KR102239937B1 - A surgery drill - Google Patents

Abstract

The present invention discloses a surgical drill.
To this end, the present invention is provided with a cutting edge, a rod-shaped drill that is vertically raised and lowered while being rotated with respect to the contact surface to make a hole; A cutting edge portion formed by being drilled at one side of the drill at a twist angle along the outer surface of the rod by the contact angle; A full length part extending in the longitudinal direction including the cutting edge part to allow a perforation operation to be performed in the bone at the lesion location; A coupling portion formed on the other side of the drill and mounted on the chuck of the driving jaw for providing a driving force; The cutting edge portion has a first end on which the cutting edge is formed, and is formed to extend in the longitudinal direction of the cutting edge, and is larger than the diameter of the first end, and has a diameter smaller than the diameter of the entire length. In perforating the drill, it is easy to straighten it easily in a state where the diameter of the drill increases sequentially with the diameter of the drill, and there is an advantage of not being transmitted to the patient during the orthodontic drilling operation.

Description

A surgery drill

The present invention relates to a surgical drill capable of accurately drilling to a lesion location in a surgical procedure and preventing damage to tissues due to frictional heat of a cutting edge.

During orthopedic surgery, when drilling through the bone, it is important that the drill tip does not break through the distal cortex wall and does not damage any underlying soft tissue behind the bone.

In the field of orthopedic surgery, most of the perforation processes performed during surgery require a perforation state from one side of the cortex to the other side to perforate the bone through the center of the bone or through a hollow part known as the medullary canal. .

These cortex are known as the adjacent cortex and the distant cortex, and the soft tissues such as muscles, veins and arteries lie past the distant cortex.

In addition, in some cases, the bone structures that are perforated inside are generally made of hard, dense, and thin dense outer layers or cortical bones and lighter, sponge-like or reticulated bones, so the hardness and density of the bone cortex are different. It is higher than the bone spongy quality, which makes it quite difficult to perforate.

With typical orthopedic drill bits, it is difficult to determine when the cut end has just penetrated the bone cortex.

This piercing occurs almost immediately after the drill bit has passed through the bone to the extent that the rear end of the main cutting edge (at the full diameter of the drill bit) first engages the bone surface, and A hole is provided in the bone surface that is the full diameter.

When the drill bit penetrates the adjacent cortex, it proceeds through the hollow portion of the bone to the distant cortex through which the tooth passes through the soft tissue.

Progression of the drill bit deep into the muscles veins and arteries, with the drill bit advancing faster and more, can cause a sudden breakthrough, potentially leading to significantly increased trauma and arterial damage. In some cases it can lead to death.

In order to solve such a conventional problem, a drill bit has been proposed to the Korean Intellectual Property Office in Korean Patent Application Laid-Open No. 10-2013-0140007 (referred to as preliminary disclosure) to accurately and easily perforate bones.

This pre-opening configuration is a structure in which the outer diameter of the drill is formed to have the same diameter from the tip where the cutting edge starts to the head of the entire length of the drill. There was an inconvenience of having to rework the drilling work for it.

KR Patent Publication 10-2013-0140007 (published on December 23, 2013)

An object of the present invention is to allow the drilling state to be punctured in a straight line to the lesion location when the bone is unavoidably punctured during surgery.

In addition, the present invention makes it easy to straighten and straighten it easily in a state where the diameter to be drilled is pierced with the diameter of a drill whose diameter is sequentially increased when drilling the bone of the surgical site, and the unreasonableness is transmitted to the patient during the corrective drilling operation. Its purpose is not to be.

Characterized in the present invention, a surgical drill. An auxiliary battery for charging smartphones is introduced.

To this end, the present invention is provided with a cutting edge, a rod-shaped drill that is vertically raised and lowered while being rotated with respect to the contact surface to make a hole; A cutting edge portion formed by being drilled at one side of the drill at a twist angle along the outer surface of the rod by the contact angle; A full length part extending in the longitudinal direction including the cutting edge part to allow a perforation operation to be made in the bone at the lesion location; A coupling portion formed on the other side of the drill and mounted on the chuck of the driving jaw for providing a driving force; The cutting edge portion is viewed by providing a configuration having a first end on which the cutting edge is formed, and extending in the longitudinal direction of the cutting edge, which is larger than the diameter of the first end, and has a diameter smaller than the diameter of the electric length part. The object of the invention is sufficiently achieved.

In a configuration in which the object of the present invention is achieved, it is preferable that the cutting edge portion is formed such that the boundary portion of the second end that continues from the first end is connected by an inclined guide surface.

In a configuration in which the object of the present invention is achieved, the electric length part further includes a third end and a fourth end having a diameter that is sequentially increased between the second end and the electric length part, but having a diameter smaller than the diameter of the electric length part, and It is preferable that the cutting edge is configured to extend to the fourth end.

In a configuration in which the object of the present invention is achieved, it is preferable that the electric length part is configured such that a sawtooth surface is formed on the bottom surface of the electric length part, and formed radially with respect to the central axis of the electric length part.

In the configuration in which the object of the present invention is achieved, it is preferable that the cutting edge portion is configured with a diameter of the first end of 2 mm and a diameter of the second end of 3 to 5 mm.

The present invention provides an advantage of smoothly performing a related follow-up procedure since the drilling state to be punctured is punctured in a straight line to the lesion location when the bone is punctured.

In addition, the present invention makes it easy to straighten and straighten it easily in a state where the diameter to be pierced is pierced with the diameter of a drill that increases sequentially in perforating the bone of the surgical site, and it is unreasonable to the patient during the corrective drilling operation. The advantage of not being delivered is provided.

1 is a perspective view of a surgical drill to which the present invention is applied,
Figure 2 is a front state view of the surgical drill to which the present invention is applied,
3 is a perspective view of the bottom of the surgical drill to which the present invention is applied,
Figure 4 is a state diagram applying another embodiment to the cutting edge of the present invention,
5 is a longitudinal cross-sectional view of FIG. 4;
Figure 6 is a state diagram showing the configuration of the bottom of the electric device of the present invention.

Specific embodiments in which the present invention may be practiced will be described with reference to the accompanying drawings to illustrate.

These embodiments will be described in detail sufficient to enable those skilled in the art to practice the present invention, and it should be understood that various embodiments of the present invention are different from each other, but need not be 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 present invention in relation to one embodiment.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to enable those of ordinary skill in the art to easily implement the present invention.

FIG. 1 is a perspective view of a surgical drill to which the present invention is applied, and FIG. 2 is a front view of a surgical drill to which the present invention is applied. A cutting tool with a coupling part fastened to the chuck of the driving device on one side of the rod-shaped shank, and on the other side, a cutting edge that digs into the surface of the work piece to make a hole or to form a groove. to be.

In order to use such a drill as a surgical tool for treatment of the patient, the rod-shaped handle, that is, the cutting edge part 200 formed on one side of the front part 300, a hole in the workpiece, that is, the lesion part of the patient. In order to operate, the first end 210 and the second end 230 are formed to form a through hole in the bone blocking the lesion location.

In forming the first end 210 and the second end 230, each has a different diameter, and is formed different from the diameter of the handle of the electric length part 300. The diameter of the end 230 is small, and the diameter of the first end 210 is smaller than that of the second end 230.

In addition, a contact angle 202a is formed at the tip 202 of the first end 210 to penetrate the surface of the processing position.

In addition, a cutting edge 205 extending from the contact angle 220a is formed on the outer diameter of the first end 210.

The cutting edge 205 is formed with a torsion angle that is sharpened to an optimum state when cutting the processing position in connection with the contact angle 202a that digs into the surface of the processing position, and the cutting edge 205 uses the driving force of the cutting blade. The cutting groove 207 is formed at the same twist angle so that the generated chips are discharged to the outside of the machining position.

The cutting edge 205 and the cutting groove 207 formed in the first end 210 are formed on the outer diameter of the second end 230 at a twist angle.

Therefore, the cutting edge 205 is also formed on the outer diameter of the second end 230, so that the cutting edge of the second end 230 is drilled by the first end 210 that has dug into the surface of the machining position. (205) is entered while being cut, and the diameter of the hole currently being processed is machined in an expanded state.

3 is a bottom perspective state of a surgical drill to which the present invention is applied, the first end 210 and the second end 230 formed on the cutting edge 200 of the drill 100 have different diameters. Therefore, their interface is separated by the difference in diameter size.

Since the difference in diameter between the first end 210 and the second end 230 causes the expansion of the hole to proceed unnaturally when the bone portion covering the lesion location is punctured, the first end 210 The guide surface 250 is formed so that the boundary between the and the second end 230 is connected by an inclined surface.

Since the boundary portion between the first end 210 and the second end 230 is obliquely connected by the guide surface 250, the lesion location is at the contact angle 202a of the first end 210 and the cutting edge 205. When the through hole is processed in the bone of the inclined surface of the guide surface 250 is brought into contact with the through hole processed by the first end 210.

When the guide surface 250 is in contact with the through hole, the cutting edge 205 formed on the guide surface 250 enters while cutting the contacted through hole, so that the diameter of the through hole is expanded.

When the inclined guide surface 250 is inserted into the through hole processed into the first end 210 as described above, the through hole expands to the diameter of the second end 230, and when the state is sequentially performed, excessive cutting pressure on the bone. By reducing the burden caused by the lesion, it is possible to smoothly perform the through-hole work on the lesion area, and the patient is provided with features that are not unreasonable.

The first end 210 of the cutting edge 200 has a diameter of 1.5 mm to 2.5 mm, and the second end 230 has a diameter of 3 to 5 mm. It is a desirable and suitable standard.

Since the first end 210 has a diameter of 1.5 mm to 2.5 mm, and the second end 230 has a diameter of 3 to 5 mm, during the through hole processing by the first end 210, the processing position of the through hole is Even after resetting and drilling, the burden transmitted to the patient can be reduced to a minimum compared to a configuration in which a through hole is formed with a large diameter from the beginning.

4 shows a state in which another embodiment is applied to the cutting edge of the present invention, and FIG. 5 is a longitudinal sectional state of FIG. 4, wherein the drill 100 of the present invention has a cutting edge portion ( In the configuration in which the diameter of 200) is small, in addition to forming the first end 210 and the second end 230, the third end 260 and the third end 260 between the electric length portion 300 and the second end 210 A fourth stage 270 is further provided.

The third end 260 is larger than the diameter of the second end 230, and the fourth end is larger than the diameter of the third end 260 and smaller than the diameter of the electric length part 300, so the cutting edge part The outer diameter of 200 is sequentially increased by the first to fourth stages.

In addition, each boundary portion of the first to fourth ends is configured such that each outer surface is connected to the inclined guide surface 250.

Therefore, when drilling a through hole in the bone covering the lesion site, processing of the through hole starts by the contact angle 202a of the first end 210, and the second end 230, the third end 260, and the third end When the diameter change leads to the cutting edge 205 of the fourth stage 270, the through-hole processing is expanded without impact by the slope guide surface 250 of each stage, so the burden transmitted to the patient through the bone according to the change in the diameter of the drill Becomes minimal.

Figure 6 is a state diagram showing the configuration of the bottom of the electric device of the present invention.

In the electric length part 300 provided in the drill 100, a stepped jaw is formed on a bottom surface of a boundary portion to which the cutting edge part 200 is connected due to a difference in diameter.

A sawtooth surface 330 is formed radially from the central axis of the electric length column 300 so as to form a groove or a through hole on the surface of the electric length part 300 in contact with the bone in the stepped jaw of the electric length part 300.

The sawtooth surface 300 formed on the bottom surface of the boundary portion of the electric length part 300 can dig the surface of the bone to be in contact due to the uneven shape, so that the above-described cutting edge part when drilling by the drill 100 is performed. At the same time as the through hole processing by 200, processing by the toothed surface 330 is also possible.

Embodiments of the present invention have been described above with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, but may be manufactured in various different forms, and those of ordinary skill in the art to which the present invention pertains It will be appreciated that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects.

100: drill 200: cutting edge 202: tip
205: cutting edge 207: cutting groove 210: first stage
230: second stage 250: guide surface 260: third stage
270: fourth stage 300: full length 330: serrated surface
400: coupling portion 410: fixed protrusion

Claims (5)

A rod-shaped drill having a cutting edge and vertically raising and lowering it while being rotated with respect to the contact surface to make a hole;
A cutting edge portion which is drilled at one side of the drill at a twist angle along the outer surface of the rod by a contact angle to form a cutting edge;
A full length part extending in the longitudinal direction including the cutting edge part to allow a perforation operation to be performed in the bone at the lesion location; And
It is formed on the other side of the drill and includes a coupling portion mounted on the chuck of the driving jaw providing a driving force,
The cutting edge part,
A first end on which the cutting edge is formed, and a second end formed to extend in the longitudinal direction of the cutting edge, which is larger than the diameter of the first end and has a diameter smaller than the diameter of the electric length part, and continues from the first end. Is formed to be connected to the inclined guide surface,
The electric field part,
A third end and a fourth end having a diameter sequentially increasing between the second end and the electric length part but having a diameter smaller than the diameter of the electric length part are further provided, and the cutting edge extends to the fourth end, A sawtooth surface is formed on the bottom surface of the electric length part, characterized in that it is formed radially with respect to the central axis of the electric length part, surgical drill. delete delete delete The method of claim 1,
The cutting edge part,
The first stage has a diameter of 2mm, and the second stage has a diameter of 3 to 5mm.

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