CN206167036U - Linear drive's parallelly connected surgery robot - Google Patents

Abstract

The utility model relates to a linear drive's parallelly connected surgery robot. The purpose is that the robot that provides should have the characteristics that the precision is high. Technical scheme is: a linear drive's parallelly connected surgery robot, this robot of includes ring shape base, moves platform, operation instrument and three branch, first branch in the three branch is the same with the second branch structure, all, first revolute pair vice including removing, second revolute pair, first connecting rod, third revolute pair, second connecting rod and fourth revolute pair, third branch is vice including removing, first revolute pair, second revolute pair, first connecting rod, third revolute pair and second connecting rod, in every branch, first revolute pair axis is of each other parallel and perpendicular to second revolute pair axis with third revolute pair axis, fourth revolute pair axis in the first branch and the fourth revolute pair axis in the second branch coaxial and first revolute pair axis of perpendicular to and third revolute pair axis, still with all three branches in second revolute pair axis intersect in a fixed point.

Description

A Linear Driven Parallel Surgical Robot

technical field

The utility model relates to a robot for minimally invasive surgery, in particular to a linearly driven parallel robot.

Background technique

In open surgery for a long time, surgeons use scalpels to continuously "create wounds" for patients, and then take measures to heal the wounds as much as possible, which often makes patients fearful and uneasy when facing surgery. How to reduce surgical trauma and bleeding, reduce surgical risks and complications, and shorten recovery time has become the direction of surgical development. In this context, minimally invasive surgery represented by laparoscopy was born and developed rapidly in the past 30 years. Minimally invasive surgery is the use of slender rod-shaped surgical tools inserted into the body through tiny incisions on the surface of the body for surgical operations. Compared with traditional open surgery, it can reduce surgical incisions and surgical scars, shorten recovery time, reduce bleeding and complications, etc.

"A Hybrid Manipulator for Minimally Invasive Surgery" and "A New Hybrid Manipulator for Minimally Invasive Surgery" disclosed in Chinese patent documents can be effectively used in minimally invasive surgery, but the structure needs to be further simplified , the accuracy needs to be further improved, and the cost also needs to be reduced; therefore, further improvement is needed.

Utility model content

The purpose of this utility model is to overcome the shortcomings in the above-mentioned background technology and provide a linearly driven parallel surgical robot. The robot should have the characteristics of compact structure, low control difficulty, high precision and good safety.

The technical solution provided by the utility model is: a linearly driven parallel surgical robot, which is characterized in that: the robot includes a circular base, a moving platform, a surgical tool positioned on the moving platform, and a parallel connection between the base and the moving platform. the three branches between;

Among the three branches, the first branch and the second branch have the same structure, and both include a moving pair, a first rotating pair, a second rotating pair, a first connecting rod, and a third rotating pair sequentially connected between the moving platform and the base. pair, the second connecting rod and the fourth rotating pair; the third branch includes the moving pair connected in turn between the moving platform and the base, the first rotating pair, the second rotating pair, the first connecting rod, the third rotating pair and the fourth rotating pair Two connecting rods; in each branch, the axis of the first rotation pair and the axis of the third rotation pair are parallel to each other and perpendicular to the axis of the second rotation pair; the axis of the fourth rotation pair in the first branch and the fourth rotation in the second branch The secondary axes are coaxial and perpendicular to the first rotary secondary axis and the third rotary secondary axis, and also intersect the second rotary secondary axes in all three branches at a fixed point.

The first rotary joint axis intersects the second rotary joint axis.

The surgical tool is rotatably positioned on the moving platform, the rotation axis coincides with the fourth rotating pair, and is driven by a servo motor fixed on the moving platform.

The beneficial effects of the utility model are: compared with the existing parallel surgical robot, the provided robot adopts a non-linkage design between the first rotating pair and the second rotating pair, which makes the robot structure simpler and more compact; The degree of freedom of the surgical tool is increased, thereby increasing the flexibility of operation, making complex surgical operations simple and safe, with higher surgical precision, greatly reduced costs, and simple control. Therefore, the utility model has important significance for the popularization and application of minimally invasive surgery.

Description of drawings

Fig. 1 is a three-dimensional structure diagram of an embodiment of the utility model.

Fig. 2 is a schematic diagram of the structure of the first branch and the second branch in the embodiment of the utility model.

Fig. 3 is a schematic diagram of the third branch mechanism in the embodiment of the utility model.

Fig. 4 is an enlarged view of the entry point of the surgical tool in the embodiment of the present invention.

detailed description

The utility model will be further described below in conjunction with the accompanying drawings of the description, but the utility model is not limited to the following embodiments.

As shown in FIG. 1 , a linearly driven parallel surgical robot includes a circular base 1 , a moving platform 13 , a surgical tool 2 and three branches.

The three branches are connected between the base and the moving platform in a parallel connection; wherein the first branch and the second branch have the same structure, including the moving pair 3 connected between the moving platform and the base, the first rotating Auxiliary 4, second rotating pair 5, first connecting rod 6, third rotating pair 7, second connecting rod 8 and fourth rotating pair 9; the difference between the third branch and other branches is that there is no fourth rotating pair in the branch .

In the first branch and the second branch, the axis of the first rotating pair 4 and the axis of the third rotating pair 7 are parallel to each other and perpendicular to the axis of the second rotating pair 5 and the axis of the fourth rotating pair 9; in the third branch, the first The axis of the rotating pair 4 and the axis of the third rotating pair 7 are parallel to each other and perpendicular to the axis of the second rotating pair 5 .

The axes of the fourth rotating pair 9 in the first branch and the second branch are coaxial and intersect at a fixed point O with the axes of all the second rotating pairs 5 in the three branches at the same time.

Obviously, the axis of the moving pair in each branch is parallel to the axis of the first rotating pair 4; the axis of the first rotating pair intersects with the axis of the second rotating pair and are perpendicular to each other, acting as a universal hinge.

The surgical tool is positioned on the movable platform and can perform rotational movement relative to the movable platform. The rotation axis coincides with the axis of the fourth rotating pair, and is driven by a servo motor fixed on the movable platform.

The moving pair 3 is driven by a ball screw (omitted in the figure) driven by a servo motor.

The servo motor 10 is fixed on the moving platform 13 through the motor frame 11 .

As shown in Figure 4, a poking card 14 is placed at the incision position of the human body, and the surgical tool is inserted into the body after passing through the poking card. Driven by four motors, the surgical tool has four degrees of freedom, including two swings around the incision position O, movement along the axis of the surgical tool, and rotation of the surgical tool.

Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the utility model and not to limit them; the specific implementation of the utility model is modified or some technical features are equivalently replaced without departing from the technology of the utility model Any scheme in the spirit of the scheme shall be covered by the protection scope of the utility model.

Claims (4)

1. A linearly driven parallel surgical robot is characterized in that: the robot comprises a circular base (1), a moving platform (13), a surgical tool (2) positioned on the moving platform and a parallel connection between the base and the moving platform. Three branches between platforms; The first branch and the second branch in the three branches have the same structure, and both include a moving pair (3), a first rotating pair (4), and a second rotating pair (5) sequentially connected between the moving platform and the base , the first connecting rod (6), the third rotating pair (7), the second connecting rod (8) and the fourth rotating pair (9); the third branch includes a moving pair connected in turn between the moving platform and the base, The first rotating pair, the second rotating pair, the first connecting rod, the third rotating pair and the second connecting rod; in each branch, the axis of the first rotating pair and the axis of the third rotating pair are parallel to each other and perpendicular to the second rotating pair Axis; the axis of the fourth rotary joint in the first branch is coaxial with the fourth rotary joint axis in the second branch and perpendicular to the first rotary joint axis and the third rotary joint axis, and also with the second rotary joint in all three branches The secondary axes intersect at a fixed point (O). 2 . The linearly driven parallel surgical robot according to claim 1 , wherein the axis of the first rotating pair intersects the axis of the second rotating pair. 3 . 3. The linearly driven parallel surgical robot according to claim 2, wherein the surgical tool is rotatably positioned on the moving platform, and the rotation axis coincides with the fourth rotation pair. 4. The linearly driven parallel surgical robot according to claim 3, characterized in that: the surgical tool is driven by a servo motor (10) fixed on the moving platform.