KR102726186B1 - Surgical flexible drill bit manufacturing method - Google Patents

Abstract

The present invention relates to a method for manufacturing a surgical flexible drill bit, which is implemented to be capable of manufacturing a surgical drill bit capable of banding, comprising: a component joining step of joining each component of a surgical flexible drill bit; a heating step of heating the surgical flexible drill bit manufactured by joining the components by the component joining step; a cooling step of cooling the surgical flexible drill bit heated by the heating step; a defect checking step of checking whether the surgical flexible drill bit is defective; and a packaging step of packaging the surgical flexible drill bit confirmed to be a good product.

Description

{Surgical flexible drill bit manufacturing method}

The present invention relates to a method for manufacturing a surgical flexible drill bit, and more particularly, to a method for manufacturing a surgical flexible drill bit that is capable of manufacturing a bandable surgical drill bit.

In many surgical procedures or therapies, it is desirable to provide one or more tubular holes in the patient's bone. For example, dental implants or cochlear implants are typically installed into holes provided in the jaw or other bone and are then firmly connected to the bone. Or, in orthopedic applications, a support structure, such as a metal plate, or a replacement, such as an artificial joint, is often screwed into the associated bone, with the screws provided in pre-drilled holes in the bone. Or, in other applications, it is preferred to drill holes in the mastoid process of the temporal bone.

Surgical drills are commonly used to provide holes in a bone. These drills typically include a main unit having a drive and a hand piece. The hand piece typically has a connector on which a drill bit can be rotatably mounted. These drill bits often include a longitudinal body having a sharp distal end and a proximal end formed as a shaft. For mounting, the shaft can be clamped to the connector of the hand piece. At the distal end of the body, a plurality of cutting faces are typically formed into spiral flutes extending around the body along its axis.

Meanwhile, the background technology described above is technical information that the inventor possessed for deriving the present invention or acquired during the process of deriving the present invention, and cannot necessarily be considered as publicly known technology disclosed to the general public prior to the application of the present invention.

Korean Patent Publication No. 10-2018-0104101 (Published on September 19, 2018)

One aspect of the present invention provides a method for manufacturing a surgical flexible drill bit, which is implemented to enable the manufacturing of a surgical drill bit capable of being banded.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

A method for manufacturing a surgical flexible drill bit according to one embodiment of the present invention comprises: a component joining step for joining each component of a surgical flexible drill bit; a heating step for heating the surgical flexible drill bit manufactured by joining the components by the component joining step; a cooling step for cooling the surgical flexible drill bit heated by the heating step; a defect checking step for checking whether the surgical flexible drill bit is defective; and a packaging step for packaging the surgical flexible drill bit confirmed to be a good product.

In one embodiment, each component of the surgical flexible drill bit includes: a shank portion installed in a surgical drill device; a guide portion having a diameter larger than that of the shank portion and installed at a front end of the shank portion; a first extension portion extending from a front end of the guide portion; a second extension portion spaced apart from the first extension portion; a bending portion installed between the first extension portion and the second extension portion and configured to transmit torque transmitted from the first extension portion to the second extension portion while being bendable by an external force; and a cutting portion installed at a front end of the second extension portion and having a blade formed to perform a perforation process.

In one embodiment, a method for manufacturing a surgical flexible drill bit according to another embodiment of the present invention may further include a foreign substance removal step of removing foreign substances attached to the surgical flexible drill bit that has progressed to the cooling step using a foreign substance removal device.

In one embodiment, the foreign substance removal device may include: a delivery tube formed of a cylindrical tube shape, which is disposed between two delivery devices that move the surgical flexible drill bit and has an inner diameter identical to a largest diameter portion of the surgical flexible drill bit so as to allow the surgical flexible drill bit to pass through the delivery tube during movement; a bit insertion guide portion installed at an inlet of the delivery tube into which the surgical flexible drill bit is inserted and moves the surgical flexible drill bit entering the delivery tube forward along an inner space of the delivery tube; a bit discharge guide portion installed at an outlet of the delivery tube through which the surgical flexible drill bit is discharged and discharges the surgical flexible drill bit moved along the delivery tube by the bit insertion guide portion from the delivery tube; and a rotating cleaning portion that removes foreign substances attached to the surgical flexible drill bit while rotating along an inner surface of the delivery tube.

In one embodiment, the bit insertion guide unit may include an upper guide roller unit installed at the upper end of the inlet of the delivery tube through which the surgical flexible drill bit is inserted to move the surgical flexible drill bit entering the delivery tube forward along the internal space of the delivery tube; and a lower guide roller unit installed at the lower end of the inlet of the delivery tube through which the surgical flexible drill bit is inserted while facing the upper guide roller unit to move the surgical flexible drill bit entering the delivery tube forward along the internal space of the delivery tube.

In one embodiment, the upper induction roller section may include: an upper mounting groove formed on an inner surface of an upper portion of an inlet of the delivery tube; a roller housing mounted in the upper mounting groove; a contact spring installed on the inner side of the upper mounting groove to support the roller housing; and a contact roller rotatably connected to the roller housing to be rotatably driven to be in contact with the surgical flexible drill bit entering the delivery tube and to move the surgical flexible drill bit forward.

In one embodiment, the roller housing comprises: a housing body supported by the contact spring and secured in the upper fixing groove; a fluid tank disposed along the inner side of the contact spring to support the housing body in the upper fixing groove, and supplying fluid contained in an internal space while contracting as the housing body is inserted into the upper fixing groove; a first wing rotatably connected to one side of the lower end of the housing body exposed from the upper fixing groove to support one side of the contact roller; a second wing rotatably connected to the other side of the lower end of the housing body exposed from the upper fixing groove while facing the first wing to support the other side of the contact roller; a first cylinder spaced inwardly from a connection position between the first wing and the housing body to support between the first wing and the housing body, and extending as fluid is supplied from the fluid tank to spread the first wing in a direction away from the second wing; and a second cylinder, spaced inwardly from a connection position between the second wing and the housing body and supporting between the second wing and the housing body, and extending as fluid is supplied from the fluid tank to spread the second wing in a direction away from the first wing.

In one embodiment, the contact roller comprises: a first disc having a circular flat plate shape and arranged on an inward surface of the first wing; a second disc having a circular flat plate shape and arranged on an inward surface of the second wing; a first rotational shaft extending from a center of the inward surface of the first disc facing the second disc; a second rotational shaft extending from a center of the inward surface of the second disc facing the first disc and having a front end inserted into an extension mounting groove formed at a front end of the first rotational shaft; a variable cylinder installed on the second rotational shaft, the cylinder rod being installed on the inner side of the extension mounting groove, and exposing the cylinder rod as fluid is supplied from the fluid tank to expose the second rotational shaft from the extension mounting groove to increase a gap between the first plate and the second disc; The invention may include: a first connecting shaft installed at the center of an outward surface of the first plate and rotatably connected to an inward surface of the first wing through a universal joint structure to support the first plate; a second connecting shaft installed at the center of an outward surface of the second plate and rotatably connected to an inward surface of the second wing through a universal joint structure to support the second plate; a driving motor installed at the center of an inward surface of the second wing to support the second connecting shaft and to rotate the second connecting shaft; and a roller tube formed in a ring-shaped tube shape and installed along the circumference of the first rotational axis and the second rotational axis between the first plate and the second plate to be closely seated on the surgical flexible drill bit, the width of which increases as the gap between the first plate and the second plate increases, and which expands as fluid is supplied from the fluid tank.

In one embodiment, the rotary cleaning unit may include: a ring mounting groove formed to extend along an inner surface of the transmission tube; a rotary ring formed in a circular ring shape and rotatably connected to the ring mounting groove; a ring driving gear installed to be rotatably driven in the ring mounting groove and connected to gear teeth formed along an outer surface of the rotary ring by a gear engagement so as to be rotatably driven by a rotary driving device to rotate the rotary ring in a forward or reverse direction; and a cleaning brush installed along the inner surface of the rotary ring to rotate together with the rotation of the rotary ring and to remove foreign substances attached to the surgical flexible drill bit.

According to one aspect of the present invention described above, a surgical drill bit capable of banding can be manufactured.

The effects of the present invention are not limited to the effects mentioned above, and various effects may be included within a range obvious to those skilled in the art from the contents described below.

FIG. 1 is a flowchart illustrating a method for manufacturing a surgical flexible drill bit according to one embodiment of the present invention.
FIG. 2 is a drawing showing a surgical flexible drill bit manufactured by a method for manufacturing a surgical flexible drill bit according to one embodiment of the present invention of FIG. 1.
FIG. 3 is a flowchart illustrating a method for manufacturing a surgical flexible drill bit according to another embodiment of the present invention.
Figures 4 and 5 are drawings showing a foreign substance removal device used in the present invention.
Fig. 6 is a drawing showing the bit insertion induction part of Fig. 5.
Figures 7 and 8 are drawings showing the roller housing of Figure 6.

The detailed description of the invention set forth below refers to the accompanying drawings which illustrate, by way of example, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the invention, while different from one another, are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention. It should also be understood that the positions or arrangements of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly so described. Like reference numerals in the drawings designate the same or similar functionality throughout the several aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

FIG. 1 is a flowchart illustrating a method for manufacturing a surgical flexible drill bit according to one embodiment of the present invention.

Referring to FIG. 1, a method for manufacturing a surgical flexible drill bit according to one embodiment of the present invention first combines each component of a surgical flexible drill bit (10) (i.e., a shank portion (11), a guide portion (12), a first extension portion (13), a second extension portion (14), a banding portion (15), and a cutting portion (16), etc.) (S110).

For heat treatment of the surgical flexible drill bit (10) manufactured by the combination step (S110), a preset temperature (e.g., 740 to 880°C, etc.) is heated (S120).

The surgical flexible drill bit (10) heated by the heating step (S120) is cooled (S130).

Check whether the surgical flexible drill bit (10) is defective (S140).

A surgical flexible drill bit (10) confirmed to be of good quality is packaged (S150).

A method for manufacturing a surgical flexible drill bit according to one embodiment of the present invention having the steps described above can manufacture a surgical drill bit capable of being banded.

FIG. 2 is a drawing showing a surgical flexible drill bit manufactured according to the present invention.

Referring to FIG. 2, a surgical flexible drill bit (10) manufactured by the present invention includes a shank portion (11), a guide portion (12), a first extension portion (13), a second extension portion (14), a banding portion (15), and a cutting portion (16).

The shank part (11) is installed in a surgical drill device (not shown in the drawing for convenience of explanation) and transmits the rotational torque transmitted from the surgical drill device to the guide part (12).

The guide portion (12) is formed with a diameter larger than that of the shank portion (11) and is installed at the front end of the shank portion (11).

The first extension part (13) is formed by extending from the front end of the guide part (12).

The second extension (14) is positioned apart from the first extension (13).

The banding portion (15) is installed between the first extension portion (13) and the second extension portion (14) and is configured to transmit torque transmitted from the first extension portion (13) to the second extension portion (14) while being capable of being bent by an external force.

The cutting part (16) is installed at the front end of the second extension part (14) and a blade for perforating is formed.

FIG. 3 is a flowchart illustrating a method for manufacturing a surgical flexible drill bit according to another embodiment of the present invention.

Referring to FIG. 3, a method for manufacturing a surgical flexible drill bit according to another embodiment of the present invention removes foreign substances attached to a surgical flexible drill bit (10) that has progressed to the cooling step using a foreign substance removal device (20) (S130-1).

A method for manufacturing a surgical flexible drill bit according to another embodiment of the present invention having steps as described above can improve the manufacturing quality of a surgical flexible drill bit (10) by removing foreign substances such as dust or burrs that may be attached to a surgical flexible drill bit (10) during the manufacturing process of the surgical flexible drill bit (10) using a foreign substance removal device (20) described below in FIG. 4.

Figures 4 and 5 are drawings showing a foreign substance removal device used in the present invention.

Referring to FIGS. 4 and 5, the foreign substance removal device (20) includes a delivery tube (100), a bit insertion guide unit (200), a bit discharge guide unit (300), and a rotating cleaning unit (400).

The delivery tube (100) is placed between two transfer devices (30) that move the surgical flexible drill bit (10), and is formed in a cylindrical tube shape that forms an inner diameter identical to the largest diameter portion of the surgical flexible drill bit (10) so that the surgical flexible drill bit (10) can pass through it while being moved.

The bit insertion guide (200) is installed at the entrance of a delivery tube (100) into which a surgical flexible drill bit (10) is inserted, and moves the surgical flexible drill bit (10) entering the delivery tube (100) forward along the internal space of the delivery tube (100).

The bit discharge guide unit (300) is installed at the outlet of the delivery tube (100) through which the surgical flexible drill bit (10) is discharged, and discharges the surgical flexible drill bit (10) moved along the delivery tube (100) by the bit insertion guide unit (200) from the delivery tube (100).

The rotating cleaner (400) removes foreign substances attached to the surgical flexible drill bit (10) while rotating along the inner surface of the delivery tube (100).

In one embodiment, the rotary cleaner (400) may include a ring mounting groove (410), a rotary ring (420), a ring driving gear (430), and a cleaning brush (440).

The ring mounting groove (410) is formed to extend along the inner surface of the transmission tube (100).

The rotating ring (420) is formed in a circular ring shape and is installed so as to be rotatable in the ring mounting groove (410).

The ring drive gear (430) is installed so as to be rotatably driven in the ring mounting groove (410) and is connected by gear engagement to the gear teeth formed along the outer surface of the rotating ring (420), and is rotatably driven by a rotational driving device such as a step motor (not shown in the drawing for convenience of explanation) to drive the rotating ring (420) in the forward or reverse direction.

The cleaning brush (440) is installed along the inner surface of the rotating ring (420) and rotates along with the rotating ring (420) to remove foreign substances attached to the surgical flexible drill bit (10).

A foreign substance removal device (20) having a configuration as described above can improve the manufacturing quality of a surgical flexible drill bit (10) by removing foreign substances such as dust or burrs that may be attached to a surgical flexible drill bit (10) during the manufacturing process of the surgical flexible drill bit (10).

Fig. 6 is a drawing showing the bit insertion induction part of Fig. 5.

Referring to FIG. 6, the bit insertion induction unit (200) includes an upper induction roller unit (210) and a lower induction roller unit (220).

The upper induction roller part (210) is installed at the upper end of the entrance of the delivery tube (100) into which the surgical flexible drill bit (10) is inserted, and moves the surgical flexible drill bit (10) entering the delivery tube (100) forward along the internal space of the delivery tube (100).

In one embodiment, the upper induction roller portion (210) may include an upper mounting groove (211), a roller housing (500), a contact spring (212), and a contact roller (600).

The upper mounting groove (211) is formed on the inner surface of the upper portion of the inlet of the transmission tube (100).

The roller housing (500) is mounted in the upper mounting groove (211) of the chant.

The contact spring (212) is installed on the inside of the upper mounting groove (211) and supports the roller housing (500).

The contact roller (600) is rotatably connected to the roller housing (500) and is rotatably driven to move the surgical flexible drill bit (10) forward while in contact with the surgical flexible drill bit (10) entering the delivery tube (100).

The lower induction roller part (220) is installed at the lower end of the entrance of the delivery tube (100) into which the surgical flexible drill bit (10) is introduced while facing the upper induction roller part (210), and moves the surgical flexible drill bit (10) entering the delivery tube (100) forward along the internal space of the delivery tube (100).

Here, the lower induction roller part (220) has the same configuration as the upper induction roller part (210) described above, and the upper mounting groove (211), roller housing (500), contact spring (212), and contact roller (600) of the upper induction roller part (210) can be applied in the same manner. Therefore, the description thereof will be omitted to avoid duplication of explanation.

Figures 7 and 8 are drawings showing the roller housing and the contact roller of Figure 6.

Referring to FIGS. 7 and 8, the roller housing (500) includes a housing body (510), a fluid tank (520), a first wing (530), a second wing (540), a first cylinder (550), and a second cylinder (560).

The housing body (510) is supported by a contact spring (212) and is seated in the upper seating groove (211).

The fluid tank (520) is arranged along the inner side of the sealing spring (212) to support the housing body (510) in the upper mounting groove (211), and as the housing body (510) is inserted into the upper mounting groove (211), it contracts and simultaneously supplies the fluid, which is a fluidic substance contained in the internal space, to the first cylinder (550), the second cylinder (560), and the variable cylinder (650).

The first wing (530) is rotatably connected to one side of the lower portion of the housing body (510) exposed from the upper mounting groove (211) and supports one side of the contact roller (600).

The second wing (540) is rotatably connected to the other side of the lower housing body (510) exposed from the upper mounting groove (211) while facing the first wing (530) to support the other side of the contact roller (600).

The first cylinder (550) is spaced inwardly from the connection position between the first wing (530) and the housing body (510) and supports between the first wing (530) and the housing body (510), and as fluid is supplied from the fluid tank (520), it expands and spreads the first wing (530) in a direction away from the second wing (540).

The second cylinder (560) is spaced inwardly from the connection position between the second wing (540) and the housing body (510) and supports between the second wing (540) and the housing body (510), and as fluid is supplied from the fluid tank (520), it expands and spreads the second wing (540) in a direction away from the first wing (530).

Referring to FIGS. 7 and 8, the contact roller (600) includes a first disc (610), a second disc (620), a first rotational shaft (630), a second rotational shaft (640), a variable cylinder (650), a first connecting shaft (660), a second connecting shaft (670), a driving motor (680), and a roller tube (690).

The first plate (610) is formed in a circular flat shape and is placed on the inward surface of the first wing (530).

The second plate (620) is formed in a circular flat shape and is placed on the inward surface of the second wing (540).

The first rotation axis (630) is formed by extending from the center of the inward surface of the first disk (610) facing the second disk (620).

The second rotation axis (640) is formed by extending from the center of the inner surface of the second disk (620) facing the first disk (610), and is inserted and seated in an extension mounting groove (631) formed at the front end of the first rotation axis (630).

The variable cylinder (650) is installed on the second rotation shaft (640), and the cylinder rod is installed inside the extension mounting groove (631). As fluid is supplied from the fluid tank (520), the cylinder rod is exposed to expose the second rotation shaft (640) from the extension mounting groove (631), thereby increasing the gap between the first disk (610) and the second disk (620).

The first connecting shaft (660) is installed at the center of the outward surface of the first disc (610) and is rotatably connected to the inward surface of the first wing (530) through a universal joint structure to support the first disc (610).

The second connecting shaft (670) is installed in the center of the outward surface of the second disc (620) and is rotatably connected to the inward surface of the second wing (540) through a universal joint structure to support the second disc (620).

The drive motor (680) is installed on the inward surface of the second wing (540), supports the second connecting shaft (670), and rotates the second connecting shaft (670).

The roller tube (690) is formed in a ring-shaped tube shape and is installed around the first rotation axis (630) and the second rotation axis (640) between the first and second discs (610 and 620) to be closely attached to the surgical flexible drill bit (10). As the gap between the first and second discs (610 and 620) increases, the width increases and at the same time, the tube expands as fluid is supplied from the fluid tank (520).

A roller housing (500) having a configuration as described above can stably move a surgical flexible drill bit (10) by using a wheel that varies depending on the size of the surgical flexible drill bit (10).

The above-described embodiments are for illustrative purposes, and those skilled in the art will appreciate that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. Therefore, the above-described embodiments should be understood as illustrative and not restrictive in all respects. For example, each component described as a single entity may be implemented in a distributed manner, and likewise, components described as distributed may be implemented in a combined manner.

The scope of protection sought by this specification is indicated by the claims described below rather than the detailed description above, and should be interpreted to include all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts.

10: Surgical flexible drill bit
11: Shankbu
12: Guide Department
13: 1st extension
14: 2nd extension
15: Banding section
16: Cutting section

Claims (8)

A configuration bonding step for bonding each component of a surgical flexible drill bit;
A heating step for heating the surgical flexible drill bit manufactured by the above-mentioned composition combining step;
A cooling step for cooling the surgical flexible drill bit heated by the heating step;
A defect confirmation step for checking whether the above surgical flexible drill bit is defective; and
A packaging step for packaging the above surgical flexible drill bit confirmed to be of good quality;
Each component of the above surgical flexible drill bit is:
A shank portion installed in a surgical drill device;
A guide part having a diameter larger than that of the shank part and installed at the front end of the shank part;
A first extension formed by extending from the front end of the above guide portion;
A second extension portion spaced apart from the first extension portion;
A bending part installed between the first extension part and the second extension part and configured to transmit torque transmitted from the first extension part to the second extension part while being bendable by an external force; and
It includes a cutting part which is installed at the front end of the second extension part and has a blade for performing perforation processing;
It further includes a foreign substance removal step of removing foreign substances attached to the surgical flexible drill bit that has progressed to the cooling step using a foreign substance removal device;
The above foreign substance removal device,
A delivery tube formed of a cylindrical tube shape having an inner diameter identical to the largest diameter portion of the surgical flexible drill bit, and positioned between two transfer devices for moving the surgical flexible drill bit so as to allow the surgical flexible drill bit to pass through while being moved;
A bit insertion guide installed at the entrance of the delivery tube into which the surgical flexible drill bit is inserted and moving the surgical flexible drill bit entering the delivery tube forward along the internal space of the delivery tube;
A bit discharge guide unit installed at the outlet of the delivery tube through which the surgical flexible drill bit is discharged and discharges the surgical flexible drill bit moved along the delivery tube by the bit insertion guide unit from the delivery tube; and
A rotating cleaning unit that removes foreign substances attached to the surgical flexible drill bit while rotating along the inner surface of the delivery tube;
The above bit insertion induction part is,
An upper guide roller section installed at the upper end of the inlet of the delivery tube into which the surgical flexible drill bit is inserted and moving the surgical flexible drill bit entering the delivery tube forward along the internal space of the delivery tube; and
A lower guide roller section is installed at the lower end of the inlet of the delivery tube into which the surgical flexible drill bit is introduced while facing the upper guide roller section, and moves the surgical flexible drill bit entering the delivery tube forward along the internal space of the delivery tube;
The upper induction roller part above,
An upper mounting groove formed on the inner surface of the upper portion of the inlet of the above-mentioned transmission tube;
A roller housing that is seated in the upper mounting groove of the chandelier;
A sealing spring installed on the inside of the upper mounting groove to support the roller housing; and
A contact roller is provided that is rotatably connected to the roller housing and is rotatably driven to move the surgical flexible drill bit forward while in close contact with the surgical flexible drill bit entering the delivery tube;
The above roller housing,
A housing body supported by the above-mentioned adhesion spring and seated in the above-mentioned upper seating groove;
A fluid tank arranged along the inner side of the above-mentioned sealing spring to support the housing body in the upper mounting groove, and supplying the fluid contained in the internal space by contracting as the housing body is inserted into the upper mounting groove;
A first wing rotatably connected to one side of the lower portion of the housing body exposed from the upper mounting groove and supporting one side of the contact roller;
A second wing rotatably connected to the other side of the lower portion of the housing body, which is exposed from the upper mounting groove while facing the first wing, and which supports the other side of the contact roller;
A first cylinder, spaced inwardly from the connection position between the first wing and the housing body and supporting between the first wing and the housing body, and extending as fluid is supplied from the fluid tank, to spread the first wing in a direction away from the second wing; and
A second cylinder is provided, spaced inwardly from the connection position between the second wing and the housing body, to support between the second wing and the housing body, and to spread the second wing in a direction away from the first wing while extending as fluid is supplied from the fluid tank;
The above-mentioned adhesion roller,
A first disc having a circular flat plate shape and arranged on the inward surface of the first wing;
A second plate having a circular flat plate shape and arranged on the inward surface of the second wing;
A first rotation axis extending from the center of the inward surface of the first disc facing the second disc;
A second rotational axis extending from the center of the inner surface of the second disk facing the first disk, and having a front end inserted into an extension mounting groove formed at the front end of the first rotational axis;
A variable cylinder installed on the second rotary shaft, the cylinder rod being installed inside the extension mounting groove, and exposing the cylinder rod as fluid is supplied from the fluid tank, thereby exposing the second rotary shaft from the extension mounting groove, thereby increasing the gap between the first disc and the second disc;
A first connecting shaft that is installed in the center of the outward surface of the first disc and is rotatably connected to the inward surface of the first wing through a universal joint structure to support the first disc;
A second connecting shaft that is installed in the center of the outward surface of the second disc and is rotatably connected to the inward surface of the second wing through a universal joint structure to support the second disc;
A driving motor installed on the inner surface of the second wing to support the second connecting shaft and rotate the second connecting shaft; and
A roller tube having a ring-shaped tube shape, installed between the first and second plates along the circumference of the first and second rotational axes, and being closely seated on the surgical flexible drill bit, the width of which increases as the gap between the first and second plates increases, and which expands as fluid is supplied from the fluid tank;
The above rotating cleaner,
A ring mounting groove formed extending along the inner surface of the above-mentioned transmission tube;
A rotating ring having a circular ring shape and installed so as to be rotatable in the ring mounting groove;
A ring drive gear that is installed so as to be rotatably driven in the ring mounting groove and is connected by gear engagement to a gear tooth formed along the outer surface of the rotating ring and is rotatably driven by a rotating drive device to drive the rotating ring in the forward or reverse direction; and
A cleaning brush is installed along the inner surface of the rotating ring and rotates together with the rotating ring to remove foreign substances attached to the surgical flexible drill bit;
The above rotating ring,
A method for manufacturing a surgical flexible drill bit, wherein the ring drive gear, which is engaged by a gear engagement on an outer surface, is rotated together with the rotational drive.
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