DE1277516B - Dental handpiece with compressed air turbine motor - Google Patents

Description

Dental handpiece with air turbine motor The invention relates to a dental handpiece with a compressed air turbine motor as a drive for a drill that can be clamped in the handpiece and other rotating tools, in which the rotor of the motor is mounted in compressed air bearings.

In one known from German Patent 1,099,693 The handpiece is the cylindrical outer surface of the rotor, which is used for storage, divided into two parts by the turbine wheel.

Each of these two parts of the cylindrical surface of the rotor is assigned to one of two hollow cylindrical bearing bushes, their inner diameter is selected to be about 0.01 to 0.02 mm larger than the outer diameter of the bearing parts of the rotor. This results in two axial bearing gaps. Each of the two bearing bushes is provided with at least one ring of radially directed nozzles, the diameter of which is about 0.1 to 0.2 mm. These nozzle rings are connected to a source of compressed air in connection, of which the two axial bearing gaps are used to support the rotor receive required compressed air in the radial direction. Between those facing each other The turbine wheel is arranged on the end faces of the two hollow cylindrical bearing bushes.

Each of the two end faces of the turbine wheel is at a distance of about 0.1 to 0.2 mm from the face of the bearing bush facing it. Through this a radial bearing gap is created on each of the two sides of the turbine wheel, the one in the axial bearing gap on the same side of the turbine wheel flows out. From this axial bearing gap, each of the two radial bearing gaps receives the compressed air required to support the rotor in the axial direction.

Such dental handpieces have encountered difficulties result from the radial and axial working pressure generated during drilling are conditional. The compressed air bearings described do not hold this working pressure certainly stood. This makes it easy for the rotor to rest against the bearing bushes.

The aim of the invention is to reduce the load capacity of the compressed air bearings without significant increase in the pressure of the bearing air and without increasing the dimensions of the rotor to increase significantly.

In pursuing this goal, the inventors initially determined that in the known handpieces due to manufacturing tolerances of the two bearing bushes of the rotor, these two bearing bushings are normally not aligned. The consequence of this is that at least one of the two bearing gaps the rotor is no longer centric, but eccentric surrounds. As a result, part of the bearing capacity is lost. The inventors have also found that in the case of the known dental handpieces with built-in compressed air turbine and with compressed air storage of the rotor in two axial and two radial bearing gaps through the compressed air supply the two radial bearing gaps from the axial bearing gaps and the compressed air storage of the rotor is not very stable in the axial direction. Just occurs in the axial direction but when drilling a considerable work pressure.

The invention is based on these observations.

In the case of a dental handpiece containing an air turbine motor, which serves as a drive for a rotating tool that can be clamped into the handpiece and whose rotor is stored in compressed air bearings, is according to the invention for storage the rotor shaft in the handpiece head has a single axial hollow cylindrical bearing gap to the single cylindrical outer surface of the rotor forming only hollow cylindrical Bearing bush by elastic rings, which are angled on one side of the hollow cylindrical Head housing and on the other hand the bearing bush are held radially and axially, there are two radial bearing gaps, on the one hand by parts of the end faces of the rotor and on the other hand by surface parts lying parallel to these end faces are limited by bearing parts, with the single hollow cylindrical bearing bush at least one ring of radially directed nozzles for supplying the compressed air the single axial bearing gap is arranged and in which the two radial bearing gaps limiting bearing parts several axially directed nozzles for supplying the compressed air to the two radial bearing gaps are provided. In this way the difficulties are based on the known use of two bearing bushes for supporting the rotor go back in the radial direction, avoided. Also get the radial bearing gaps regardless of the single axial bearing gap, compressed air, its load capacity through a suitable dimensioning of the axially directed nozzles can be made sufficiently large can.

Regarding the state of the art, it should also be noted that compressed air bearing and driven turbine is known, in which the rotor in one off apparently a piece made cylinder is arranged. Apart from that, it is Larger machines with correspondingly larger dimensions are mainly absent In addition to the axial bearing gap, there are also radial bearing gaps, which are the same as in dental handpieces Can absorb any axial working pressure.

There are also air-bearing miniature turbines with a turbine wheel from 30 mm diameter and probably one axial and two radial bearing gaps known, which are to be used to drive mirror wheels, centrifuges, etc. Apart from The dimensions described above exist for these devices with completely different dimensions Problems of the dental handpieces with regard to the axial and radial working pressure not.

A particularly simple structure of the counter bearing for the rotor can achieve according to a further embodiment of the invention in that the two End faces of the single hollow cylindrical bearing bush as the one boundary surfaces of the two radial bearing gaps are used and that the other two boundary surfaces of the two radial bearing gaps are formed by lateral surfaces of the rotor, which lie parallel to the two end faces of the single hollow cylindrical bearing bush. One boundary surfaces of the two radial bearing gaps and the inner boundary of the axial bearing gap are then the circumferential surfaces of the rotor and all mating surfaces are the outer surfaces of the single hollow cylindrical bearing bush. This can be achieve a high accuracy of the boundary surfaces for all bearing gaps. All Nozzles can then be arranged in the single hollow cylindrical bearing bush. The rotor can consist of a cylindrical body, the length of which is the only hollow cylindrical Bearing bush corresponds to one stub shaft on each end face of the cylindrical Body and a turbine wheel, stuck on one of the two stub shafts, and from an annular flange corresponding in diameter to the turbine wheel, stuck on the other shafts butt, insist.

Another embodiment of the invention relates to training the single hollow cylindrical bearing bush in the event that it is desired, several To attach wreaths of radially directed nozzles distributed in the longitudinal direction of the bearing bush. It is important to achieve an equally strong air pressure on all nozzle rings expedient, within the hollow cylindrical bearing bush a hollow cylindrical Provide channel for pressure equalization in which on the one hand the wreaths of the radially directed Nozzles and, on the other hand, a ring of compressed air supplies open. A bearing bush with such a hollow cylindrical pressure equalization channel most skilled thereby obtained that the bearing bush is firmly joined together from a first hollow cylindrical Body, which at each end of its cylindrical outer surface with an annular groove for one ring each made of elastic material to support this first hollow cylindrical Body can be provided in the housing of the handpiece, and a second hollow cylindrical Body with ring-shaped flanges attached to its two end faces, whose Outside diameter adapted to the inside diameter of the first hollow cylindrical body is to use these flanges with a tight fit in the first hollow cylindrical Body to be able to be inserted. The one between the two flanges Part of the second hollow cylindrical body is then at a distance from the inner surface of the first hollow cylindrical body through which the hollow cylindrical pressure equalization channel is formed.

The pressure equalization channel described above can be in longitudinal grooves divided on the inner surface of the first hollow cylindrical body of the bearing bush be, the number of longitudinal grooves corresponding to the number of nozzles in the Wreaths of radially directed nozzles are provided. On the second hollow cylindrical one Body no flanges are required in this case. It consists of a socket, whose outer diameter is the inner diameter of the first hollow cylindrical body at the points not provided with longitudinal grooves is adapted so that it is firmly seated can be inserted into the first hollow cylindrical body.

Although the invention, the compressed air storage of the rotor is essential can be improved with a very strong working pressure on the rotating tool a grinding of the rotor on the inner surface of the single hollow cylindrical bearing bush enter. To reduce the frictional forces between the rotor and the bearing bush in this case To keep it low, can in the context of the invention when using a rotor made of steel the inside of the bushing is made of carbon.

Further details of the invention are given below with reference to the Figures explained, which represent an embodiment of the subject matter of the invention. It shows Fig. 1 a dental handpiece in side view, in which the head part, in which the compressed air turbine is installed, at an angle to the longitudinal axis of the handpiece is arranged, Fig. 2 in an enlarged compared to Fig. 1 scale an axial Longitudinal section through the head part of the handpiece according to FIG. 1, F i g. 3 shows a cross section according to the line III-III of FIG. 2.

The in FIG. 1 illustrated dental handpiece consists from the handle part 2, the handle 3 angled therefrom, the cylindrical head part 4 with the drill 5 clamped therein and the one inserted into the rear end of the handpiece Hose 6 for supplying compressed air and pressurized water.

According to FIG. 2, the stem 3 of the handpiece 1 ends in a hollow cylindrical one Housing 7 into which the actual air turbine motor is inserted.

The hollow cylinder 7 is closed at the rear by the cap 9, which can be pressed, glued or screwed into the cylinder, the front A corresponding bend of the cylinder forms the end. The hollow cylindrical Bearing bush o is made by elastic rings 11, 12 in corresponding Bends on the one hand of the hollow cylinder 7 or the cap 9 and on the other hand the Bearing bush 10 are held radially and axially in the angle head. The rotor is made from the rotor shaft8, the turbine wheel placed on the rear end of the shaft 27 and the annular flange 28 attached to the tapered front end of the shaft is attached. It is inside the single hollow cylindrical bearing bush 10 in Compressed air bearings held from the single axial bearing gap 17 and the two radial bearing gaps 20 exist. The axial bearing gap 17 is compressed air the channel 13 in the cylindrical head part 7, via a ring of holes 14 and Supplied via rings of radially directed nozzles 16 in the single bearing bush 10. The two radial bearing gaps 20 receive their compressed air via the axially directed ones Nozzles 19 in the bearing bush 10. The supply of the propellant air to the turbine wheel 27 takes place via the channel 23 in the hollow cylindrical housing 7 and the discharge of the relaxed Propellant air and the compressed air used for storage via central openings 25 and 26 in the angled part of the cylinder 7 and in the end cap 9.

The single bearing bush 10 is firmly assembled from several parts, its structure is from FIG. 3 clearly recognizable. The hollow cylindrical counter body 10 a to the rotor shaft 18 with the radially directed nozzle rings - each ring has for example eight nozzles 16 evenly distributed over the entire circumference of the cylinder (F i g. 3) - consists of coal or the like, the outer hollow cylindrical body 10 b for example made of brass. In the inner wall of the hollow cylindrical body 10 b are in the area of each row of nozzles - each row comprises, for example, four nozzles 16 (F i g. 2) - one longitudinal groove 10 c cut into each - so eight with eight rows of nozzles Longitudinal grooves (F i g. 3) - which ensure an even distribution of the compressed air over all Ensure radially directed nozzles 16. For the supply of compressed air to the Longitudinal grooves each have a radially directed bore 14. The two hollow cylindrical ones Bodies are matched to one another in such a way that the outer diameter of the inner body 10a the inner diameter of the outer body 10 b on the not provided with longitudinal grooves 10 c Corresponds to places, so the carbon body is glued into the brass body can. The two end faces of the LagerbuchselO are also made of carbon and are each in the form of an annular disc 10d on the end faces of the Parts 10 a and 10 b glued together hollow cylinder, after previously the axially directed nozzles 19 are drilled. Each nozzle ring 19 consists in this embodiment from only four nozzles, which are aligned with every second longitudinal groove 10 c (F i g. 3) and supplied with compressed air from here.

Claims (6)

Claims: 1. Dental handpiece, containing a compressed air turbine motor, which serves as a drive for a rotating tool that can be clamped into the handpiece and whose rotor is mounted in compressed air bearings, characterized in that for the bearing of the rotor shaft in the handpiece head is a single axial hollow cylinder Bearing gap to the single cylindrical The only one forming the lateral surface of the rotor Hollow cylindrical bearing bush by elastic rings (11, 12), which are angled on the one hand the hollow cylindrical head housing (7) and on the other hand the bearing bush lie, is held radially and axially, that two radial bearing gaps (20) are present are, on the one hand by parts of the end faces of the rotor (18) and on the other hand limited by surface parts lying parallel to these end faces of bearing parts be, wherein in the single hollow cylindrical bearing bush (10) at least one Ring of radially directed nozzles (16) for supplying the compressed air to the only one axial bearing gap is arranged and in which the two radial bearing gaps delimiting Bearing parts several axially directed nozzles (19) for supplying the compressed air to the two radial bearing gaps are provided. 2. Dental handpiece according to claim 1, characterized in that that of the two radial bearing gaps (20) each one on the one hand through one of the end faces the single hohlzylindri's bearing bushing (10) and on the other hand by a too this end face parallel lateral surface of the rotor (18) is limited and that all nozzles are arranged in the single hollow cylindrical bearing bush (10). 3. Dental handpiece according to claim 2, characterized in that that the rotor (18) consists of a cylindrical body, the length of which is the length of the single hollow cylindrical bearing bush (10), from one stub shaft on each End face of the cylindrical body, as well as a turbine wheel (27), firmly seated on one of the two stub shafts, and off one of the turbine wheel in diameter corresponding annular flange (28), firmly seated on the other stub shaft, consists. 4. Dental handpiece according to claim 1, characterized in that that the only hollow cylindrical bearing bush (10) consists of a first hollow cylindrical Body, each provided with an annular groove for one ring (11, 12) made of elastic Fabric at each end of its cylindrical outer surface and with at least one den Bore penetrating the body between the two annular grooves in the radial direction (14), and from a second hollow cylindrical body with on both of its front sides attached annular flanges, the outer diameter of which corresponds to the inner diameter of the first hollow cylindrical body is adapted, with several rings of radially directed Nozzles (16), which penetrate the part of the body lying between the two flanges, and with axially directed nozzles (19) which pass through each of the two flanges, is firmly joined together. 5. Dental handpiece according to claim 1, characterized in that that the only hollow cylindrical bearing bush (10) is firmly assembled from one first hollow cylindrical body (10 b), each provided with an annular bend for one ring (11, 12) of elastic material at each end of its essentially cylindrical outer surface and with evenly around the circumference of its cylindrical Inner surface distributed longitudinal grooves (10 c) as well as with a wreath of the number of Longitudinal grooves corresponding radial bores (14) that make the body enforce in the area of the longitudinal grooves in the radial direction, and from a second hollow cylindrical body (lOa), the outer diameter of which corresponds to the inner diameter of the first cylindrical body adapted to the points not provided with longitudinal grooves is, with several its wall penetrating rings of radially directed nozzles (16), the number of nozzles present in each ring being the number of longitudinal grooves (10 c) corresponds in the first hollow cylindrical body, and with two annular Washers (10et), one of which is one of the two end faces of the bearing bush away- covers and each penetrated at the level of the longitudinal grooves of axially directed nozzles (19) is. 6. Dental hand piece according to claim 5, characterized in that that at least the lateral surfaces used to delimit the bearing gaps (17, 20) of the rotor (18) made of steel and the second hollow cylindrical body (10a) made of carbon exist. Documents considered: German Auslegeschrift No. 1,147,003; U.S. Patent No. 2,602,632; Journal> Feingerätetechnik ", 1960, issue p. 166 to 172.