CN217040291U - Balloon catheter driving device for vascular intervention surgical robot - Google Patents

Abstract

The utility model discloses a sacculus pipe drive arrangement for vascular intervention operation robot, sacculus pipe drive arrangement sets up on the apparatus operation box, be located the below of apparatus operation box, horizontal one side and the robot body side direction of apparatus operation box are connected, sacculus pipe drive arrangement includes sacculus pipe power input shaft, drive assembly and sacculus pipe delivery subassembly, drive assembly includes power output shaft, sacculus pipe delivery subassembly includes the delivery gyro wheel that sets up in pairs that realizes the delivery of sacculus pipe, one delivery gyro wheel in a pair of delivery gyro wheel of interoperation each other is installed on the output shaft and rotates along with the output shaft, power output shaft with sacculus pipe power input shaft sets up perpendicularly, sacculus pipe power input shaft follows the horizontal extension of apparatus operation box, its power input end stretches out from apparatus operation box side, for connection with a balloon catheter delivery drive shaft disposed on one side of the robot body.

Description

Balloon catheter driving device for vascular intervention surgical robot

Technical Field

The utility model relates to the technical field of medical equipment, especially, relate to a sacculus pipe drive arrangement for blood vessel intervenes surgical robot.

Background

The minimally invasive vascular interventional operation is a basic means for diagnosing and treating cardiovascular and cerebrovascular diseases, and most of the currently implemented vascular disease diagnosis and vascular reconstruction operations need to be assisted by the technology. The minimally invasive vascular intervention surgical robot can effectively improve the accuracy and the controllability of instrument delivery in the surgical process and reduce the cumulative radiation injury to doctors. The existing propelling mechanisms of instruments such as a catheter, a guide wire, a balloon catheter and the like in the vascular interventional surgical robot have the following defects: the various dispersing components are complicated and inconvenient to disassemble, and are not beneficial to disinfection of a catheter, a guide wire and a balloon catheter before an operation and replacement in the operation; the advancing mechanism does not allow for simultaneous delivery of the catheter and guidewire. For the operation of the robot-assisted surgery, the instrument operation needs to be capable of realizing the cooperative action of the guide catheter, the guide wire and the balloon catheter in a relatively compact space without interfering with each other. Meanwhile, strict requirements are placed on the sterility of instruments in surgical operations, and it is necessary to ensure that instruments in direct contact with blood vessels of patients are not polluted by operating mechanisms. On the other hand, the efficiency of installing and replacing instruments such as catheters, guide wires, balloon catheters and the like is still an important issue to be considered during the operation. Therefore, it is necessary to design an instrument operation box for an interventional surgical robot, which realizes precise, stable, sterile and efficient operation of related instruments.

In the prior art, most of instrument operation boxes for interventional operation robots are arranged above a power unit, but the mode of arranging the instrument operation boxes above the power unit has at least the following defects: (1) liquid in the operation process can permeate into the body of the power unit below, so that the problem of structural part corrosion or electrical short circuit is easily caused; (2) the whole thickness of the robot is large, so that the instruments such as the tube wire loaded on the robot cannot be completely attached to the vascular inlet of a patient, the effective use distance of the instruments such as the tube wire is reduced, and the operation of part of the patients cannot be completed.

In view of the above problems of the conventional techniques, there is a need for a vascular interventional surgical robot with further improved structural performance.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the above-mentioned defect that the conventional art exists, its purpose provides a sacculus pipe drive arrangement for vascular intervention operation robot, and it makes the apparatus operation box can be through side connected mode and this body coupling of robot to solve among the prior art the liquid infiltration that the apparatus operation box installed in the power pack top and lead to and take place the problem of corroding structure or electrical short circuit in the power pack organism, and reduce the robot and follow the operation of the whole thickness of tip portion and be convenient for the operation.

In order to achieve the above objects, the present invention provides a balloon catheter driving device for a vascular intervention surgical robot, the balloon catheter driving device is disposed on an instrument operation box and located below the instrument operation box, one lateral side of the instrument operation box is laterally connected to a robot body, the balloon catheter driving device includes a balloon catheter power input shaft, a transmission assembly and a balloon catheter delivery assembly, the transmission assembly includes a power output shaft, the balloon catheter delivery assembly includes delivery rollers arranged in pairs for delivering a balloon catheter, one delivery roller of a pair of delivery rollers cooperating with each other is mounted on the output shaft and rotates together with the output shaft, the power output shaft is disposed perpendicular to the balloon catheter power input shaft, the balloon catheter power input shaft extends along a lateral direction of the instrument operation box, the power input end of the robot extends out of the side face of the instrument operation box and is used for being connected with a balloon catheter delivery shaft arranged on one side of the robot body.

The above technical scheme of the utility model compare prior art and obtained following technological effect:

according to the balloon catheter driving device for the vascular intervention operation robot of the utility model, the power input shaft extends along the transverse direction of the instrument operation box, the power input end of the power input shaft extends out from the side surface of the instrument operation box and can be connected with the balloon catheter power output shaft of the power unit at one side of the robot body in a side connection mode, and the adaptive transmission component is adopted to connect the balloon catheter power input shaft with the balloon catheter delivery component, so that the instrument operation box of the vascular intervention operation robot can be connected with the robot body in a side connection mode, thereby solving the problem that the liquid seeps into the power unit body to generate corrosion structural parts or electrical short circuit caused by the installation of the instrument operation box above the power unit in the prior art, and the instrument operation box is arranged at the transverse side surface of the robot body in the side connection mode, the whole thickness of the slave end part of the robot is reduced, so that the devices such as the tube wire loaded on the robot can be completely close to the vascular entrance of a patient, the effective use distance of the devices such as the tube wire is remarkably increased, and the device is easy to popularize and use.

Drawings

The invention will be described in further detail with reference to the following figures and examples, in which:

fig. 1A is a perspective view illustrating the general structure of a slave end portion for a vascular interventional surgical robot;

fig. 1B is a perspective view illustrating a partial structure of a robot body for a vascular interventional surgical robot;

fig. 2 is a perspective view illustrating an instrument cassette assembly for a vascular interventional surgical robot;

fig. 3A is a perspective view of a balloon catheter drive device according to a first embodiment of the present invention;

fig. 3B is a perspective view of the balloon catheter driving device according to the first embodiment of the present invention, in which a part of the housing of the transmission mechanism is removed to show the internal structure of the transmission mechanism;

fig. 4 is a perspective view of a balloon catheter drive device according to a second embodiment of the present invention;

fig. 5 is a perspective view of a balloon catheter drive device according to a third embodiment of the present invention;

fig. 6 is a perspective view of a balloon catheter drive device according to a fourth embodiment of the present invention;

fig. 7 is a perspective view of a balloon catheter drive device according to a fifth embodiment of the present invention;

figure 8 is a perspective view illustrating one embodiment of a bias adjustment portion for a balloon catheter delivery assembly according to the present invention;

fig. 9A is a perspective view illustrating a second embodiment of a bias adjustment portion for a balloon catheter delivery assembly according to the present invention;

FIG. 9B is a cross-sectional view taken along line A-A of FIG. 9A;

fig. 10 is a perspective view illustrating a third embodiment of a bias adjustment portion for a balloon catheter delivery assembly according to the present invention; and

fig. 11 is a perspective view illustrating a fourth embodiment of a bias adjustment portion for a balloon catheter delivery assembly according to the present invention.

Detailed Description

The following describes the balloon catheter driving device for a vascular intervention surgical robot in detail. It should be noted herein that the embodiments of the present invention are merely illustrative and are used only for the purpose of illustrating the principles of the present invention and not for the purpose of limiting the same.

Reference is first made to fig. 1A, which illustrates in perspective view the general structure of a slave end portion for a vascular interventional surgical robot. As shown in fig. 1A, the slave end portion includes a robot body 1 and an instrument manipulation box assembly 2. The robot body 1 comprises a base mechanism and a power unit, the power unit comprises a catheter power box 5 and a guide wire power box 4, the catheter power box is installed on a sliding block arranged in the base mechanism and moves along with the sliding block, and the guide wire power box 4 is arranged at the rear part of the catheter power box and is laterally connected and fixed with the catheter power box. The transverse side of the instrument operation box component 2 is laterally connected with the adjacent side of the catheter power box 5, and the instrument operation box component 2 moves along with the catheter power box.

For convenience of description, in the following description and elsewhere in the specification, the moving direction of the instrument operation box assembly is defined as a longitudinal direction, and the width direction of the instrument operation box assembly perpendicular to the longitudinal direction is defined as a lateral direction; when in use, one end of the instrument operation box assembly facing to the blood vessel of the human body is called a front end, and the other end of the instrument operation box assembly facing away from the blood vessel is called a rear end; the side on which the operation surface of the instrument operation box assembly is located is referred to as an upper side, and the side opposite to the operation surface of the instrument operation box assembly is referred to as a lower side.

Referring now to fig. 2, there is illustrated in perspective view an instrument cassette assembly 2 for a vascular access surgical robot, which is detachably mounted laterally on one lateral side of the robot body by a connector. As shown in fig. 2, the instrument operation box assembly 2 includes an instrument operation box 300, on which a guide tube 301 is provided, the guide tube extending in a longitudinal direction of the instrument operation box, a front end of which extends from a front end of the instrument operation box, a rear end of which is connected to a front end of a guide tube connector 302, and a rear end of which is connected to a Y valve 303, the Y valve being fixedly installed on the instrument operation box 300. A rotary drive 304, typically in the form of a gear, is provided on the catheter connector, the catheter connector and catheter being rotatable relative to the Y-valve and hence the instrument cartridge. During operation, the catheter usually needs to realize two motions, namely rotation motion and longitudinal front-back motion, and the instrument operation box can move back and forth relative to the base of the robot body, so that the catheter is driven to move back and forth together to realize the longitudinal motion of the catheter; the rotary driving member 304 is connected to a driving source, such as a motor, via a catheter rotation driving device, and is driven by the driving source to perform a rotary motion, so as to drive the catheter to rotate together to perform a rotary motion of the catheter.

In addition, the instrument operation box is also provided with a balloon catheter 311 which is arranged in a channel 312 which is formed at the rear side of the Y valve and extends towards the rear side, the front end of the balloon catheter extends into the catheter through the Y valve, and the balloon catheter is driven by the balloon catheter delivery component to perform directional movement in the catheter so as to deliver the balloon catheter to the position of the blood vessel lesion. The balloon catheter delivery assembly is in the form of a pair of delivery rollers disposed in pairs, the cooperating pair of delivery rollers being located on the sides of the grooved wheels, respectively, the balloon catheter being sandwiched between the delivery rollers, the forward and backward movement of the balloon catheter being achieved by the pair of delivery rollers rotating in engagement with each other, which may be friction wheels.

Fig. 3A and 3B illustrate a balloon catheter driving device 200 for a vascular intervention surgical robot according to a first embodiment of the present invention, wherein fig. 3A is a perspective view of the balloon catheter driving device, and fig. 3B is a perspective view of a transmission mechanism 297 with a partial housing removed to show an internal structure of the transmission mechanism.

The balloon catheter driving device 200 is provided on and below the instrument manipulation box 300. As shown in fig. 3A and 3B, the balloon catheter driving device 200 includes a balloon catheter power input shaft 201, and a transmission assembly disposed between the balloon catheter power input shaft and a balloon catheter delivery assembly 290, wherein power input from the balloon catheter power input shaft 201 is transmitted to the balloon catheter delivery assembly 290 through the transmission assembly, and the balloon catheter delivery assembly drives the balloon catheter to move back and forth longitudinally.

With continued reference to fig. 3A, 3B and 2, a balloon catheter power input shaft 201 extends transversely of the instrument pod and is bearing-supported on the housing wall of a housing 296 of a transmission 297 mounted on the instrument pod or otherwise secured to other structural components of the instrument pod, with a first transmission gear 202 provided on a power output 2012 of the balloon catheter power input shaft and a power input 2011 extending laterally from the instrument pod (see fig. 2) for connection to a balloon catheter delivery drive shaft 902 of a drive source (e.g., a motor or the like) of a power unit on the side of the robot body, see fig. 1B. Preferably, the power input 2011 of the balloon catheter power input shaft is formed with an axial bore having a polygonal or D-shaped cross-sectional profile for non-rotational coupling with the balloon catheter delivery drive shaft 902 of the drive source.

Referring to fig. 3A and 3B, the transmission assembly includes a first intermediate transmission shaft 205, a second intermediate transmission shaft 209 and an output shaft 2011, the first intermediate transmission shaft 205 is disposed parallel to the balloon catheter power input shaft 201 and is supported on the housing wall through a bearing, and a power input end of the first intermediate transmission shaft is provided with a second transmission gear 206. An intermediate transmission gear 204 is arranged between the first transmission gear 202 and the second transmission gear 206, the intermediate transmission gear is arranged on an intermediate gear shaft 203, the intermediate gear shaft 203 is arranged in parallel with the balloon catheter power input shaft 201 and is supported on the wall of the casing through a bearing, and the intermediate transmission gear 204 is respectively meshed with the first transmission gear 202 and the second transmission gear 206.

The power take-off of the first intermediate transmission shaft 205 is provided with a third transmission gear 207 in the form of a bevel gear. The second intermediate transmission shaft 209 is perpendicular to the power input shaft and the first intermediate transmission shaft 205, is arranged along the up-and-down direction, and is supported on the horizontal structure wall of the instrument operation box through a bearing, the power input end of the second intermediate transmission shaft 209 is provided with a fourth transmission gear 208 in the form of a bevel gear, and the fourth transmission gear 208 is meshed with the third transmission gear 207.

The power output end of the second intermediate transmission shaft 209 is provided with a fifth transmission gear 210 in the form of a straight gear, the number of the power output shafts 2011 is two, and the two power output shafts are arranged in parallel with the second intermediate transmission shaft 209 and are supported on the horizontal structure wall of the instrument operation box through bearings. The two power output shafts 2011 are respectively provided with straight gears 212 (only one of which is shown in the figure) meshed with the fifth transmission gear 210, so that when the fifth transmission gear 210 rotates, the two straight gears 212 are driven to synchronously rotate in the same direction.

The balloon catheter delivery assembly 290 includes two pairs of delivery rollers arranged sequentially in the delivery direction of the balloon catheter. One of the delivery rollers provided in pairs is mounted on each of the output shafts, and the delivery rollers 213 mounted on the output shafts rotate together with the output shafts. In the embodiment shown, the delivery roller may be a friction wheel, and a delivery roller 213 mounted on the output shaft is adapted to engage with a further delivery roller 214 provided on the instrument cassette for co-operation therewith.

In operation, a balloon catheter is placed between each of the two pairs of delivery rollers, the power input shaft of the balloon catheter receives power from a power source and transmits the power to the two spur gears 212 rotating synchronously via the transmission assembly, the two spur gears rotating synchronously drive the delivery rollers 213 mounted on the output shaft to rotate, respectively, and the delivery rollers 213 and the delivery rollers 214 cooperate to drive the balloon catheter to move back and forth.

Reference is now made to fig. 4, which illustrates a balloon catheter driving device for a vascular interventional surgical robot in accordance with a second embodiment of the present invention.

The balloon catheter driving device of the second embodiment is substantially the same in overall structure as the balloon catheter driving device of the first embodiment, except that:

in the balloon catheter driving device of the second embodiment, the intermediate gear shaft and the intermediate transmission gear are omitted, and the first transmission gear 222 on the power input shaft 221 is directly meshed with the second transmission gear 226 on the intermediate transmission shaft 225, thereby simplifying the structure of the transmission assembly.

Reference is now made to fig. 5, which illustrates a balloon catheter driving device for a vascular interventional surgical robot in accordance with a third embodiment of the present invention.

The balloon catheter driving device of the third embodiment is substantially the same in overall structure as the balloon catheter driving device of the first embodiment, except that:

in the balloon catheter driving device of the third embodiment, the first transmission gear, the intermediate gear shaft, and the second transmission gear are omitted, and the power output end 2312 of the balloon catheter power input shaft 231 is provided with the third transmission gear 237 and directly drives the third transmission gear, thereby simplifying the structure of the transmission assembly.

Reference is now made to fig. 6, which illustrates a balloon catheter driving device for a vascular intervention surgical robot in accordance with a fourth embodiment of the present invention.

The balloon catheter driving device of the fourth embodiment is substantially the same in overall structure as the balloon catheter driving device of the first embodiment, except that:

in the first embodiment, a gear set composed of the first transmission gear, the intermediate transmission gear, and the second transmission gear is used as a transmission mechanism between the power input shaft and the first intermediate transmission shaft. In the balloon catheter driving device according to the fourth embodiment, the power input shaft 241 has a power output end provided with a first pulley 242, the power input end of a first intermediate transmission shaft 245 is provided with a second pulley 246, and a transmission belt 243 is wound around the first pulley and the second pulley, respectively, so that power is transmitted from the power input shaft to the first intermediate transmission shaft by a pulley-belt transmission mechanism.

Reference is now made to fig. 7, which illustrates a balloon catheter driving device for a vascular interventional surgical robot according to a fifth embodiment of the present invention.

The main differences between the balloon catheter drive device of the fifth embodiment and the balloon catheter drive device of the first embodiment are as follows.

As shown in fig. 7, the balloon catheter driving device includes a balloon catheter power input shaft 251 and a transmission assembly including an intermediate transmission shaft 255 and an output shaft 259, the intermediate transmission shaft 255 is disposed in parallel with the balloon catheter power input shaft 201, and the transmission mechanism therebetween is the same as that of the first embodiment, and the description thereof is omitted. The power output end of the intermediate drive shaft 255 is provided with a third drive gear 257 in the form of a bevel gear. The output shaft 259 is perpendicular to the balloon catheter power input shaft 251 and the intermediate transmission shaft 255 and is arranged along the up-and-down direction, a fourth transmission gear 258 in the form of a bevel gear is arranged at the power input end of the output shaft 259, and the fourth transmission gear is meshed with the third transmission gear 257.

In the fifth embodiment, the balloon catheter delivery assembly 252 has only one pair of delivery rollers. One delivery roller 253 of the pair of delivery rollers is mounted on the output shaft 259 and rotates with the output shaft. A delivery roller 253 mounted on the output shaft is adapted to engage with another delivery roller 254 provided on the instrument operation box and cooperating therewith.

In operation, the balloon catheter is placed between the pair of delivery rollers, the power input shaft 251 receives power from the power source and transmits the power to the delivery rollers 253 in the delivery assembly of the balloon catheter via the transmission assembly, and the delivery rollers 253 drive the delivery rollers 254 to rotate together, thereby driving the balloon catheter to move back and forth.

Further, as a modification of the balloon catheter driving device of the fifth embodiment, as for the transmission mechanism between the power input shaft and the intermediate transmission shaft, it is possible to adopt a manner in which the first transmission gear on the power input shaft is directly meshed with the second transmission gear on the intermediate transmission shaft, similarly to the balloon catheter driving device of the second embodiment, thereby omitting the intermediate transmission gear.

Further, as another modification of the balloon catheter driving device according to the fifth embodiment, the first transmission gear, the intermediate gear shaft, and the second transmission gear may be omitted, and the third transmission gear may be provided at the power output end of the power input shaft and directly driven, thereby simplifying the structure of the transmission assembly, similarly to the balloon catheter driving device according to the third embodiment.

Further, as still another modification of the balloon catheter driving device of the fifth embodiment, as for the transmission mechanism between the balloon catheter power input shaft and the intermediate transmission shaft, a first pulley may be provided at the power output end of the balloon catheter power input shaft, a second pulley may be provided at the power input end of the intermediate transmission shaft, and a belt may be wound around the first pulley and the second pulley, respectively, similarly to the balloon catheter driving device of the fourth embodiment, so that power is transmitted from the balloon catheter power input shaft to the intermediate transmission shaft using a pulley-belt transmission mechanism.

Due to the variety of sizes of the balloon catheters, two cooperating delivery rollers must be tightly attached to the balloon catheter to achieve delivery of the balloon catheter. Preferably, therefore, the balloon catheter delivery assembly comprises a biased adjustment portion which on the one hand facilitates the placement and removal of the balloon catheter and on the other hand accommodates different sized balloon catheters.

Referring now to FIG. 8, one embodiment of a bias adjustment portion is schematically illustrated.

As shown in fig. 8, the bias adjusting part includes a fixed plate 261, a movable plate 262, a biasing member 263, a guide rod 264, and a knob 265. The fixing plate 261 is fixedly mounted on the instrument operation box or integrally formed with the instrument operation box, and includes circular arc-shaped enclosing plates 2611, two ends of the enclosing plates are symmetrically provided with lugs 2612 extending away from each other, the bottom of the enclosing plates is provided with a bottom plate 2613 extending outwards away from the enclosing plates so as to form a large enough supporting surface to support the movable plate. The bottom plate is provided with a mounting hole 2614 for mounting and positioning the lower end of the knob rod part; the two protrusions 2612 are formed with guide bar mounting holes on one end thereof facing the movable plate after assembly, for fixedly mounting the guide bars 264.

The movable plate 262 is movably disposed on the fixed plate, and has a plate shape, including a main body 2621 and protrusions 2622 protruding from both sides of the main body; the shape of the main body is matched with that of the bottom plate of the fixed plate, two holes 2623 are formed on the movable plate for respectively installing the rotating shafts of the delivery rollers, guide rod insertion holes facing the fixed plate are formed on the two protrusions 2622, and one end of the guide rod 264 is movably fitted in the holes, so that the movable plate 262 can move axially along the guide rods relative to the fixed plate. An operation hole 2624 through which the knob shaft portion 2651 extends is formed at a middle position of the movable plate main body.

The knob 265 includes a handle 2652 to be held by hand to rotate the knob, and a rod portion 2651 having a lower end mounted in a mounting hole 2614 formed on the bottom plate and having a protrusion 266 formed at a position corresponding to an operation hole 2624 formed at a middle position of the movable plate main body.

The biasing member 263 is in the form of a coil spring that is fitted over the guide rod 264 when assembled.

In an assembled state, one end of the guide rod 264 is fixed in the guide rod mounting hole of the fixed plate, the other end is axially movably mounted in the guide rod insertion hole of the movable plate, and the helical spring is sleeved on the guide rod and positioned between the projection 2612 of the fixed plate and the projection 2622 of the movable plate. The shaft of the knob 265 extends through the operating aperture 2624 in the movable plate and has its ends rotatably mounted in the mounting apertures 2614 in the base plate. Under the action of the helical spring, the movable plate is biased in a direction away from the fixed plate, so that the delivery roller mounted on the movable plate abuts against the other delivery roller operating in cooperation.

In actual use, when a balloon catheter needs to be placed, the knob is rotated to enable the protrusions on the knob to abut against the hole wall of the operation hole and drive the movable plate to move towards the fixed plate, so that the delivery rollers are far away from each other, the balloon catheter can be placed in a gap between the pair of delivery rollers at the moment, then the knob is rotated reversely to enable the protrusions on the knob to be far away from the hole wall of the operation hole, the movable plate moves away from the fixed plate under the action of the spiral spring, the delivery rollers mounted on the movable plate are driven to approach to the other delivery roller, and the balloon catheter is clamped between the two delivery rollers.

Fig. 9A and 9B schematically illustrate one embodiment of a bias adjustment portion, where fig. 9A is a perspective view of the bias adjustment portion and fig. 9B is a partial sectional view taken along line a-a in fig. 9A.

As shown in fig. 9A and 9B, the bias adjusting portion includes a fixed plate 271, a movable plate 272, a biasing member 273, and a knob, which is the same as the embodiment shown in fig. 8 and is not shown in fig. 9A and 9B for clearly illustrating other constituent elements, is employed in the present embodiment. The fixing plate 271 is fixedly installed on the instrument operation box or integrally formed with the instrument operation box, and includes a U-shaped enclosure plate 2712, a bottom plate 2713 is provided at the bottom of the enclosure plate, the enclosure plate 2712 includes two baffles 2715 oppositely arranged in the direction perpendicular to the moving direction of the enclosure plate, and guide grooves 2716 are formed on the mutually opposite surfaces of the two baffles. A knob mounting hole 2717 is formed on the bottom plate 2713 to mount the lower end of the knob rod part.

The movable plate 272 is in the form of a rectangular plate movably disposed on the fixed plate; two holes 2721 are formed on the movable plate, and are respectively used for mounting the rotating shaft of the delivery roller; guide protrusions 2722 are formed on both side walls of the movable plate 272 in a direction perpendicular to the moving direction of the movable plate, and the guide protrusions 2722 are fitted into the guide grooves 2716 of the two blocking plates of the fixed plate. When assembled, the guide projection of the movable plate is inserted into the guide groove, so that the movable plate can move relative to the fixed plate along the fixed direction, and the guide groove and the guide projection which are jointed with each other form a guide piece. An operation hole 2723, such as a rectangular hole as shown in the drawing, through which the knob shaft extends, is formed at a middle position of the movable plate main body.

The biasing member 273 is in the form of a coil spring which in the assembled state is mounted between the bottom wall of the U-shaped shroud 2712 of the fixed plate and the movable plate so that the movable plate is biased in a direction away from the fixed plate so that the delivery rollers mounted on the movable plate abut the same operating delivery rollers.

Fig. 10 schematically illustrates another embodiment of the bias adjuster, which is substantially the same as the embodiment shown in fig. 9A and 9B except that the operation hole 2725 has an elliptical shape.

Fig. 11 schematically illustrates yet another embodiment of the bias voltage adjustment portion. As shown in fig. 11, the bias adjusting portion includes a fixed plate 281, a movable plate 282, a biasing member 283 and an operating lever 284.

The fixing plate 281 is fixedly installed on or integrally formed with the instrument operation box, and includes a U-shaped enclosure 2812, and the enclosure 2812 includes two baffles 2815 oppositely arranged in a direction perpendicular to the moving direction of the movable plate, and guide slots 2816 are formed on the two baffles. In the illustrated embodiment, the guide slot 2816 is a through slot in a direction perpendicular to the moving direction of the movable plate, but it is obvious to those skilled in the art that a non-through slot may be employed, as in the embodiments illustrated in fig. 9A, 9B and 10.

The movable plate 282 is in the form of a rectangular plate movably disposed on the fixed plate; two holes 2821 are formed on the movable plate for mounting the rotating shaft of the delivering roller respectively; guide protrusions 2822 are formed on two side walls of the movable plate in a direction perpendicular to the moving direction of the movable plate, and the guide protrusions 2822 are matched with the guide grooves 2816 on the two baffles of the fixed plate. When assembled, the guide projection of the movable plate is inserted into the guide groove, so that the movable plate can move relative to the fixed plate along the fixed direction, and the guide groove and the guide projection which are jointed with each other form a guide piece.

The biasing member 283 is in the form of a coil spring which in an assembled state is mounted between the bottom wall of the U-shaped enclosure 2812 of the fixed plate and the movable plate such that the movable plate is biased in a direction away from the fixed plate such that the delivery rollers mounted on the movable plate abut the cooperating delivery rollers.

The lever 284 is connected at one end to the movable plate, extends away from the movable plate, and passes through a hole 2819 formed in a bottom wall 2818 of the U-shaped enclosure 2812.

In actual use, when a balloon catheter needs to be placed, the movable plate can be moved away from the power output shaft by pulling the operating rod, and the balloon catheter can be placed in the gap between the delivery rollers. After the operating rod is loosened, the movable plate moves away from the fixed plate under the action of the spiral spring, so that the delivery rollers mounted on the movable plate are driven to approach the other delivery roller, and the balloon catheter is clamped between the two delivery rollers.

In the embodiment shown in fig. 9A and 9B and fig. 10 and 11, the guide projection is formed on the movable plate and the guide groove is formed on the fixed plate, but it may be reversed, that is, the guide projection is formed on the fixed plate and the guide groove is formed on the movable plate.

According to the technical scheme of the utility model, the balloon catheter power input shaft of the balloon catheter driving device extends along the transverse direction of the instrument operation box, the power input end of the balloon catheter power input shaft extends out from one transverse side of the instrument operation box, and the transmission component is adopted to adapt to the transmission structure between the balloon catheter delivery component and the balloon catheter power input shaft, so that the balloon catheter power input shaft can be connected with a driving source in a power unit arranged on one side of the robot body in a side connection mode, and the instrument operation box can be laterally arranged on one side of the robot body through a connector, thereby solving the problem that the liquid permeates into the power unit body to cause structural part corrosion or electric short circuit in the prior art because the instrument operation box is arranged above the power unit, reducing the whole thickness of the robot by the side connection mode, leading instruments such as the balloon catheter and the like arranged on the instrument operation box to be completely close to the vascular inlet of a patient, the effective use distance of instruments such as a balloon catheter and the like is remarkably increased. Therefore, the utility model discloses technological effect showing has been obtained for prior art.

The present invention has been described above with reference to the accompanying drawings in conjunction with specific embodiments, but this is for illustrative purposes only and the present invention is not limited thereto. Therefore, it is apparent to those skilled in the art that various changes and modifications can be made within the technical spirit and scope of the present invention, and these changes and modifications should be construed as falling within the scope of the present invention, the scope of which is defined by the claims and their equivalents.

Claims (17)

1. A balloon catheter driving device for a vascular interventional surgical robot, the balloon catheter driving device being disposed on an instrument operation box below the instrument operation box, one lateral side of the instrument operation box being laterally connected to a robot body, the balloon catheter driving device including a balloon catheter power input shaft, a transmission assembly, and a balloon catheter delivery assembly, the transmission assembly including a power output shaft, the balloon catheter delivery assembly including delivery rollers disposed in pairs for enabling delivery of a balloon catheter, one delivery roller of the pair of delivery rollers cooperating with each other being mounted on the output shaft and rotating therewith, the power output shaft being disposed perpendicular to the balloon catheter power input shaft extending in a lateral direction of the instrument operation box, the power input end of the balloon catheter control system extends out of the side face of the instrument operation box and is used for being connected with a balloon catheter delivery driving shaft arranged on one side of the robot body.

2. A balloon catheter driving device for a vascular interventional surgical robot as claimed in claim 1, wherein the transmission assembly further comprises an intermediate transmission shaft disposed in parallel with the balloon catheter power input shaft, power of the balloon catheter power input shaft is transmitted to the intermediate transmission shaft via a transmission mechanism, a power output end of the intermediate transmission shaft is provided with a bevel gear engaged with a bevel gear disposed at a power input end of the power output shaft.

3. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 2, wherein the transmission mechanism is a gear transmission mechanism including a first transmission gear in the form of a spur gear provided on a power input end of the balloon catheter power input shaft and a second transmission gear in the form of a spur gear provided on a power input end of the intermediate transmission shaft.

4. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 3, wherein the gear transmission mechanism further includes an intermediate transmission gear in the form of a spur gear installed on an intermediate gear shaft parallel to the balloon catheter power input shaft and engaged with the first and second transmission gears.

5. The balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 2, wherein the transmission mechanism is a belt transmission mechanism including a first pulley provided on a power output end of the balloon catheter power input shaft, a second pulley provided on a power input end of the intermediate transmission shaft, and a transmission belt wound around the first pulley and the second pulley.

6. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 1, wherein the power output end of the balloon catheter power input shaft is provided with a bevel gear which meshes with a bevel gear provided at the power input end of the power output shaft.

7. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 1, wherein the transmission assembly further includes a first intermediate transmission shaft and a second intermediate transmission shaft, the first intermediate transmission shaft being disposed in parallel with the balloon catheter power input shaft, the second intermediate transmission shaft being disposed perpendicularly to the first intermediate transmission shaft, the power of the balloon catheter power input shaft being transmitted to the first intermediate transmission shaft via a transmission mechanism, a power output end of the first intermediate transmission shaft being provided with a bevel gear engaged with the bevel gear disposed at a power input end of the second intermediate transmission shaft;

the transmission assembly is characterized by further comprising a straight gear arranged at the power output end of the second intermediate transmission shaft, the number of the power output shafts is two, the two power output shafts are arranged in parallel with the second intermediate transmission shaft, and straight gears meshed with the straight gears at the power output end of the second intermediate transmission shaft are arranged on the two power output shafts respectively, so that the two power output shafts rotate in the same direction during operation.

8. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 7, wherein the transmission mechanism is a gear transmission mechanism including a first transmission gear in the form of a spur gear provided on a power output end of the balloon catheter power input shaft and a second transmission gear in the form of a spur gear provided on a power input end of the first intermediate transmission shaft.

9. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 8, wherein the gear transmission mechanism further includes an intermediate transmission gear in the form of a spur gear installed on an intermediate gear shaft parallel to the balloon catheter power input shaft and engaged with the first and second transmission gears.

10. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 7, wherein the transmission mechanism is a belt transmission mechanism including a first pulley disposed on a power output end of the balloon catheter power input shaft, a second pulley disposed on a power input end of the first intermediate transmission shaft, and a transmission belt wound around the first pulley and the second pulley.

11. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 1, wherein the transmission assembly further comprises an intermediate transmission shaft disposed perpendicular to the balloon catheter power input shaft, a power output end of the balloon catheter power input shaft being provided with a bevel gear engaged with a bevel gear disposed at a power input end of the intermediate transmission shaft;

the transmission assembly further comprises straight gears arranged at the power output end of the intermediate transmission shaft, the number of the power output shafts is two, and the two power output shafts are respectively provided with the straight gears meshed with the straight gears at the power output end of the intermediate transmission shaft, so that the two power output shafts rotate in the same direction during operation.

12. A balloon catheter drive apparatus for a vascular access surgical robot as claimed in any one of claims 1-11, wherein the balloon catheter delivery assembly further includes a bias adjustment portion for biasing a delivery roller cooperating with a delivery roller mounted on the power take-off shaft in a direction toward the power take-off shaft and operable to move the delivery roller cooperating with the delivery roller mounted on the output shaft in a direction away from the power take-off shaft.

13. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 12, wherein the bias adjusting part includes a fixed plate, a movable plate, a bias resetting member, a guide member and a knob;

the fixing plate is fixedly arranged on the instrument operation box or integrally formed with the instrument operation box, and a positioning hole is formed in the fixing plate;

the movable plate is movably arranged on the fixed plate along the direction facing to or departing from the power output shaft through the guide piece, a delivery roller cooperating with the delivery roller arranged on the power output shaft is arranged on the movable plate, and an operation hole is formed on the movable plate;

the bias resetting piece is arranged between the fixed plate and the movable plate and is used for applying bias to the movable plate towards one side of the power output shaft;

the knob comprises an operating handle part and a rod part, a protrusion is arranged on the rod part, in an assembling state, the end part of the rod part is assembled in the positioning hole, the protrusion on the rod part is located in the operating hole, and the knob can abut against the hole wall of the operating hole when rotating, so that the movable plate deviates from the power output shaft to move.

14. A balloon catheter driving device for a robot for vascular interventional procedures as defined in claim 13, wherein the guide member comprises a pair of guide rods extending in parallel with the moving direction of the movable plate, the pair of guide rods being symmetrically disposed at both sides of the knob, one end of each guide rod being fixed to the fixed plate and the other end thereof being inserted into the hole formed in the movable plate in a clearance fit manner, and the biasing restoring member is a coil spring fitted over the guide rods.

15. The balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 13, wherein the fixed plate includes two blocking plates disposed opposite to each other in a direction perpendicular to a moving direction of the movable plate, guide grooves or guide protrusions are formed on surfaces of the two blocking plates facing each other, and guide protrusions or guide grooves are formed on both side surfaces of the movable plate in a direction perpendicular to the moving direction of the movable plate, the guide grooves or guide protrusions on the blocking plates are engaged with the guide protrusions or guide grooves on the side surfaces of the movable plate, the guide grooves and the guide protrusions engaged with each other constitute the guide, and the biasing return member is a coil spring.

16. A balloon catheter driving device for a vascular interventional surgical robot as set forth in claim 12, wherein the bias adjusting part includes a fixed plate, a movable plate, a bias restoring member, a guide member and an operation rod;

the fixing plate is fixedly arranged on the instrument operation box or integrally formed with the instrument operation box;

the movable plate is movably mounted on the fixed plate in a direction toward or away from the power output shaft through the guide, and a delivery roller cooperating with the delivery roller mounted on the output shaft is mounted on the movable plate;

the bias resetting piece is arranged between the fixed plate and the movable plate and is used for applying bias to the movable plate towards one side of the power output shaft;

one end of the operating rod is connected with the movable plate, and the movable plate can move away from the power output shaft by pulling the operating rod.

17. A balloon catheter driving device for a vascular interventional surgical robot according to claim 16, wherein the fixed plate includes two blocking plates disposed opposite to each other in a direction perpendicular to the moving direction of the movable plate, guide grooves or guide protrusions are formed on surfaces of the two blocking plates facing each other, and guide protrusions or guide grooves are formed on both sides of the movable plate in a direction perpendicular to the moving direction of the movable plate, the guide grooves or guide protrusions on the blocking plates are engaged with the guide protrusions or guide grooves on the sides of the movable plate, the guide grooves and guide protrusions engaged with each other constitute the guide member, and the biasing return member is a coil spring.

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