The present invention relates to a dental drill having a shaft, the distal free end of which is provided with a head provided comprising cutting edges.
From the state of the art, it is known to manufacture dental drills with different designs. The shape as well as the type of the cutting edges (toothing) are adapted to the respective purposes of application, such that the dentist may select the optimum tool for each preparation step.
The design of the cutting edges may be straight-lined. However, it is also known to provide the complete cutting edges of the head with one or more cross-cuts. These cross-cuts, having the shape of peripheral grooves or helical grooves, divide the cutting edges into individual cutting portions. Therewith, small chips are produced. Furthermore, the cutting efficiency of the dental drill is increased.
Such cutting edges being provided with cross-cuts, however, result in an inferior surface quality, such that these dental drills may only be used in a first processing step for a rough pre-processing. In order to obtain a smooth surface with high quality, it is required to use a dental drill being provided with continuous cutting edges not being interrupted by a cross-cut.
It has thus to be noted that the dentist has to use a plurality of dental drills or dental instruments in order to perform the preparation work. This results in increased costs for the different dental drills and requires a considerable expenditure of time for exchanging the dental drills during the preparation treatment.
It is therefore an object of the invention to create a dental drill which enables a high-quality preparation in a preferably short period of time.
According to the invention, a dental drill is provided, the head of which is divided into three different portions. Therein, the portion of the head facing the shaft as well as the portion facing the free distal end are provided with cutting edges which are not interrupted by a cross-cut, whereas the cutting edges of a middle portion of the head are divided by at least one cross-cut.
According to the invention, the cross-cut is formed in the shape of a groove interrupting the cutting edge and therewith the cutting flange. Therefrom, there results an increased cutting efficiency. The chips of the removed material are divided into small chips.
The smooth cutting edges of the distal end portion of the head as well as the of the end portion of the head facing the shaft enable a high-quality preparation with very good surfaces.
The inventive dental drill may therefore be used to achieve a high cutting performance, but is also capable to prepare smooth edges, e. g. for the inlay preparation of for the classic cavity preparation in the area of the cavity rim.
The dentist therewith can perform different processing steps with different qualities by using one single dental drill, without the necessity to exchange the tool. Therefrom, there results a considerable time saving.
The quality of the surface to be processed is also enhanced by the respective end portions of the head which has no cross-cuts in that only a minimum vibration of the dental drill occurs during operation.
The inventive dental drill comprises several cutting edges distributed equally or non-equally about its periphery, the cutting edges being substantially straight-lined, wherein the cutting edges may also be provided with a twist. According to the invention, a left-handed twist as well as a right-handed drill is provided. Preferably, the dental drill is right-hand cutting with respect to its rotation about its longitudinal axis.
The shapes of the head may be adapted easily to the respective requirements. The head may thus be shaped conical, tapered, spherical, pear-shaped or in the shape of a conical cylinder.
Concerning the complete axial length of the head, it is preferred that the front and rear portions being not provided with a cross-cut respectively cover 5 to 20% of the complete length.
In order to increase the strength and service life of the inventive dental drill, a method of manufacturing is proposed in which at first the shaft as well as the blank shape of the head are lathed and/or ground from a hard metal blank. Subsequently, the cutting edges of the head are produced by means of a grinding step. In a further processing step, a helical groove is ground into the middle portion of the head by means of preferably one grinding wheel, said groove serving to divide the individual cutting edges into cutting portions which have substantially the same length. Therewith, the cross-cut provided according to the invention is created. Said cross-cut therewith only forms an interruption of the cutting edges, but does not create any additional further toothing, as it is provided in dental instruments having a staggered tooth system in which the tooth system itself forms cutting portions. In case of the inventive dental drill, only the cutting portions are self-cutting, the cross-cut interrupts the cutting edges or cutting flanges.
The head 3 is divided into three portions, i. e. a distal end portion 5, a middle portion 6 as well as an end portion 7 adjacent to the shaft end 2.
As is discernible from
The distal end portion 5 of the head 3 has cutting edges which are formed continuously and therewith comprise a continuous cutting flange. The same applies for the end portion 7 adjacent to the shaft end 2.
The middle portion 6 of the head 3 is provided with a helically circumferential cross-cut 8 introduced in the form of a circumferential groove and dividing the cutting edge 4 into individual cutting segments or cutting portions 4a, as e.g. shown in
Concerning the dimensions of the axial lengths of the portions 5, 6 and 7, reference is made e.g. to
As results from the front views of
The dental drills of the preferred embodiments are made of hard metal. According to the invention, it is, however, also possible to manufacture same from a ceramic material.
Concerning the dimensions, in particular the axial lengths, there exist numerous possibilities of alterations and variations within the scope of the invention. Same exist also in view of the axial lengths of the cutting segments 4a.
Concerning the cross-cut 8, it is possible to provide a helical circumferential groove, as it is shown in the embodiments of