mechanical arm 223, these measurement data will transfer to end mechanical arm control station 14 by holding wire, measurement data is after the process of end mechanical arm control station 14, get rid of the interference factors such as transmission resistance, obtain the size that in fact operating robotic arm 11 should apply power, the treated data obtained will transfer to command control station 13 by communication port 4, determine that doctor is applied to the size of operating robotic arm 11 power further, be convenient to doctor applies power size when operation process determination operation mechanical arm 11 like this.

During work, input equipment monitor 14 and endoscopic monitors 33 need and camera head matches, thus obtain the image feedback of 2D/3D.The image feedback obtained can be processed, and increases the display for robot manipulation's state and information, allows doctor more understand operation information and state.

The above is preferred implementation of the present utility model; for those skilled in the art; under the prerequisite not departing from this utility model principle, can also make some improvements and modifications, these improvements and modifications are also regarded as protection domain of the present utility model.

Claims (10)

1. automatization's endoscopic surgery operating system, is characterized in that, it comprises external command input equipment, action command actuating unit and endoscope apparatus;

Described endoscope apparatus comprises endoscope, endoscope's work station and endoscopic monitors, and described endoscope's work station connects endoscope and endoscopic monitors respectively by holding wire; Described endoscope comprises ducts of endoscope and is arranged on the endoscope body of ducts of endoscope bottom;

Described action command actuating unit comprises end mechanical arm control station, driver element, action execution unit, and described end mechanical arm control station is connected to driver element and endoscope's work station respectively by connection;

Described driver element comprises some micromachines and some power switching devices of arranging corresponding to micromachine, and described power switching device is connected respectively in action execution unit;

Described action execution unit is two covers, and described often cover action execution unit comprises arm and drives link, serpentine neck, end mechanical arm; Described arm drives link, serpentine neck, end mechanical arm to be connected successively; One end that described serpentine neck connects end mechanical arm is stretched in the ducts of endoscope of endoscope apparatus, and the end mechanical arm being connected to serpentine neck end stretches out ducts of endoscope, described in stretch out ducts of endoscope end mechanical arm be fixed on the end of ducts of endoscope;

Described external command input equipment comprises operating robotic arm, external command receptor, command control station and input equipment monitor, be connected by holding wire successively between described operating robotic arm, external command receptor, command control station, described input equipment monitor is respectively by the endoscopic monitors of order wire link order transmission control station and endoscope apparatus;

Arrange communication port between described external command input equipment and action command actuating unit, described communication port connects the command control station of external command input equipment and the end mechanical arm control station of action command actuating unit.

2. a kind of automatization as claimed in claim 1 endoscopic surgery operating system, it is characterized in that, described end mechanical arm comprises finger actuation device and operation finger, and described finger actuation device comprises deflection mechanism and rotating mechanism, and described operation finger is arranged on finger actuation device.

3. a kind of automatization as claimed in claim 2 endoscopic surgery operating system, it is characterized in that, described deflection mechanism comprises bracing wire, slipping block, deflection gears structure, described bracing wire is two, slipping block is two, deflection gears structure is two pairs, described two secondary deflection gears structures are separately fixed on slipping block corresponding thereto, the teeth portion of two secondary deflection gears structures is intermeshed, and two described bracing wires are each passed through the slip hole that wherein slipping block both sides are arranged and are fixedly connected with the both sides of another slipping block.

4. a kind of automatization as claimed in claim 2 endoscopic surgery operating system, it is characterized in that, described deflection mechanism comprises bracing wire, understructure, pulley structure, described pulley structure is arranged on the bracing frame on understructure top, described bracing wire is two, two described bracing wires are each passed through understructure, walk around pulley and are fixed on pulley.

5. a kind of automatization as claimed in claim 2 endoscopic surgery operating system, it is characterized in that, described rotating mechanism comprises bracing wire, understructure, rotary joint, described bracing wire is two, two bracing wires are each passed through understructure and enter rotary joint inside, two described bracing wires all wind with one circuit along rotary joint inside, and described end of pulling is fixed on rotary joint.

6. a kind of automatization as claimed in claim 2 endoscopic surgery operating system, is characterized in that, described operation finger refers to structure for two, and described pair refers to that structure comprises two holding fingers, and the inner side that described two holding fingers are relative arranges clamping tooth.

7. a kind of automatization as claimed in claim 2 endoscopic surgery operating system, is characterized in that, described operation finger, for singly to refer to structure, singly refers to that the end of structure connects cutting tool or vacuum inhales rainbow equipment.

8. a kind of automatization as claimed in claim 1 endoscopic surgery operating system, it is characterized in that, deflection mechanism and the rotating mechanism one_to_one corresponding of the driver element of described action command actuating unit and the finger actuation device of described end mechanical arm are arranged, and deflection mechanism and the rotating mechanism of described driver element and finger actuation device are connected respectively by two bracing wires.

9. a kind of automatization as claimed in claim 1 or 2 endoscopic surgery operating system, it is characterized in that, the deflection mechanism of the finger actuation device of described end mechanical arm and rotating mechanism correspond respectively to two driver elements of action command actuating unit, deflection mechanism and being connected by bracing wire between rotating mechanism with the corresponding driver element arranged.

10. a kind of automatization endoscopic surgery operating system as described in claim 1 or 8, is characterized in that, the driver element of described action command actuating unit is also provided with force transducer, described force transducer is common pulling force sensor or spring pressure sensor.