KR100513841B1 - Electromotive apparatus for operating a dental implant - Google Patents

Abstract

The present invention relates to a power tool for implant surgery, and more particularly to a power mechanism consisting of a handpiece and a driving device used to make a hole in the jawbone or to fasten a screw-shaped artificial tooth fixation in order to perform a dental implant. However, in the case of replacing the handpiece due to wear of the bevel gear installed on the transmission shaft in the handpiece by installing the reduction gear unit, which is conventionally mounted inside the handpiece, to be integrally coupled to the front end of the micromotor embedded in the driving device. It can completely reduce the manufacturing cost of the handpiece and significantly reduce the cost of replacing the handpiece by completely eliminating the conventional problem of having to dispose of the gearbox with a longer service life and an expensive reduction gear device than the bevel gear. The present invention relates to a power tool for implant surgery.

Description

Electromotive apparatus for operating a dental implant

The present invention relates to a power tool for implant surgery, and more particularly to a power mechanism consisting of a handpiece and a driving device used to make a hole in the jawbone or to fasten a screw-shaped artificial tooth fixation in order to perform a dental implant. However, in the case of replacing the handpiece due to wear of the bevel gear installed on the transmission shaft in the handpiece by installing the reduction gear unit, which is conventionally mounted inside the handpiece, to be integrally coupled to the front end of the micromotor embedded in the driving device. It can completely reduce the manufacturing cost of the handpiece and significantly reduce the cost of replacing the handpiece by completely eliminating the conventional problem of having to dispose of the gearbox with a longer service life and an expensive reduction gear device than the bevel gear. The present invention relates to a power tool for implant surgery.

In general, when a dental implant is used to replace a damaged natural tooth, most of the dental implants use a screw-shaped artificial tooth fixture, which acts as an artificial tooth root. In order to install in the jawbone in the inner most as shown in Figure 1 is a micro-motor (Micro-Motor) built-in drive unit 15 and the detachable coupled to the front end of the drive device 15 and the front end is formed to be inclined And the dental drill or screwdriver 31 is a dental implant or a power tool (1) consisting of a handpiece (Contra-angle handpiece) 2 is removable.

As described above with reference to FIG. 2, the configuration and working relationship of a conventional implant surgery power tool widely used in the treatment of dental implants is as follows.

The handpiece (2) of the conventional implant surgery power mechanism is provided with a reduction gear device 30, the front shaft (30a) and the rear shaft (30b) protruding forward and rearward inside the body portion (3) and at the rear end Coupling hole (3a) is formed through and the inclined neck portion 8 is integrally formed in the front end portion, the front shaft (30a) and the bevel gear (7) of the reduction gear device 30 inside the inclined neck portion (8) An inclined motor shaft (9) interlocked by the support is supported by a bearing (10), and a head portion (11) is integrally formed at a front end portion, and the inclined motor shaft (9) is formed inside the head portion (11). ) And a tool engagement shaft 12 interlocked by the bevel gear 14 are supported by the bearing 13.

The driving device 15 coupled to the rear end of the handpiece 2 has a micromotor 18 installed inside the case 16 and inserted into the coupling hole 3a of the handpiece 2 at the front end. A coupling guide portion 17 to be coupled is installed, and a conductive wire 21 for supplying power to the micromotor 18 is connected to the rear end portion.

The coupling tool 6 is inserted into the rear shaft 30b of the reduction gear device 30 of the handpiece 2, and the coupling tool is installed in the main shaft 18a of the micromotor 18 of the driving device 15. Coupler 20 coupled to the insertion (6) is inserted, the coupling of the driving device 15 to the coupling hole (3a) of the handpiece (2) when the handpiece (2) and the driving device 15 is coupled After inserting the guide portion 17 is configured to be coupled to each other by inserting the engaging projection of the coupler 20 to the groove portion of the coupler (6).

In addition, the handpiece 2 is divided into two for drilling and artificial tooth fixation according to the purpose of use of the reduction gear device 30 installed therein. It is built in the reduction gear device 30 formed of 16: 1 to sufficiently reduce the rotational force transmitted from the micromotor 18 to minimize the heat generated by friction with the jaw bone during drilling to prevent damage to bone tissue by friction heat In addition, the handpiece for fastening the artificial tooth fixing body has a reduction gear device 30 having a reduction ratio of 256: 1, so that the rotational torque is further increased instead of greatly reducing the rotational speed, so that the artificial tooth fixing body is easier on the jawbone. To be tightened.

In the conventional implant surgery power mechanism, the handpiece 2 is coupled to the coupling guide portion 17 of the driving device 15, and then a dental drill or a screwdriver is applied to the head of the handpiece 2. When the power switch (not shown) to control the electricity supply to the driving device 15 is turned on, the micromotor embedded in the driving device 15 is connected to the rear end of the driving device 15 through a conductor 21 connected to the rear end of the driving device 15. Electricity is supplied to 18 to generate a strong rotational force while the main shaft 18a of the micromotor 18 rotates.

The rotational force generated as described above is coupled to the main shaft 18a of the micromotor 18 by a coupler 6 and 20 connecting the rear shaft 30b of the reduction gear device 30 incorporated in the handpiece 2. It is transmitted to the reduction gear device 30, the transmitted rotational force is constantly decelerated according to the reduction ratio of the reduction gear device 30, and then to the bevel gear (7) through the front shaft (30a) of the reduction gear device (30). The rotational force transmitted to the inclined transmission shaft (9) interlocked by, the transmission force transmitted to the inclined transmission shaft (9) is transmitted to the tool coupling shaft (12) interlocked by the bevel gear (14), to the tool coupling shaft (12) The transmitted torque is to rotate the dental drill or screwdriver inserted into the tool coupling shaft 12 to make a hole in the jawbone or to fasten the artificial tooth fixture.

When such a conventional implant-driven power tool is used for a certain period of time, most of the bevel gears 7 and 14 installed in the handpiece 2 are worn, and the rotational force transmitted from the driving device 15 is transmitted to the dental drill or driver. Since it is not properly delivered to the end of the service life of the handpiece (2), the end of the service life of the handpiece (2) is separated from the drive unit 15 is replaced with a new handpiece (2).

However, such a conventional implant operation power mechanism has an expensive deceleration gear device 30 built into the handpiece 2, which is a factor that excessively increases the manufacturing cost of the handpiece 2, which is a consumable. In addition, when the handpiece 2 needs to be replaced due to wear of the bevel gears 7 and 14 installed in the handpiece 2, it is more durable than the bevel gears 7 and 14 and has a long service life. Since the reduction gear device 30 is also usedlessly disposed, there is a problem in that the replacement of the handpiece 2 takes a lot of cost.

In order to solve the above problems, the present invention constitutes a power mechanism consisting of a handpiece and a driving device used to puncture a jawbone or to fasten a screw-shaped artificial tooth fixture in order to perform a dental implant. By installing the reduction gear unit to be integrated with the front end of the micromotor embedded in the driving device, the service life of the bevel gear is relatively longer than that of the bevel gear when the handpiece is replaced due to wear of the bevel gear installed on the electric shaft in the handpiece. The technical problem is to completely reduce the manufacturing cost of the handpiece and to significantly reduce the cost of replacing the handpiece by completely eliminating the conventional problem of having to discard this long and expensive reduction gear unit together. .

Hereinafter, the present invention will be described in detail with reference to FIG. 3 to achieve the above object.

3 is a cross-sectional view schematically showing the configuration of the power tool for implant surgery according to the present invention.

As shown in FIG. 3, the driving mechanism 15 for implant surgery according to the present invention includes: a driving device 15 having a micromotor 18 embedded therein; In the transmission mechanism, the handpiece (2) which is detachably coupled to the front end of the drive device 15, the dental drill or driver 31 is detachable to the head portion 11, the handpiece ( 2) has a trunk portion (3) is formed horizontally the inner space is formed with a coupling hole (3a) penetrating to the rear end, is formed integrally with the front end portion of the trunk portion (3) An inclined neck portion (8) communicating with the inclined neck and having an inner space therein, the head portion (11) being integrally formed at the front end of the inclined neck portion (8) and communicating with the inclined neck portion (8); The driving device 15 has a coupling guide portion 17 inserted into the coupling hole 3a of the handpiece 2 at the front end portion, and the inner space penetrated by the coupling guide portion 17 is horizontally formed. It is provided with a case 16; A horizontal electric shaft 4 is installed in a horizontal internal space of the trunk portion 3 of the handpiece 2; The horizontal transmission shaft 4 is provided with a coupling hole 6 located on the coupling hole 3a at the rear end thereof, and a bevel gear 7 is installed at the front end thereof. Rotating force transmitted from the drive device 15 is rotatably supported by a bearing 5 installed and supported in the inner space of the body portion 3 between the gears 7 and the inclined neck portion 8. It is transmitted to the tool coupling shaft 12 of the head portion 11 through the inclined transmission shaft 9, the horizontal space of the case 16 of the drive device 15 of the micromotor 18 The reduction gear part 19 is installed in series at the front end; The coupling shaft 20 located in the inner space of the coupling guide portion 17 is installed on the main shaft 19a of the reduction gear portion 19, thereby providing the coupling guide portion 17 of the driving device 15 with the coupling guide portion 17. The horizontal transmission shaft 4 of the handpiece 2 and the main shaft 19a of the reduction gear unit of the driving device 15 are inserted into the coupling hole 3a of the handpiece 2 so that the two coupling holes 6, The rotational force decelerated by the reduction gear unit 19 in the driving device 15 is connected horizontally to the inner space in the trunk portion 3 of the handpiece 2 so as to be connected by the coupling of the bearing 20. It is configured as a transmission mechanism for the implant procedure, characterized in that to be transmitted to the inclined transmission shaft (9) through a horizontal transmission shaft (4) supported by.

The micromotor 18 operates stably with a small power to use a known micro motor commonly used in various communication devices, measuring devices, automatic control devices, and the like.

The reduction gear unit 19 is made of a combination of a plurality of gears to use a known reduction gear device having a variety of reduction ratios that are commonly used to reduce the rotational speed of the motor, such as a constant, in the case of a drive device for drilling work A reduction gear device with a reduction gear ratio of 16: 1 is used, and a reduction gear device with a reduction gear ratio of 256: 1 is preferably used for fastening artificial teeth.

The configuration in which the micromotor 18 and the reduction gear unit 19 are integrally coupled to each other generally uses a known geared micromotor that is already commercialized by being used in combination with the micromotor and the reduction gear unit. .

The coupler 6 and 20 connecting the handpiece 2 and the driving device 15 are the same as the coupler used in the conventional power tool for implant surgery, respectively, the horizontal electric shaft of the handpiece 2 ( 4) is fixedly installed on the main shaft (19a) of the reduction gear unit 19 installed in the drive unit 15, the coupling of the handpiece (2) when the handpiece (2) and the drive unit 15 is coupled After the coupling guide portion 17 of the driving device 15 is inserted into the ball 3a, the coupling protrusions of the coupling sphere 20 are inserted into the grooves of the coupling sphere 6 so as to be coupled to each other.

Referring to the working relationship of the power tool for implant surgery according to the present invention configured as described above are as follows.

According to the present invention, the power tool for implant surgery combines the handpiece 2 to the coupling guide portion 17 of the driving device 15, and then mounts a dental drill or driver to the head portion of the handpiece 2; When the power switch (not shown) controlling the supply of electricity to the driving device 15 is turned on, the electric power is supplied to the micromotor 18 through the conductive wire 21 connected to the rear end of the driving device 15. It generates a rotational force.

The strong rotational force generated as described above is transmitted to the reduction gear unit 19 integrally coupled to the front end of the micromotor 18, and the rotational force decelerated at a constant reduction ratio according to the type of the reduction gear unit 19 is again reduced in the reduction gear unit. It is transmitted from the main shaft (19a) of the 19 to the horizontal transmission shaft (4) of the handpiece (2) through the coupler (20, 6).

The rotational force transmitted to the horizontal transmission shaft 4 of the handpiece 2 is transmitted to the inclined transmission shaft 9 interlocked by the bevel gear 7, and the rotational force transmitted to the gradient transmission shaft 9 is again beveled. It is transmitted to the tool coupling shaft 12 interlocked by the gear 14, the rotational force transmitted to the tool coupling shaft 12 is the jawbone by rotating the dental drill or driver finally inserted into the tool coupling shaft 12 It will be possible to drill holes or fasten artificial teeth.

As described above, the implant-driven electric mechanism according to the present invention is a micromotor, which is conventionally installed in the handpiece 2 and includes the reduction gear unit 19 which is disposed together with the handpiece 2 when the handpiece 2 is replaced. It is installed so as to be integrally coupled to (18) so that the reduction gear unit 19 can be used semi-permanently, and at the same time the service life of the handpiece 2 due to the wear of the bevel gears (7) (14) installed in the handpiece (2) In this case, only the handpiece 2 excluding the reduction gear unit 19 is separated from the driving device 15 and then replaced with a new handpiece 2 to be used.

In addition, since the drive device of the power tool for implant surgery according to the present invention can be used in combination with a handpiece of a low-cost dental power tool having a reduction ratio of 1: 1, which is usually provided in a number of dentists, The handpiece 2 of the power tool for implant surgery according to the present invention can be immediately replaced and used in the event of a failure or the like when there is no replacement handpiece 2.

As described above, the power tool for implant surgery according to the present invention constitutes a power mechanism consisting of a handpiece and a driving device used to make a hole in a jawbone or to fasten a screw-shaped artificial tooth fixture in order to perform a dental implant. Since the gearbox installed inside the handpiece is integrally coupled to the front end of the micromotor embedded in the driving device, it is relatively more relative to the bevel gear when the handpiece needs to be replaced due to wear of the bevel gear installed in the handpiece. In order to reduce the manufacturing cost of the handpiece, it is possible to reduce the manufacturing cost of the handpiece. Can be used in combination with the handpiece of a general dental power tool Because it has an effect that allows you to dramatically reduce the cost of replacement of the handpiece.

1 is a side view showing a conventional power tool for implant surgery.

Figure 2 is a cross-sectional view schematically showing the configuration of a conventional power tool for implant surgery.

3 is a cross-sectional view schematically showing the configuration of the power tool for implant surgery according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: Electric Mechanism 2: Handpiece 3: Body

3a: coupling hole 4: horizontal drive shaft 5: bearing

6 coupling unit 7 bevel gear 8 inclined neck portion

9 Sloped Power Shaft 10 Bearing 11 Head

12: tool coupling shaft 13: bearing 14: bevel gear

15: drive device 16: case 17: coupling guide portion

18: micromotor 19: reduction gear 20: coupling sphere

21: lead wire

Claims (1)

A driving device 15 having a micromotor 18 therein; In the transmission mechanism of the implant procedure consisting of a handpiece (2) detachably coupled to the front end of the drive device 15, the dental drill or driver 31 to the head portion 11, The handpiece (2) has a body portion (3) is formed in the inner space is formed horizontally through the coupling hole (3a) penetrating to the rear end, formed integrally with the front end of the body portion (3) The head portion 11 having an inclined neck portion 8 which communicates with the portion 3 and is formed to be inclined and is integrally formed at the front end of the inclined neck portion 8 so as to communicate with the inclined neck portion 8. With; The driving device 15 has a coupling guide portion 17 inserted into the coupling hole 3a of the handpiece 2 at the front end portion, and the inner space penetrated by the coupling guide portion 17 is horizontally formed. It is provided with a case 16; A horizontal electric shaft 4 is installed in a horizontal internal space of the trunk portion 3 of the handpiece 2; The horizontal transmission shaft 4 is provided with a coupling hole 6 located on the coupling hole 3a at the rear end thereof, and a bevel gear 7 is installed at the front end thereof. Rotating force transmitted from the drive device 15 is rotatably supported by a bearing 5 installed and supported in the inner space of the body portion 3 between the gears 7 and the inclined neck portion 8. To be transmitted to the tool coupling shaft 12 of the head portion 11 through the inclined transmission shaft 9, The reduction gear unit 19 is installed in the front end of the micromotor 18 in series in the horizontal inner space of the case 16 of the drive device 15; The coupling shaft 20 located in the inner space of the coupling guide portion 17 is installed on the main shaft 19a of the reduction gear portion 19, thereby providing the coupling guide portion 17 of the driving device 15 with the coupling guide portion 17. The horizontal transmission shaft 4 of the handpiece 2 and the main shaft 19a of the reduction gear unit of the driving device 15 are inserted into the coupling hole 3a of the handpiece 2 so that the two coupling holes 6, The rotational force decelerated by the reduction gear unit 19 in the driving device 15 is connected horizontally to the inner space in the trunk portion 3 of the handpiece 2 so as to be connected by the coupling of the bearing 20. Implantation power mechanism for the transfer to the inclined motor shaft (9) through a horizontal motor shaft (4) supported by the).