CN218852814U - Transmission connection structure of instrument driver and sterile adapter and surgical robot - Google Patents

Abstract

The utility model discloses a transmission connection structure of an instrument driver and an aseptic adapter and a surgical robot. The instrument driver comprises a driver transmission connecting piece, the driver transmission connecting piece is provided with a first butt joint end, the first butt joint end is used for butt joint with the sterile adapter, and a first tooth-shaped part is arranged at the first butt joint end. The sterile adapter includes an adapter drive connection having a second interface end for connection with the first interface end of the instrument driver, the second interface end having a second toothed portion disposed thereon. The second tooth portion is configured to be capable of meshing with the first tooth portion. According to the utility model discloses a transmission connection structure of apparatus driver and aseptic adapter utilizes dentate structure's meshing for adapter transmission connecting piece and driver transmission connecting piece can realize connecting wantonly in whole circumference direction, and the meshing is connected closely, and the gap is difficult for appearing, has improved driven stability and accuracy nature.

Description

Transmission connection structure of instrument driver and sterile adapter and surgical robot

Technical Field

The utility model relates to the technical field of medical equipment, particularly to a transmission connection structure and surgical robot of instrument driver and aseptic adapter.

Background

The surgical robot can help doctors to realize accurate positioning of operations, and has the advantages of reducing wounds of patients, shortening postoperative recovery time and the like. And it has stable operation platform, can solve the condition such as doctor's shiver, therefore has a large amount of applications in clinical surgery.

The surgical robot on the patient side performs a surgical operation with a surgical tool having an end effector. To meet the requirements of different surgical instruments used in surgery, the surgical instruments and instrument drivers are usually designed to be detachable for replacing different surgical instruments during surgery. Meanwhile, the surgical instruments are generally independently sterilized.

The instrument driver end is typically designed to be non-sterilizable, and to ensure sterility during the surgical procedure, a sterile adapter is added between the instrument driver and the surgical instrument during the procedure to isolate the non-sterilizable instrument driver end from the sterilizable surgical instrument end during the procedure.

At present, the transmission connection between the instrument driver and the sterile adapter mostly adopts a single-point butt joint mode. It requires that a single raised portion on the instrument driver connector and a single recessed portion on the sterile adapter drive connection rotate to the same direction and then do a one-to-one correspondence. The butt joint mode has more actions during operation, and the joint mode needs the bulge and the groove to provide certain clearance during matching to ensure the reliability of assembly when being connected, but the matching clearance can influence the torque transmission and can generate a rotation virtual position to cause the problem of lower relative reliability.

Therefore, there is a need for a drive connection of an instrument driver with a sterile adapter and a surgical robot to at least partially address the above problems.

SUMMERY OF THE UTILITY MODEL

In the summary section a series of concepts in a simplified form is introduced, which will be described in further detail in the detailed description section. The inventive content does not imply any attempt to define the essential features and essential features of the claimed solution, nor is it implied to be intended to define the scope of the claimed solution.

To at least partially solve the above problems, a first aspect of the present invention provides a transmission connection structure of an instrument driver and a sterile adapter,

the instrument driver comprises a driver transmission connecting piece, the driver transmission connecting piece is provided with a first butt joint end, the first butt joint end is used for butt joint with the sterile adapter, and a first tooth-shaped part is arranged at the first butt joint end;

the sterile adapter comprises an adapter transmission connecting piece, the adapter transmission connecting piece is provided with a second butt joint end, the second butt joint end is used for being connected with the first butt joint end of the instrument driver, and a second tooth-shaped part is arranged at the second butt joint end;

wherein the second tooth portion is configured to be capable of meshing with the first tooth portion.

According to the utility model discloses an instrument driver and aseptic adapter's transmission connection structure utilizes dentate structure's meshing for adapter transmission connecting piece and driver transmission connecting piece can realize connecting wantonly in whole circumference direction, and the meshing is connected closely, and the gap is difficult for appearing, has improved driven stability and accuracy nature.

Further, the first tooth-shaped part comprises a plurality of first teeth which are uniformly distributed along the circumferential direction of the driver transmission connecting piece;

the second toothed portion comprises a plurality of second teeth which are uniformly distributed along the circumferential direction of the adapter transmission connecting piece. According to the scheme, the direct installation is facilitated, the installation is convenient, and the aligning steps of the driver transmission connecting piece and the adapter transmission connecting piece are reduced.

Further, the driver transmission connector further comprises a first body part, the first tooth-shaped part is arranged at the top of the first body part, and each first tooth is symmetrical along the center line of the first tooth;

the adapter drive connector also includes a second body portion, the second tooth portions being disposed at a bottom of the second body portion, each of the second teeth being symmetrical along its own centerline.

Further, the first tooth has a first peak configured as a sharp or rounded corner; and/or

The second teeth have a second peak configured as a sharp or rounded corner. According to the arrangement, the first tooth crest and the second tooth crest are prevented from abutting against each other, so that the first tooth crest and the second tooth crest can be staggered quickly, and quick installation is facilitated.

Further, a pair of first guide surfaces which are symmetrically arranged is arranged on two sides of the first tooth crest, the horizontal distance between the two first guide surfaces is gradually increased along the direction far away from the first tooth crest, and the first guide surfaces are constructed into a straight surface or a smooth curved surface;

the two sides of the second tooth peak are provided with a pair of symmetrically arranged second guide surfaces, the horizontal distance between the two second guide surfaces is gradually increased along the direction away from the second tooth peak, and the second guide surfaces are constructed into straight surfaces or smooth curved surfaces.

Further, the two sides of the first tooth are symmetrical and provided with first meshing surfaces which are configured to be vertical surfaces or slightly inclined surfaces;

the two sides of the second tooth are symmetrically provided with second meshing surfaces which are constructed into vertical surfaces or slightly inclined surfaces;

when the first tooth-shaped part and the second tooth-shaped part are in a meshed state, the first meshing surface is in surface contact with the second meshing surface. According to the above arrangement, the transmission torque can be improved.

Further, a radial cross-sectional width at the first crest of the first tooth is less than a radial cross-sectional width at the root of the first tooth;

a radial cross-sectional width at the second crest of the second tooth is less than a radial cross-sectional width at a root of the second tooth.

Further, the outer peripheral surface of the first tooth-shaped part, which is located on the solid surface part of the first tooth, is configured with a first smooth cambered surface, and the diameter length of the first smooth cambered surface is increased along the direction from the first tooth crest to the tooth root of the first tooth; and/or

And the connecting surfaces between a plurality of second teeth of the second toothed part are connected with the meshing surfaces of two adjacent second teeth, part of the connecting surfaces are formed into second matching inclined surfaces, the diameter length of each second matching inclined surface is gradually reduced from the direction of the tooth crest of each second tooth to the direction of the tooth root of each second tooth, and the second matching inclined surfaces are formed to be matched with the first smooth arc surfaces on the peripheral surface of the first toothed part.

Further, the outer peripheral surface of the first tooth-shaped part, which is located on the solid surface part of the first tooth, is also provided with a first cylindrical surface, and the first cylindrical surface is adjacent to the first smooth arc surface and extends to the tooth root part of the first tooth; and/or

And part of the connecting surface between the plurality of second teeth of the second toothed part is a second matching cylindrical surface, the second matching cylindrical surface is adjacent to the second matching inclined surface, and the second matching cylindrical surface is matched with the first cylindrical surface of the first toothed part.

Furthermore, the driver transmission connecting piece further comprises a positioning part which is located at the first butt end and arranged on the first body part, the first tooth-shaped part is arranged around the positioning part, and a first matching inclined surface which extends along the circumferential direction is arranged on the periphery of the top of the positioning part.

Further, the adapter transmission connecting piece comprises a matching part located at the second butt end, the position of the matching part corresponds to the positioning part, so that the positioning part can at least partially extend into the matching part, the second toothed part is arranged along the circumferential direction of the matching part, the matching part is provided with a second matching inclined surface, and the second matching inclined surface is arranged along the circumferential direction of the matching part.

Further, the adapter transmission connecting piece is also provided with a second driving end opposite to the second butt end, the positioning portion is configured to protrude out of the protruding portion of the first body portion, the first toothed portion is connected to the protruding portion, the matching portion is configured to be a recessed portion, an opening of the recessed portion is located at the second butt end, the recessed portion is configured to be recessed towards the second driving end, the second toothed portion is arranged on the inner wall of the recessed portion, and the second matching inclined surface is arranged on the periphery, located at the second butt end, of the inner wall of the recessed portion.

Further, the positioning portion is configured to protrude from the positioning column of the first body portion, the first tooth-shaped portion is spaced apart from the positioning column, the engaging portion is configured to protrude from the positioning cylinder of the second body portion, the second engaging inclined surface is disposed on a top periphery of an inner wall of the positioning cylinder, the positioning column extends at least partially into the positioning cylinder, and the first engaging inclined surface is capable of being guided by the second engaging inclined surface in an engaging manner.

A second aspect of the present invention provides a surgical robot, comprising the above first aspect, wherein the instrument driver is connected to the sterile adaptor in a transmission manner.

According to the utility model discloses a surgical robot can play the similar technological effect with the transmission connection structure of the apparatus driver of above-mentioned first aspect and aseptic adapter.

Drawings

The following drawings of the utility model are used as part of the utility model for understanding the utility model. There are shown in the drawings, embodiments and descriptions thereof, for illustrating the principles of the invention.

In the drawings:

fig. 1 is a partial perspective view of a surgical robot according to a first preferred embodiment of the present invention;

FIG. 2 is an exploded view of the surgical robot of FIG. 1;

FIG. 3 is an exploded view of the surgical robot of FIG. 2 from another perspective;

FIG. 4 is a perspective view of the drive transmission linkage of FIG. 2;

FIG. 5 is a perspective view of the drive transmission linkage of FIG. 4 from another perspective;

FIG. 6 isbase:Sub>A schematic sectional view taken along line A-A' of the drive transmission linkage of FIG. 4;

FIG. 7 is a schematic view of the drive transmission linkage of FIG. 4 cut away in the direction B-B';

FIG. 8 is a perspective view of the adapter drive connection of FIG. 2;

FIG. 9 is a schematic view of the adapter drive connection of FIG. 8 cut away in the direction of C-C';

FIG. 10 is a schematic view of the adapter drive connection of FIG. 8 cut away in the direction D-D';

fig. 11 is a partial perspective view of a surgical robot according to a second preferred embodiment of the present invention;

FIG. 12 is a perspective view of the drive transmission linkage of FIG. 11;

FIG. 13 is a front view of the drive transmission linkage of FIG. 12;

FIG. 14 is a perspective view of the adapter drive connection of FIG. 11;

FIG. 15 is a perspective view of the adapter drive connection of FIG. 14 from another perspective;

FIG. 16 is a front view of the adapter drive connection of FIG. 14; and

figure 17 is a cross-sectional schematic view of the adapter drive connection of figure 14.

Description of the reference numerals:

100/200: surgical robot 110/210: instrument driver

111/211: drive transmission link 112/212: first driving end

113/213: first interface end 114/214: first body part

115/215: first tooth 116/216: first tooth

117/217: first tooth peak 118/218: first tooth valley

119/219: first guide surface 120/220: first transition surface

121/221: first engagement surface 122/222: first matching inclined plane

123: projection 124: first smooth arc surface

125: first cylindrical surface 223: positioning column

150: sterile adaptor 151/251: adapter drive connector

152/252: second driving end 153/253: second butt joint end

154/254: second body portion 155/255: second toothed part

156/256: second tooth 157/257: second crest

158/258: second valley 159/259: second guide surface

160/260: second transition surface 161/261: second mating surface

162/262: second mating ramp 163: concave part

263: the positioning cylinder 164: second smooth arc surface

165: the second column surface 266: third tooth part

180: the adapter main body 181: adapter cover

182: mounting hole 126: first fitting cylindrical surface

167: second mating cylindrical surface

Detailed Description

In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without one or more of these specific details. In other instances, well-known features have not been described in order to avoid obscuring the present invention.

In the following description, a detailed description will be given for a thorough understanding of the present invention. It is understood that these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of these exemplary embodiments to those of ordinary skill in the art. It is apparent that the implementation of the embodiments of the invention is not limited to the specific details familiar to those skilled in the art. The preferred embodiments of the present invention are described in detail below, however, the present invention can have other embodiments in addition to the detailed description.

It should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments in accordance with the invention. As used herein, the singular is intended to include the plural unless the context clearly dictates otherwise. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

Ordinal words such as "first" and "second" are referred to in this application as labels only, and do not have any other meanings, such as a particular order, etc. Also, for example, the term "first component" does not itself imply the presence of "second component", and the term "second component" does not itself imply the presence of "first component".

It is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "inner", "outer", and the like are used herein for purposes of illustration only and are not limiting.

A first preferred embodiment of the present invention will now be described in more detail with reference to fig. 1 to 10, and a second preferred embodiment of the present invention will now be described in more detail with reference to fig. 11 to 17.

First preferred embodiment

Referring first to fig. 1, 2 and 3, a surgical robot 100 of the present invention may include a surgical instrument (not shown), a sterile adapter 150 and an instrument driver 110. Wherein the sterile adapter 150 is connected to the instrument driver 110 and the surgical instrument is connected to the sterile adapter 150. Specifically, the lower surface of sterile adapter 150 interfaces with the upper surface of instrument driver 110. The front end of the surgical instrument is configured as a surgical tool such as forceps, scissors, clip light, and the like. The rear end of the surgical instrument is connected to the upper surface of the sterile adaptor 150, and the instrument driver 110 provides a driving force to the instrument actuator in the middle of the rear end of the surgical instrument through the sterile adaptor 150, so that the surgical instrument can perform pitching, yawing and gripping actions through a traction assembly (such as a wire rope) in the casing. The surface of the instrument driver 110 and the lower surface of the sterile adapter 150 can be fixed in a buckling manner, and the surface of the rear end of the surgical instrument and the upper surface of the sterile adapter 150 can be fixed in a buckling manner, so that when the surgical instrument is used, the surface of the instrument driver 110, the lower surface of the sterile adapter 150, the upper surface of the sterile adapter 150 and the surface of the rear end of the surgical instrument do not change relative to each other. And the driver transmission connecting piece 111 of the instrument driver 110 is fixedly connected with the adapter transmission connecting piece 151 of the sterile adapter 150 and the instrument rear end transmission connecting piece in a specific mode, so that when in use, the instrument driver 110 drives the driver transmission connecting piece 111 to rotate, and the driving force (or torque) is transmitted to the instrument rear end transmission connecting piece through the adapter transmission connecting piece 151, and further the control on the surgical tool is realized. This embodiment illustrates the drive connection of the instrument driver to the sterile adapter.

The instrument driver 110 includes a driver drive connection 111, the sterile adapter 150 includes an adapter drive connection 151, the adapter drive connection 151 is connected to the driver drive connection 111, and the instrument rear end connection is connected to the adapter drive connection 151.

Specifically, referring to fig. 2, 3, 4, 5, 8, the drive transmission link 111 has a first drive end 112 and a first interface end 113. With the first drive end 112 remote from the sterile adaptor 150 for connection to a drive assembly (not shown, which may be a motor, etc.) within the instrument driver 110. The first interface end 113 is proximate the sterile adapter 150 for interfacing with the adapter drive connection 151.

The adapter drive connection 151 has a second drive end 152 and a second interface end 153. With the second interface end 153 adjacent the instrument driver 110 for interfacing with the driver drive link 111. The second drive end 152 is distal to the instrument driver 110 for interfacing with the instrument rear drive link.

The drive transmission link 111 also has a first tooth 115 located at the first interface end 113. The adapter drive link 151 also has a second tooth 155 located at the second interface end 153. Also, the second toothed portion 155 is configured to be capable of meshing with the first toothed portion 115.

From this, according to the utility model discloses a surgical instruments utilizes the meshing of two dentations for adapter transmission connecting piece 151 and driver transmission connecting piece 111 can realize connecting wantonly in whole circumference direction, and the meshing is connected closely, and the gap is difficult for appearing, has improved driven stability and accuracy nature.

The drive transmission connection 111 will be described in detail below with reference to fig. 4 to 7. Here, the driver transmission connecting member 111 has a first body portion 114 and a positioning portion protruding from the first body portion 114, and therefore, in the present embodiment, the positioning portion is configured as a protruding portion 123. The end of the positioning portion forms a first abutting end 113. The first tooth portion 115 is disposed on the top of the first body portion 114 and disposed along the circumferential direction of the first body portion 114. Or, the first tooth 115 is disposed around the projection 123. The first body portion 114 and the positioning portion are preferably cylindrical.

The first tooth portion 115 includes a plurality of first teeth 116, the number of the first teeth 116 may be odd number or even number, the plurality of first teeth 116 are uniformly arranged along the circumferential direction of the driver transmission connecting member 111, and each first tooth 116 is connected to the protruding portion 123.

Each of the first teeth 116 has the same structure, and each of the first teeth 116 is symmetrical with respect to an axial cross-section of the first body portion 114. Alternatively, the first tooth 116 is symmetrical about its center plane. This arrangement facilitates direct mounting, facilitates ease of installation, and reduces the alignment steps of the driver drive connection 111 and the adapter drive connection 151.

First teeth 116 have first tooth peaks 117, and adjacent first teeth 116 form first tooth valleys 118 therebetween. A pair of symmetrical first guide surfaces 119, a pair of symmetrical first transition surfaces 120, and a pair of symmetrical first mating surfaces 121 are provided in this order on both sides of the first tooth 116 in the direction from the first crest 117 to the root of the first tooth 116.

In this case, a pair of first guide surfaces 119 is joined at the first tooth crest 117, or the first guide surfaces 119 are inclined toward the first tooth crest 117, and are configured as straight surfaces having an inclination angle, or the first guide surfaces 119 are configured as smoothly curved surfaces, so that the first tooth crest 117 is configured as a sharp corner or a rounded corner. Thus, the radial sectional area (or radial sectional width) at the first crest 117 of the first tooth 116 is smaller than the radial sectional area (or radial sectional width) at the root of the first tooth 116, so that the first tooth 116 forms a shape that is wide at one end and narrow at the other end.

A pair of first engaging surfaces 121, which are configured as vertical surfaces or slightly inclined surfaces, extend to the first body portion 114 in the height direction of the first teeth 116. The first engagement surface 121 is adapted to be in contact engagement with the second tooth 156 and functions to transmit torque primarily. The first engagement surface 121 is designed as a straight surface, which allows maximum transmission of torque. The first engagement surface 121 may also be configured as a slightly inclined surface, which may balance torque requirements and accuracy requirements. Meanwhile, when the slightly inclined structure of the first engaging surface 121 is matched with the corresponding matching surface of the second tooth 156, highly accurate matching can be achieved. Specifically, a slightly inclined surface may refer to an inclined surface that forms an angle of up to 15 ° with the vertical direction. Preferably, the included angle of the slightly inclined surface and the vertical direction is less than or equal to 5 degrees.

The first transition surface 120 is connected between the first guide surface 119 and the first engaging surface 121 to perform a transition guide function. The first transition surface 120 is inclined to a greater extent than the first guide surface 119, so that a smooth transition of the first guide surface 119 into the first engagement surface 121 is achieved.

The projection 123 is circumferentially provided with a first fitting slope 122 and a first fitting cylindrical surface 126. Wherein, the first mating slope 122 is located at the top periphery of the protruding portion 123, and the diameter length thereof gradually increases in the direction from the first crest 117 to the root of the first tine 116. In other words, the first mating ramp 122 may be configured as a straight ramp or an arc ramp, such as a rounded corner or a chamfer. And the first cylindrical mating surface 126 is disposed adjacent to the first inclined mating surface 122. The first mating cylindrical surface 126 and the first mating inclined surface 122 may be configured as a connecting surface between two first teeth 116 on the protruding portion 123.

Referring to fig. 4, 5, and 6, the outer peripheral surface of the first toothed portion 115, which is located on the outer peripheral side of the first tooth 116, transitions from a first smooth arc surface 124 to a first cylindrical surface 125 in a direction from the first tooth peak 117 to the root of the first tooth 116. The first smooth curved surface 124 has a radial cross-sectional radius or length that gradually increases in a direction from the first crest 117 to the first cylindrical surface 125. Thus, the first smooth arcuate surface 124 generally forms a shape that is inclined toward the middle of the drive transmission linkage 111. In other words, the radial cross-sectional radius or radial length of the first smooth arc surface 124 in the circumferential direction gradually increases in the direction from the first crest 117 to the root of the first tooth 116. The first cylindrical surface 125 extends from the first smooth arc surface 124 to the first body portion 114.

The adapter drive connection 151 will be described in detail below with reference to fig. 8, 9 and 10. The adapter transmission connector 151 has a second body 154, and the second body 154 is recessed at the second connection end 153 to form a fitting portion, which is shown as a cap and can be engaged with the first connection end. Therefore, in the present embodiment, the fitting portion may also be referred to as a recessed portion 163.

The opening of the recess 163 is located at the second interface end 153, and the recess 163 is configured to correspond with the protrusion 123 of the drive link 111 such that the protrusion 123 can extend at least partially into the recess 163.

The second toothed portion 155 is provided at the bottom of the second body portion 154, and is provided along the circumferential direction of the second body portion 154. Alternatively, the second tooth 155 is disposed in the recess 163 and located at the opening of the recess. The second tooth portion 155 includes a plurality of second teeth 156, and the plurality of second teeth 156 are uniformly arranged along the circumferential direction of the adapter transmission connecting member 151. Each of the second teeth 156 has the same structure, and each of the second teeth 156 is symmetrical with respect to an axial cross-section of the second body portion 154.

The second teeth 156 have second crests 157, and second valleys 158 are formed between adjacent ones of the second teeth 156. When first tooth 115 is engaged with second tooth 155, first tooth 116 extends into second valley 158 and second tooth 156 extends into first valley 118. In other words, when the driver transmission link 111 is mated with the adapter transmission link 151, the protrusion 123 mates with the recess 163 while the first tooth 115 mates with the second tooth 155, so that the driver transmission link 111 and the adapter transmission link 151 can be tightly coupled at any position.

The second tooth 156 may include: a second guide surface 159 corresponding to first guide surface 119, a second transition surface 160 corresponding to first transition surface 120, a second mating surface 161 corresponding to first mating surface 121, and a second smooth arcuate surface 164 similar in construction to first smooth arcuate surface 124 and a second cylindrical surface 165 similar in construction to first cylindrical surface 125.

Specifically, the pair of second guide surfaces 159 are joined at the second crests 157, or the second guide surfaces 159 are inclined toward the second crests 157, which are configured as straight surfaces (straight inclined surfaces) or smooth arc surfaces, so that the second crests 157 are configured as sharp or rounded corners.

Thus, the radial cross-sectional area at the second crest 157 of the second tooth 156 is less than the radial cross-sectional area at the root of the second tooth 156, such that the second tooth 156 forms a shape that is wider at one end and narrower at the other. And, first crest 117 and second crest 157 all construct sharp corner or fillet to have the shape that one end is wide and one end is narrow, can avoid first crest 117 and second crest 157 to support during the butt joint, make the two stagger fast, be favorable to realizing quick installation.

A pair of second engaging surfaces 161, which are configured as a vertical surface or a slightly inclined surface, extends to the second body portion 154 in the height direction of the second tooth 156. The second engagement surface 161 is adapted for surface contacting engagement with the first engagement surface 121 of the first tooth 116.

The second transition surface 160 is connected between the second guide surface 159 and the second engagement surface 161 to perform a transition guide function. Wherein the second transition surface 160 is inclined to a greater extent than the second guiding surface 159, thereby providing a smooth transition from the second guiding surface 159 to the second engaging surface 161.

The inner wall of the recess 163 is provided with a second fitting slope 162 and a second fitting cylindrical surface 167. Wherein the second mating slope 162 is provided at the periphery of the recess 163 at the second abutment end 153, the radial length of which gradually decreases in a direction from the second crest 157 to the root of the second tooth 156. In other words, the second mating ramp 162 is preferably configured as a straight ramp or an arc ramp, such as a rounded corner or a chamfered corner. And the second mating cylindrical surface 167 is disposed adjacent to the second mating ramp surface 162. The second fitting cylindrical surface 167 and the second fitting inclined surface 162 may be configured as a joint surface between the two second teeth 156 on the inner wall of the recess 163.

The circumferential inner side of the second tooth 156 is also provided with a second smooth arc surface 164 and a second column surface 165 in sequence from top to bottom. The second smooth curved surface 164 is configured as a smooth curved surface and extends to the second crest 157 so as to connect both the pair of second guide surfaces 159 and the pair of second transition surfaces 160. Thus, the second smooth arc surface 164 is formed substantially in a shape inclined toward the outer periphery of the adapter drive link 151. In other words, the radial cross-sectional radius or length of the second smooth arc surface 164 in the circumferential direction gradually increases in a direction from the second crest 157 to the root of the second tooth 156. The second post surface 165 extends from the second smooth arc surface 164 to the second body portion 154.

Thus, when the driver drive connection 111 is mated with the adapter drive connection 151, the first smooth arc 124 can be guided in cooperation with the second mating slope 162, and the second smooth arc164 can be guided in cooperation with the first mating ramp 122,so that the protrusion 123 can enter the recess 163 more easily and smoothly. Also, the first guide surface 119 can be guided in cooperation with the second guide surface 159, so that the first tooth 116 can enter the second valley 158 more easily, and the second tooth 156 can enter the first valley 118 more easily. Thus, the first cylindrical surface 125 of the first tooth 116 is enabled to form a fitting fit (and also mesh) with the second mating cylindrical surface 167, and the second cylindrical surface 165 of the second tooth 156 is enabled to form a fitting fit (and also mesh) with the first mating cylindrical surface 126.

Second preferred embodiment

Fig. 11 to 17 show a second preferred embodiment of the present invention. Wherein the main structure of the instrument driver 210 and sterile adapter (not shown) are the same as in the first preferred embodiment. The difference is mainly in the driver drive connection 211 and the adapter drive connection 251.

Specifically, fig. 12 and 13 show a drive transmission connection 211 of a second preferred embodiment of the present invention. The driver drive link 211 has a first drive end 212 and a first interface end 213, both similar to those of the first preferred embodiment and will not be described again.

The driver transmission connector 211 further includes a first body portion 214 and a first tooth portion 215 circumferentially disposed on an edge of the first body portion 214, and the first tooth portion 215 is continuous along a circumferential direction and located at the first abutting end 213. Each first tooth 216 may be identical in structure and symmetrical left and right (axially symmetrical) in itself.

Wherein the first tooth 216 also includes a first tooth peak 217, a first tooth valley 218, a pair of first guide surfaces 219, a pair of first transition surfaces 220, and a pair of first mating surfaces 221 similar to those of the first preferred embodiment. The first tooth 216 differs from the first preferred embodiment in that: the outer peripheral side of the first tooth 216 is not provided with a fitting surface, and fitting is achieved only by means of an engaging surface, the first tooth 216 being configured to extend inwardly from the periphery of the first body portion 214.

The driver transmission connector 211 further includes a positioning portion configured as a positioning column 223, the positioning column 223 protruding from a middle portion of the first body portion 214 at the first abutting end 113. And first tooth 216 is not disposed on locator post 223 but is spaced apart from locator post 223. The top periphery of the positioning post 223 is provided with a first matching inclined surface 222.

Further, the width of the first tooth 216 in the circumferential direction is gradually narrowed in the direction close to the positioning post 223, thereby easily causing a part of the top surface to be formed at the first crest 217. For example, the outer peripheral side of the first crest 217 shown in fig. 12 has a top surface, and the inner peripheral side is formed with a sharp corner or a rounded corner. Preferably, first peaks 217 are each configured as sharp or rounded corners throughout.

Fig. 14, 15, 16 and 17 show an adapter drive connection 251 of a second preferred embodiment of the present invention.

The adapter drive link 251 has a second drive end 252 and a second interface end 253, both of which are similar to those of the first preferred embodiment and will not be described in detail herein.

The adapter drive link 251 further includes a second body 254 and a second tooth 255 circumferentially disposed on an edge of the second body 254, the second tooth 255 being located at the second abutting end 253 and continuous in the circumferential direction. The structure of each second tooth 256 may be identical and left-right symmetrical (axially symmetrical) to itself.

Wherein the second tooth 256 also includes a second crest 257, a second valley 258, a pair of second guide surfaces 259, a pair of second transition surfaces 260, and a pair of second mating surfaces 261, similar to those of the first preferred embodiment. The second teeth 256 differ from the first preferred embodiment in that: the outer peripheral side of the second tooth 256 is also not provided with a fitting surface, the second tooth 256 is configured to extend in the radial direction of the second body portion 254, and the second tooth 256 is configured to extend beyond the outer periphery of the second body portion 254. Stated differently, the second tooth 255 has a diameter that is greater than a diameter of the second body portion 254 proximate the second interface end 253.

The adapter drive connection 251 further includes a mating portion configured as a positioning cylinder 263, the positioning cylinder 263 being disposed at the second mating end 253 of the second body portion 254 and protruding out of the middle of the second body portion 254. And the second tooth 256 is spaced apart from the positioning cylinder 263. The top periphery of the inner wall of the positioning cylinder 263 is provided with a second fitting slope 262.

The positioning cylinder 263 has a shape that matches the shape of the positioning post 223 such that when the driver drive connection 211 is mated with the adapter drive connection 251, the positioning post 223 can extend into the positioning cylinder 263 and the first toothed portion 215 engages the second toothed portion 255.

Further, the width in the circumferential direction of the second tooth 256 is gradually narrowed in the direction approaching the positioning cylinder 263, thereby easily causing a part of the top surface to be formed at the second crest 257. The outer peripheral side of the second crests 257 shown in fig. 15, for example, has a top surface, and the inner peripheral side is formed with sharp corners or rounded corners. Preferably, the second peaks 257 are each configured as sharp or rounded corners throughout.

In the preferred embodiment shown, the second drive end 252 of the adapter drive link 251 may also be provided with teeth, such as may be referred to as third teeth 266 (shown in fig. 14). The third tooth 266 may have the same structure as the second tooth 255 except for its diameter, and will not be described in detail. The third tooth 266 is adapted to engage a rear instrument end connector (not shown) on the surgical instrument to further achieve the technical effect of providing an all-around smooth installation without alignment.

The flows and steps described in all the preferred embodiments described above are only examples. Unless an adverse effect occurs, various processing operations may be performed in a different order from the order of the above-described flow. The above-mentioned steps of the flow can be added, combined or deleted according to the actual requirement.

Unless defined otherwise, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Features described herein in one embodiment may be applied to another embodiment, either alone or in combination with other features, unless the feature is not applicable or otherwise stated in the other embodiment.

The present invention has been described in terms of the above embodiments, but it is to be understood that the above embodiments are for purposes of illustration and description only and are not intended to limit the invention to the described embodiments. Furthermore, it will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that many more modifications and variations are possible in light of the teaching of the present invention and are within the scope of the invention as claimed. The scope of the present invention is defined by the appended claims and their equivalents.

Claims (14)

1. A transmission connection structure of an instrument driver and a sterile adapter is characterized in that,

the instrument driver comprises a driver transmission connecting piece, the driver transmission connecting piece is provided with a first butt joint end, the first butt joint end is used for butt joint with the sterile adapter, and a first tooth-shaped part is arranged at the first butt joint end;

the sterile adapter comprises an adapter transmission connecting piece, the adapter transmission connecting piece is provided with a second butt joint end, the second butt joint end is used for being connected with the first butt joint end of the instrument driver, and a second tooth-shaped part is arranged at the second butt joint end;

wherein the second tooth is configured to be engageable with the first tooth.

2. The instrument driver-to-sterile adapter drive connection of claim 1,

the first tooth-shaped part comprises a plurality of first teeth which are uniformly distributed along the circumferential direction of the driver transmission connecting piece;

the second toothed portion comprises a plurality of second teeth which are uniformly distributed along the circumferential direction of the adapter transmission connecting piece.

3. The drive connection of a device driver to a sterile adapter according to claim 2,

the drive transfer link further includes a first body portion, each of the first teeth being symmetrical along its own centerline;

the adapter drive connection further includes a second body portion, each of the second teeth being symmetrical about its own centerline.

4. The drive connection of a device driver to a sterile adapter according to claim 3,

the first tooth has a first peak configured as a sharp or rounded corner; and/or

The second tooth has a second crest configured as a sharp or rounded corner.

5. The drive connection of a device driver to a sterile adapter according to claim 4,

a pair of first guide surfaces which are symmetrically arranged is arranged on two sides of the first tooth peak, the horizontal distance between the two first guide surfaces is gradually increased along the direction far away from the first tooth peak, and the first guide surfaces are constructed into straight surfaces or smooth curved surfaces; and/or

The both sides of second crest are provided with the second spigot surface of a pair of symmetry setting, horizontal interval between the second spigot surface is along keeping away from the direction of second crest is gradual change, the second spigot surface structure is straight face or smooth curved surface.

6. The drive connection of a device driver to a sterile adapter according to any one of claims 2 to 5,

the two sides of the first tooth are symmetrical and are provided with first meshing surfaces which are constructed into vertical surfaces or slightly inclined surfaces;

the two sides of the second tooth are symmetrically provided with second meshing surfaces which are constructed into vertical surfaces or slightly inclined surfaces;

when the first tooth-shaped part and the second tooth-shaped part are in a meshed state, the first meshing surface is in surface contact with the second meshing surface.

7. The drive connection of a device driver to a sterile adapter according to claim 4 or 5,

a radial cross-sectional width at the first crest of the first tooth is less than a radial cross-sectional width at the root of the first tooth; and/or

A radial cross-sectional width at the second crest of the second tooth is less than a radial cross-sectional width at a root of the second tooth.

8. The instrument driver-to-sterile adapter drive connection of claim 2,

the outer peripheral surface of the first tooth-shaped part is provided with a first smooth cambered surface at the solid surface part of the first tooth, and the diameter length of the first smooth cambered surface is gradually increased along the direction from the first tooth peak to the tooth root of the first tooth; and/or

The connecting surfaces are located between the second teeth of the second tooth-shaped portions, the connecting surfaces are connected with the meshing surfaces of two adjacent second teeth, part of the connecting surfaces are formed into second matching inclined surfaces, the diameter length of each second matching inclined surface is gradually reduced from the tooth crest direction of each second tooth to the tooth root direction of each second tooth, and each second matching inclined surface is formed into sliding fit with the first smooth arc surface located on the peripheral surface of the first tooth-shaped portion.

9. The instrument driver-to-sterile adapter drive connection of claim 8,

the outer peripheral surface of the first tooth-shaped part is also provided with a first cylindrical surface at the solid surface part of the first tooth, and the first cylindrical surface is adjacent to the first smooth arc surface and extends to the tooth root part of the first tooth; and/or

And part of the connecting surface between the plurality of second teeth of the second toothed part is configured as a second matching cylindrical surface, the second matching cylindrical surface is adjacent to the second matching inclined surface, and the second matching cylindrical surface is matched with the first cylindrical surface of the first toothed part.

10. The instrument driver and sterile adapter drive connection according to any one of claims 3 to 5, wherein the driver drive connection further comprises a locating portion located at the first interface end and disposed at the first body portion, the first tooth portion being disposed around the locating portion, a top periphery of the locating portion being provided with a first mating bevel extending circumferentially.

11. The instrument driver and sterile adapter drive connection according to claim 10, wherein the adapter drive connection includes a mating portion at the second interface end, the mating portion being positioned to correspond to the locating portion such that the locating portion can extend at least partially into the mating portion, the second toothed portion being disposed along a circumference of the mating portion, the mating portion having a second mating bevel, the second mating bevel being disposed along the circumference of the mating portion.

12. The instrument driver and sterile adapter drive connection according to claim 11, wherein the adapter drive connection further has a second drive end opposite the second interface end, the positioning portion is configured to protrude from a protrusion of the first body portion, the first tooth is connected to the protrusion, the mating portion is configured to be a recess, an opening of the recess is located at the second interface end, and the recess is configured to recess in a direction toward the second drive end, the second tooth is disposed on an inner wall of the recess, and the second mating bevel is disposed on a periphery of the inner wall of the recess at the second interface end.

13. The instrument driver and sterile adaptor drive connection of claim 11, wherein the positioning portion is configured to protrude from a positioning post of the first body portion, the first tooth portion is spaced apart from the positioning post, the engaging portion is configured to protrude from a positioning barrel of the second body portion, the second engaging inclined surface is disposed on a top periphery of an inner wall of the positioning barrel, the positioning post extends at least partially into the positioning barrel, and the first engaging inclined surface is capable of guiding in cooperation with the second engaging inclined surface.

14. A surgical robot comprising a drive connection of the instrument driver of any of claims 1-13 to a sterile adapter.

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