JP2013244390A - Drill and drill stopper system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a drill and a drill stopper system, capable of sending cooling water to an edge of a drill blade when a biological bone is perforated for implant placement, and assuring cooling of the bone.SOLUTION: A drill and a drill stopper system in which the drill and a stopper are composed in a detachable condition, and the drill (1) has a cooling water inlet (6) at a shaft part (3) and a cooling water outlet (7) at a cooling water outlet part (5) respectively, and when it is mounted on a drive head, the stopper (2) covers the cooling water outlet (7) equipped for the cooling water outlet part (5) so that the cooling water can be sent to a blade part (4) direction and can definitely cool the bone.

Description

Detailed Description of the Invention

  The present invention relates to a drill, a drill, and a stopper system that are used when a perforation is formed in a living bone in the dental field and the medical field.

  In recent years, an implant placement guide system for placing an implant at an ideal position in dental implant treatment has been provided. This implant placement guide system simulates the implant placement position based on the CT data of the patient's jaw bone treatment site in advance and allows the implant to be placed as planned. A surgical guide for determining the depth is prepared, and an implant operation is performed using the surgical guide.

  Such a method using a surgical guide can prevent a situation where a dental implant placement position and depth are different from a treatment plan.

  In addition, such a method using a surgical guide includes, for example, a method in which a sleeve having substantially the same inner diameter as a drill is provided in the surgical guide, and a drill with a stopper attached is inserted therein (see, for example, Patent Document 1). ), A spacer having an outer diameter that is substantially the same as the inner diameter of the sleeve, and an inner diameter that is substantially the same as the outer diameter of the drill to be used, a so-called guide key, and a method of inserting the drill. .

  However, in such a method, the affected part is covered with a surgical guide, and it is necessary for the operator to perform an operation without seeing the affected part, and the drill and guide key of the sleeve installed in the surgical guide are also free from gaps. Since it is inserted, it is difficult to deliver the cooling water from outside the surgical guide to the drill blade when drilling the living bone, so that the cooling performance of the bone is inferior.

  In addition, there is a means to use a drill having an internal water injection mechanism, but in a general internal water injection mechanism, cooling water is discharged radially from the drill, so that it is cooled to the drill blade part that actually drills the living bone. It is unclear whether water has arrived, and since the affected area is covered with a surgical guide, visual confirmation is difficult. Moreover, in a general internal water injection mechanism, since the cooling water outlet is installed in the drill blade part, the cooling function often deteriorates due to clogging of bone fragments and tissues in the cooling water outlet. Moreover, the thickness of a blade part becomes thin, the intensity | strength of drill itself is also inferior, and it deteriorates easily.

  There is a problem that the risk of causing bone burns increases as a result of insufficient cooling during drilling and difficulty in visual confirmation.

  These techniques are not particularly limited when using a surgical guide in the dental field.

Special table 2007-511275 gazette

  In the present invention, in view of the above-mentioned problems, when drilling a living bone inside a surgical guide that is difficult to visually confirm and inject water from the outside, it is possible to deliver cooling water to the tip of the drill blade, so that the bone It is an object to provide a safe drill, a drill, and a stopper system that can be cooled.

  According to the present invention, as a result of intensive studies to solve the above problems, the cooling water outlet of the drill is installed in the cooling water outlet portion provided between the blade portion and the shaft portion connected to the drive head, and the portion is drilled. Provided are a drill, a drill, and a stopper system, characterized in that cooling water can be guided to a drill blade portion by covering with a stopper that can be attached to and detached from the drill.

  This makes it possible for the drill to enhance the blade. When used in combination with a surgical guide, the stopper has both a guide key and a stopper function. In other words, it acts as a spacer between the drive head and the upper surface of the sleeve, and has a flange portion that determines the bone drilling depth and a guide portion that is inserted into the surgical guide sleeve, thereby determining the bone drilling direction. . Furthermore, since the cooling water outlet of the drill is covered with a stopper, it is possible to reduce the risk that a bone fragment or tissue enters and inhibits cooling water discharge.

  That is, according to the present invention, by using a combination of a drill and a stopper, it is possible to deliver cooling water to the tip of the drill blade without relying on external cooling. When the surgical guide is mainly used, the surgical guide A drill, a drill, and a stopper system capable of delivering cooling water to the tip of the drill blade at the time of bone drilling of the affected area covered by the cooling water, and the cooling water outlet provided in the cooling water outlet of the drill is the blade Since it is installed at the upper part, there is a very low risk of intrusion of bone fragments and tissues during drilling, and it is a drill, drill, and stopper system that excels in cleaning of the cooling water passage.

  Further, since the cooling water discharged from the drill passes between the cooling water outlet portion and the inner wall of the guide portion of the stopper, the drill blade is caused by the difference in diameter between the outer diameter of the cooling water outlet portion and the inner diameter of the guide portion. The momentum of the cooling water reaching the tip of the part is controlled, and the diameter difference is preferably set between 0.02 and 2 mm.

  According to the drill, the drill and the stopper system of the present invention, when drilling a bone in a surgical guide, which is difficult with the conventional method, it is possible to deliver cooling water to the tip of the drill blade, so It can be cooled and the cooling function can be prevented from being lowered by clogging the cooling water outlet with bone fragments or tissues.

  Below, the usage type in one Example of the drill which concerns on this invention, a drill, and a stopper system is demonstrated in detail based on figures.

  FIG. 1 is a perspective view showing an embodiment of a drill, a drill and a stopper system according to the present invention. The drill (1) is composed of a shaft part (3), a blade part (4), and a cooling water outlet part (5) located slightly between the shaft part (4) and the shaft part (3). The cooling water inlet (6) is provided, and the cooling water outlet (5) is provided with a cooling water outlet (7). The stopper (2) is composed of a connecting portion (8), a flange portion (9), and a guide portion (10). When connecting to the drill (1), the drill (1) and the stopper (2) The shaft part (3) of (1) is inserted and connected from the guide part (10) side of the stopper (2). At that time, the cooling water outlet (7) in the cooling water outlet (5) is covered with the guide (10) of the stopper (2).

  The left side of FIG. 2 is a diagram for explaining a usage pattern in one embodiment in which the drill (1), the stopper (2), and the drive head (11) are all connected, and the drill (1) is the drive head (11 The stopper (2) is fixed in a state where the upper surface of the flange portion (9) and the drive head (3) are in contact with each other. The cooling water is supplied from the water injection nozzle (12) inserted into the cooling water inlet (6) and discharged from the cooling water outlet (7), and then from the lower end of the guide portion (10) of the stopper (2) to the blade portion (4 ) Delivered in the direction.

  For comparison, the right side of FIG. 2 illustrates the flow of cooling water in a drill having a general internal water injection mechanism. As in the left figure, the cooling water is supplied from a water injection nozzle inserted into the cooling water inlet and discharged from the cooling water outlet. Since the cooling water outlet is disposed in the drill blade portion in a direction perpendicular to the rotation axis of the drill, the cooling water is discharged radially around the drill, and it is difficult to cool the blade portion.

  FIG. 3 is a view for explaining a cross section in a state where the drill (1) and the stopper (2) in FIG. 2 are connected. The cooling water introduced from the water injection nozzle (12) inserted into the cooling water inlet (6) passes through the cooling water passage (14) and is discharged from the cooling water outlet (7) in the cooling water outlet (5). The mechanism is visualized. Since the connection part (8) of the stopper (2) is sealed by an O-ring (13) for fixing to the drill (1), it is discharged from the cooling water outlet (7) in the cooling water outlet part (5). The cooling water thus guided is guided to the inner wall of the guide part (10) and passes from the lower part of the guide part (10) which is only released to the blade part (4) of the drill (1). The cooling water outlet (7) in the cooling water outlet part (5) of the drill (1) is covered with the guide part (10). Since the stopper (2) is in contact with the upper surface of the flange (9) and the drive head (11), the stopper (2) does not move further in the direction of the drive head (11). The cooling water outlet (7) in the part (5) is not exposed from the guide part (10) of the stopper (2). The stopper (2) may move in the direction of the blade (4) of the drill (1) depending on the fixing method with the drill (1). The outer diameter of the cooling water outlet (5) Since it is larger than the inner diameter of (8), the stopper (2) does not fall off from the drill (1). For example, when used in combination with a surgical guide as shown in FIG. 4, the stopper (2) advances the drilling of the drill (1) and the lower surface of the flange (9) is the sleeve (16) of the surgical guide (15). The stopper comes into contact with the upper surface and is guided in the direction of the drive head (11), and finally the flange portion (9) is sandwiched between the drive head (11) and the sleeve (16) of the surgical guide (15). For example, when the stopper (2) moves in the direction of the blade part (4) of the drill (1), the function is not impaired.

  The fixing of the drill (1) and the stopper (2) is not limited to the O-ring (13) shown in FIG. 3, but for example, a snap ring, for example, a flange portion (9) or a guide portion (10) is provided with a screw hole. There is a method of fixing by screw fixing or the like in combination. In these cases, the upper surface of the flange (9) of the stopper (2) and the drive head (11) are not necessarily in contact with each other.

  FIG. 5 is an enlarged view of FIG. 3 and shows the relationship between the cooling water outlet (7) of the drill (1) and the inner wall (17) of the stopper (2). The cooling water discharged from the cooling water outlet (7) passes between the cooling water outlet part (5) and the inner wall (15), and extends from the guide part (10) tip to the blade part (4) direction of the drill (1). Go through. The momentum of the cooling water at this time varies depending on the difference between the water flow for supplying the cooling water and the outer diameter of the cooling water outlet (5) and the inner diameter of the inner wall (17), and the water flow for supplying the cooling water is constant. If there is, the smaller the difference in diameter between the outer diameter of the cooling water outlet part (5) and the inner diameter of the inner wall (17), the stronger the cooling water leads to the direction of the blade part (4) of the drill (1). Go. The difference in diameter is preferably set between 0.02 and 2 mm.

  FIG. 6 shows the actual flow of cooling water in FIG. The cooling water discharged from the cooling water outlet (7) travels between the cooling water outlet part (5) and the inner wall (17), and the direction of the connection part (8) is closed, so it is only released. It leads from the guide part (10) tip to the blade part (4) direction of the drill (1). In addition, by setting the diameter difference between the outer diameter of the cooling water outlet (5) and the inner diameter of the inner wall (17) to an appropriate value (0.02 to 2 mm), the cooling water has a guide (10) tip. Appropriate pressure is applied before being discharged from the nozzle, and the momentum of the cooling water is increased. For example, even when the blade (4) faces obliquely upward, the cooling water is passed to the tip of the blade (4). Is possible.

  Since the function of the drill, drill and stopper system of the present invention is not impaired by the diameter and shape of the drill and the effective blade length, it is not limited to the dental field, for example, skull, jaw, facial restoration surgery, cosmetic surgery It can be used for treatment in fields such as plastic surgery, orthopedic surgery, oral surgery, otolaryngology, and the like.

It is a perspective view which shows one Example of the drill which concerns on this invention, a drill, and a stopper system. It is a figure explaining the usage pattern in one Example of the drill which concerns on this invention, a drill, and a stopper system, and has the flow of the cooling water of a drill, drill, and stopper system which concerns on this invention, and a general internal water injection mechanism It is the figure which compared the flow of the cooling water of a drill. It is a figure explaining the cross section in one Example of the drill which concerns on this invention, a drill, and a stopper system. It is a figure which shows a general surgical guide. FIG. 4 is an enlarged view of FIG. 3. It is a figure explaining the flow of the cooling water in FIG.

1: Drill 2: Stopper 3: Shaft part 4: Blade part 5: Cooling water outlet part 6: Cooling water inlet part 7: Cooling water outlet part 8: Connection part 9: Flange part 10: Guide part 11: Drive head 12: Cooling water Nozzle 13: O-ring 14: Cooling water passage 15: Surgical guide 16: Sleeve 17: Inner wall

Claims (1)

  The drill and stopper used when drilling a living bone with a drill are in a detachable state, and the drill has a water injection hole outlet between the shank part and the blade part, and the stopper covers that part. The drill, the drill, and the stopper system characterized in that the cooling water can be delivered to the tip of the drill blade.

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