KR20120105888A - Active Universal Joint Apparatus with Multi-Degree of Freedom - Google Patents

Abstract

The universal joint device of the present invention includes a universal joint, an Nth link, an N + 1 link, a pair of first drive wires, and a pair of second drive wires. The annular universal joint having a hollow has a first connecting shaft and a second connecting shaft in directions crossing each other. The Nth link is rotatably connected to both ends of the first connecting shaft, and the N + 1th link is rotatably connected to both ends of the second connecting shaft. The first drive wire is connected to the universal joint in the forward direction and drives the universal joint with respect to the first connecting shaft. The second driving wire passes through the hollow of the universal joint and then connects to the universal joint in a reverse direction through the redirection pulley and drives the universal joint with respect to the second connecting shaft. In order to separate the drive of each axis, the second drive wire may pass through the hollow center of the universal joint or a tube may be used to surround the second wire. By applying it in multiple stages, it is possible to construct a mechanical part of the desired degree of freedom or to secure a large range of motion.

Description

Active Universal Joint Apparatus with Multi-Degree of Freedom}

The present invention relates to a universal joint device, and more particularly, to an active universal joint device having multiple degrees of freedom.

Among robotic technologies, especially in the field of surgical robots, multi-degree-of-freedom surgical tools are used for the purpose of minimally invasive surgery during laparoscopic surgery or other surgical procedures. Minimally invasive surgery is a new concept of inserting a single-passed laparotomy robot through a small incision to perform surgery. It can minimize the damage to the body and improve the accuracy and stability of the surgery to improve survival and quality of life after surgery.

Universal joint structure is known as one of the techniques applied to the joint portion of such a surgical robot.

1 is a schematic view of a universal joint structure according to an example of the prior art. The conventional universal joint structure shown in FIG. 1 uses four wires.

The left and right sides of the joint ring 13 are rotatably connected to the first link 11 by the connecting shaft 18. Vertical shafts 14 are fixed to upper and lower sides of the joint ring 13, and the vertical shafts 14 rotatably penetrate the second link 12. A horizontal shaft 15 is fixed to the second link 12. Vertical drive wires 16 are connected to both ends of the vertical shaft 14, and horizontal drive wires 17 are connected to both ends of the horizontal axis 15, respectively. The vertical drive wire 16 drives the joint ring 13 with respect to the connecting shaft 18 by pulling one of both ends of the vertical shaft 14. The horizontal drive wire 17 drives the second link 12 with respect to the vertical axis 14 by pulling one of both ends of the horizontal axis 15.

However, in the conventional universal joint structure, the length of the horizontal drive wire 17 changes slightly according to the movement of the vertical axis 14. Therefore, there is a problem in that the magnitude of the torque transmitted to the vertical axis 14 and the horizontal axis 15 are different from each other due to the difference in the wire connection radius.

2 is a schematic diagram of a universal joint structure according to another example of the prior art. The conventional universal joint structure shown in FIG. 2 uses three wires.

The joint ring 23 is rotatably connected to the first link 21 by a first axis and rotatably connected to the second link 22 by a second axis that intersects the first axis. Three drive wires 24 are connected to the second link 22 through the first link 21. The three drive wires 24 drive the joint ring 23 in the θ direction with respect to the first axis and in the δ direction with respect to the second axis.

However, in the conventional universal joint structure, since the driving of the first axis and the second axis are coupled, there is a problem that control is not easy. For this reason, it is very difficult to implement a multi-stage joint structure to increase the degree of freedom or to secure a large angle of motion range.

SUMMARY OF THE INVENTION An object of the present invention is to provide a multi-degree of freedom active universal joint device that can improve the control performance by maintaining the maximum torque transmitted to each axis by preventing the length change of the drive wire of the other axis according to the movement of one axis. It is for.

Another object of the present invention is to provide a multi-degree of freedom active universal joint device that is easy to control by solving the coupling problem of two axes and allowing independent control of each axis.

Still another object of the present invention is to provide an active universal joint device having a multiple degree of freedom capable of efficient force transmission and ensuring a high degree of freedom.

Another object of the present invention is to apply in two or more stages to enable the independent control of the axis in the same direction by overcoming the limitation of the movement range and multi-degree of freedom active universal joint device that can secure the movement range at a large angle It is to provide.

In order to achieve these objects, the multi-degree of freedom active universal joint device provided by the present invention includes a universal joint, an N-link, an N + 1 link, a pair of first drive wires, and a pair of second drive wires. It is configured by.

The universal joint is formed in an annular shape having a hollow, and has a first connecting shaft and a second connecting shaft. The first connecting shaft and the second connecting shaft are formed in the direction crossing each other on the outer surface of the annular. The N-th link has a pair of shaft connections such that both ends of the first connection shaft are rotatably connected. The N + 1th link has a pair of shaft connections such that both ends of the second connection shaft are rotatably connected. The pair of first driving wires are drawn out of the N-th link and connected to the universal joint in the forward direction, and drive the universal joint with respect to the first connecting shaft. The pair of second driving wires are drawn out of the N-th link, pass through the hollow of the universal joint, and are connected to the universal joint in a reverse direction, and drive the universal joint with respect to the second connection shaft.

In the multi-degree of freedom active universal joint device according to the present invention, the first drive wire can be connected in the forward direction near the second connecting shaft of the universal joint, the second drive wire is the first connection of the universal joint It can be connected in the reverse direction near the axis.

In addition, the multi-degree of freedom active universal joint device according to the present invention may further include a diverting pulley. The diverting pulley is installed in the N + 1 link and redirects the direction of the second driving wire passing through the hollow of the universal joint toward the universal joint.

In this case, the diverting pulley preferably has a size satisfying the minimum radius condition of the second driving wire.

In the multi-degree of freedom active universal joint device as described above, the second drive wire may pass through the center of the hollow when passing through the hollow of the universal joint. In this case, the multi-degree of freedom active universal joint device may further include a wire guide, the wire guide is installed in at least one of the N-th link and the N +1 link so that the second drive wire is the hollow Guide through the center of the.

In addition, the multi-degree of freedom active universal joint device as described above may further include a tube fixing portion and an inflexible tube. The tube fixing part is installed in the N + 1th link. The non-stretchable tube is fixed to the tube fixing part and positioned inside the hollow of the universal joint to surround the second drive wire passing through the hollow of the universal joint.

On the other hand, in order to achieve the above object, the present invention may provide a multi-degree of freedom active universal joint device having the following configuration.

The n-th universal joint is formed in an annular shape having a hollow, and has a first connecting axis and a second connecting axis formed in a direction crossing each other on the outer surface of the annular shape. The n + 1 universal joint is formed in an annular shape having a hollow, and has a third connecting axis and a fourth connecting axis formed in a direction crossing each other on the outer surface of the annular shape.

The Nth link has a pair of shaft connections such that both ends of the first connecting shaft are rotatably connected. The N + 1 link has a pair of shaft connecting portions at one end thereof so that both ends of the second connecting shaft are rotatably connected, and a pair of shaft connecting portions at the other end thereof so that both ends of the third connecting shaft are rotatably connected. The N + 2th link has a pair of shaft coupling parts so that both ends of the fourth coupling shaft can be rotatably connected.

The pair of first driving wires are drawn out of the N-th link and connected to the n-th universal joint in the forward direction, and drive the n-th universal joint with respect to the first connection shaft. The pair of second driving wires are drawn out of the N-th link and pass through the hollow of the n-th universal joint, and then are connected to the n-th universal joint in a reverse direction, and connect the n-th universal joint with respect to the second connection shaft. Drive. The pair of third driving wires are drawn out of the N + 1 link and forwardly connected to the n + 1 universal joint, and drive the n + 1 universal joint with respect to the third connecting shaft. The pair of fourth driving wires are drawn out of the N + 1 link, passes through the hollow of the n + 1 universal joint, and then connects to the n + 1 universal joint in a reverse direction, with respect to the fourth connection shaft. The n + 1 universal joint is driven.

In such a multiple degree of freedom active universal joint device, the nth universal joint and the n + 1 universal joint may be driven independently of each other, and the n + 1 universal joint may be driven dependently on the nth universal joint. Can be.

According to the present invention, two pairs of drive wires can be connected to the universal joint in opposite directions to independently control two axes, and the second drive wire passes through the hollow center of the universal joint to separate the drive of each axis. Can be used or a tube can be used to wrap the second wire. Therefore, it is possible to prevent the change of the length of the drive wire of the other axis according to the movement of one axis, and to improve the control performance by maintaining the torque transmitted to each axis as well as to solve the coupling problem of the two axes, respectively. Independent control of the axis is possible.

In addition, the universal joint device according to the present invention can efficiently transmit the force and ensure a high degree of freedom, and can be applied in two or more stages to control the axis in the same direction can overcome the limitations of the movement range and The range of motion can be secured at an angle.

1 is a schematic diagram of a universal joint structure according to an example of the prior art.
2 is a schematic diagram of a universal joint structure according to another example of the prior art.
3 is a conceptual diagram of a universal joint device according to a first embodiment of the present invention.
4 is a perspective view of the universal joint device according to the first embodiment of the present invention.
5 is a perspective view of a universal joint device according to a second embodiment of the present invention.
6 is a perspective view of the universal joint device according to the first application example of the present invention.
7 is a perspective view of a universal joint device according to a second application of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the embodiments, descriptions that are well known in the technical field to which the present invention pertains or are not directly related to the present invention may be omitted so as to clearly convey the core of the present invention without blurring them.

On the other hand, in the accompanying drawings, some components are exaggerated, omitted, or schematically illustrated, and the size of each component does not entirely reflect the actual size. Like reference numerals refer to like or corresponding elements throughout the accompanying drawings.

3 is a conceptual diagram of the universal joint device according to the first embodiment of the present invention, and FIG. 4 is a perspective view of the universal joint device according to the first embodiment of the present invention.

3 and 4, the universal joint device 100 of the first embodiment includes a universal joint 110, an Nth link 121, an N + 1 link 122, and a pair of first driving wires ( 131, and a pair of second driving wires 132.

Universal joint 110 is made of an annular having a hollow. The first connection shaft 111 and the second connection shaft 112 are formed on the outer surface of the annular shape in a direction crossing each other (that is, crosswise).

The N-th link 121 has a pair of shaft connecting portions 121a. A shaft insertion hole is drilled in the shaft connecting portion 121a, and both ends of the first connecting shaft 111 are inserted into the shaft insertion hole, so that the first connecting shaft 111 of the universal joint 110 is connected to the N-th link 121. It is connected rotatably.

Similarly, the N + 1th link 122 also has a pair of shaft coupling portions 122a, and shaft insertion holes are drilled in the shaft coupling portion 122a. Both ends of the second connecting shaft 112 are inserted into the shaft insertion hole so that the second connecting shaft 112 of the universal joint 110 is rotatably connected to the N + 1th link 122.

The reason for using the 'N' and 'N + 1' in the name of the link in this specification is to indicate that the universal joint device 100 of the present invention is not limited to the coupling between specific links. In addition, it also indicates that the universal joint device 100 of the present invention can be applied in multiple stages. Application examples in this case will be described later with reference to FIGS. 6 and 7.

The pair of first driving wires 131 are drawn out of the N-th link 121 and connected to the second connecting shaft 112 of the universal joint 110 in the forward direction, respectively. Accordingly, the first driving wire 131 drives the universal joint 110 with respect to the first connecting shaft 111 by selectively pulling both ends of the second connecting shaft 112.

On the other hand, the pair of second driving wires 132 are drawn out of the N-th link 121 to pass through the hollow of the universal joint 110, and then close to the first connecting shaft 111 of the universal joint 110, respectively. Connect in the reverse direction. Accordingly, the second driving wire 132 drives the universal joint 110 with respect to the second connecting shaft 112 by selectively pulling both ends of the first connecting shaft 111.

For reverse connection of the second drive wire 132, the universal joint device 100 further includes a diverting pulley 140. The redirection pulley 140 is installed in the N + 1 link 122 and converts the direction of the second driving wire 132 passing through the hollow of the universal joint 110 toward the universal joint 110.

The turning pulley 140 preferably has a size satisfying the minimum radius condition of the second driving wire 132. That is, the turning pulley 140 may be formed to have a size sufficient to ensure the minimum radius of curvature allowed by the material of the wire so as not to break or deteriorate the wire.

Meanwhile, although omitted in the drawing, the pair of first driving wires 131 and the pair of second driving wires 132 are respectively connected to the driving motor and driven. The driving motors may be installed on the N-th link 121, but are usually located on the first link side. In any case, the respective wires 131 and 132 are drawn out of the N-th link 121 and directed to the universal joint 110.

As described above, the universal joint device 100 of the present invention may independently control two axes by connecting the first drive wire 131 and the second drive wire 132 to the universal joint 110 in opposite directions. To help. In particular, in the first embodiment, the second drive wire 132 passes through the hollow center of the universal joint 110 to separate the drive of each axis. Therefore, even if the first driving wire 131 drives the universal joint 110 with respect to the first connecting shaft 111, the second driving wire 132 is not affected by the length change does not occur or minimize.

In order to allow the second drive wire 132 to pass through the center of the hollow when passing through the hollow of the universal joint 110, the universal joint device 100 of the first embodiment has a wire guide 150 as shown in FIG. 3. It may further include. The wire guide 150 is installed in at least one (preferably both) of the N-th link 121 and the N + 1 th link 122 so that the second drive wire 132 passes through the hollow center. To guide.

On the other hand, in the second embodiment of the present invention, a means different from the first embodiment is used to separate the drive of each axis. The second embodiment will be described below.

5 is a perspective view of a universal joint device according to a second embodiment of the present invention.

Referring to FIG. 5, the universal joint device 100 of the second embodiment includes a non-stretchable tube 160 and a tube fixing part 161. The non-stretchable tube 160 is positioned inside the hollow of the universal joint 110 to surround the second drive wire 132 passing through the hollow of the universal joint 110. The tube fixing part 161 is installed in the N + 1th link 122 to fix the non-stretchable tube 160.

As such, since the non-stretchable tube 160 is positioned inside the hollow of the universal joint 110 and the second drive wire 132 is protected by the non-stretchable tube 160, the first drive wire 131 is connected to the first connection. Even when the universal joint 110 is driven with respect to the shaft 111, the length change of the second driving wire 132 does not occur or is minimized. To this end, the non-stretchable tube 160 does not necessarily need to be positioned at the hollow center of the universal joint 110, but is only required to surround the second driving wire 132 while being positioned inside the hollow of the universal joint 110.

On the other hand, as mentioned above, the universal joint device 100 of the present invention can be applied in multiple stages to configure the mechanism of the desired degree of freedom. This example will be described below.

6 is a perspective view of the universal joint device according to the first application example of the present invention.

Referring to FIG. 6, the first universal joint 110-1 connects the first link 121 and the second link 122, and the second universal joint 110-2 is connected to the second link 122. The third link 123 is connected, and the third universal joint 110-3 connects the third link 123 and the fourth link 124.

Each of the universal joints 110-1, 110-2, and 110-3 is the same as the universal joint 110 described above, and thus redundant description thereof will be omitted. In addition, each of the links 121, 122, 123, and 124 corresponds to the aforementioned N-th link 121 and the N-th + 1 link 122. Each link shown in FIG. 6 is formed on both ends of the elongated cylindrical mechanism of the link structure described above in FIGS. In this application example, a cylindrical mechanism and the link structure of both ends are called links.

The connecting shaft of the first universal joint 110-1 is connected to the first connecting shaft and the second connecting shaft, and the connecting shaft of the second universal joint 110-2 is connected to the third connecting shaft and the fourth connecting shaft and the third universal joint 110. When the connecting shaft of -3) is referred to as the fifth connecting shaft and the sixth connecting shaft, the first link 121 and the second link 122 are connected to the first connecting shaft and the second connecting member of the first universal joint 110-1. The second link 122 and the third link 123 are respectively connected to the third and fourth connecting shafts of the second universal joint 110-2, and the third link 123. And the fourth link 124 are connected to the fifth and sixth connecting shafts of the third universal joint 110-3, respectively.

The pair of first drive wires are connected in a forward direction to the first universal joint 110-1 to drive the first universal joint 110-1 with respect to the first connecting shaft, and the pair of second drive wires are formed in a first manner. 1 Connects to the universal joint 110-1 in the reverse direction to drive the first universal joint 110-1 with respect to the second connecting shaft. Thus, the first universal joint 110-1 provides two degrees of freedom. Similarly, the pair of third drive wires are connected in the forward direction to the second universal joint 110-2 to drive the second universal joint 110-2 with respect to the third connecting shaft, and the pair of fourth drive wires Is connected in a reverse direction to the second universal joint 110-2 to drive the second universal joint 110-2 with respect to the fourth connecting shaft. Thus, the second universal joint 110-2 also provides two degrees of freedom. In addition, the pair of fifth driving wires are connected to the third universal joint 110-3 in the forward direction to drive the third universal joint 110-3 with respect to the fifth connecting shaft, and the pair of sixth driving wires Connects to the third universal joint 110-3 in the reverse direction to drive the third universal joint 110-3 with respect to the sixth connecting shaft. Accordingly, the third universal joint 110-3 also provides two degrees of freedom. As a result, the universal joint device illustrated in FIG. 6 provides six degrees of freedom.

As such, when the universal joint device of the present invention is configured in multiple stages to drive each of the universal joints independently of each other, efficient power transmission is possible and high degrees of freedom can be ensured.

In addition, by applying the universal joint device 100 of the present invention in two or more stages it may be controlled dependently. This example will be described below.

7 is a perspective view of a universal joint device according to a second application of the present invention.

Referring to FIG. 7, two universal joints 110-1 and 110-2 connect the first link 121 and the second link 122, and the second link 122 and the third link 123, respectively. do. The structures of the universal joints 110-1 and 110-2 and the links 121, 122, and 123 are the same as described above.

In the present application example, the rear universal joint 110-2 connecting the second link 122 and the third link 123 may have a front end universal joint 110 connecting the first link 121 and the second link 122. Driven by -1).

That is, the rear universal joint 110-2 when the pair of first driving wires connected to the front universal joint 110-1 in the forward direction drives the front universal joint 110-1 with respect to the first connecting shaft. The pair of third drive wires connected in the forward direction to the rear end drive the universal joint 110-2 at the rear end with respect to the third connecting shaft in the same direction as the first connecting shaft. Similarly, when a pair of second drive wires connected backwards to the front universal joint 110-1 drives the front universal joint 110-1 with respect to the second connecting shaft, the rear universal joint 110-2 is connected. The pair of fourth driving wires connected in the reverse direction also drive the rear universal joint 110-2 with respect to the fourth connecting shaft in the same direction as the second connecting shaft.

The universal joint device consisting of a single stage generally has a limited range of motion. Therefore, if the universal joint device is applied in two or more stages as in the present application example, and the control is performed dependent on the axes in the same direction, it is possible to overcome the limitation of the movement range and to secure the movement range at a large angle. For example, if the universal joint device in one stage has a rotation radius of 45 degrees, the two stages can be driven at an angle of 90 degrees.

The multi-degree of freedom active universal joint device of the present invention described above is not limited to the field of surgical robot can be utilized in mechanisms of various fields.

The embodiments of the present invention disclosed in the present specification and drawings are intended to be illustrative only and not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100: universal joint device 110: universal joint
111, 112: connecting shaft 121, 122: link
121a and 122a: shaft connecting portions 131 and 132: drive wire
140: direction change pulley 150: wire guide
160: non-stretch tube 161: tube fixing portion

Claims (8)

Universal joint having an annular having a hollow, having a first connecting shaft and a second connecting shaft formed in a direction crossing each other on the outer surface of the annular;
An N-th link having a pair of shaft connections such that both ends of the first connecting shaft are rotatably connected;
An N + 1 link having a pair of shaft connections such that both ends of the second connecting shaft are rotatably connected;
A pair of first driving wires drawn out of the N-th link and connected to the universal joint in a forward direction, and driving the universal joint with respect to the first connecting shaft;
A pair of second driving wires drawn out of the N-th link and passing through the hollow of the universal joint and connected to the universal joint in a reverse direction, and driving the universal joint with respect to the second connection shaft;
Multi-degree of freedom active universal joint device comprising a. The method according to claim 1,
The first drive wire is connected to the vicinity of the second connecting shaft of the universal joint in the forward direction, the second drive wire is connected to the vicinity of the first connecting shaft of the universal joint in the reverse direction Active universal joint device. The method according to claim 1,
A reversing pulley installed on the N + 1 link and shifting the direction of the second driving wire passing through the hollow of the universal joint toward the universal joint;
Multi-degree of freedom active universal joint device further comprises. The method according to claim 3,
The diverting pulley has an active universal joint device having a degree of freedom characterized in that it has a size that satisfies the minimum radius of the second drive wire. The method according to any one of claims 1 to 4,
And the second drive wire passes through the center of the hollow when passing through the hollow of the universal joint. The method according to claim 5,
A wire guide installed at at least one of the N-th link and the N-th +1 link to guide the second driving wire through the center of the hollow;
Multi-degree of freedom active universal joint device further comprises. The method according to any one of claims 1 to 4,
A tube fixing part installed at the N + 1th link;
A non-stretchable tube fixed to the tube fixing part and positioned inside the hollow of the universal joint to surround the second driving wire passing through the hollow of the universal joint;
Multi-degree of freedom active universal joint device further comprises. An n-th universal joint having an annular shape having a hollow and having a first connecting shaft and a second connecting shaft formed on the outer surface of the annular shape in a direction crossing each other;
An n + 1 universal joint having an annular shape having a hollow, and having a third connecting axis and a fourth connecting axis formed on the outer surface of the annular shape in a direction crossing each other;
An N-th link having a pair of shaft connections such that both ends of the first connecting shaft are rotatably connected;
An N + 1 link having a pair of shaft connecting portions at one end thereof so that both ends of the second connecting shaft are rotatably connected, and having a pair of shaft connecting portions at the other ends thereof so that both ends of the third connecting shaft are rotatably connected;
An N + 2 link having a pair of shaft connections such that both ends of the fourth connecting shaft are rotatably connected;
A pair of first drive wires drawn out of the N-th link and connected to the n-th universal joint in a forward direction and for driving the n-th universal joint with respect to the first connection shaft;
A pair of second drives drawn out from the N-th link and passing through the hollow of the n-th universal joint and connected to the n-th universal joint in a reverse direction, and driving the n-th universal joint with respect to the second connection shaft; wire;
A pair of third driving wires drawn out from the N + 1 link and connected to the n + 1 universal joint in a forward direction, and driving the n + 1 universal joint with respect to the third connecting shaft;
It is drawn out of the N + 1 link and passes through the hollow of the n + 1 universal joint. Then, the n + 1 universal joint is connected to the n + 1 universal joint in a reverse direction. A pair of fourth driving wires to drive;
Multi-degree of freedom active universal joint device comprising a.

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