The invention relates to a ceramic turbine wheel, expecially a ceramic radial turbine wheel for an exhaust gas driven turbine of a turbocharger for motor vehicles, with a body which is formed in one piece with radial blades and a hub which is connectable to a usually metallic turbine shaft.

Background Art With turbochargers for combustion engines in a power range suit- able for motor vehicles, the turbine driving the compressor is fed by the exhaust gas of the combustion engine and to date has usually been constructed out of metallic alloys having high strength at high temperatures.

With reference to the increasing use of turbochargers in auto- mobiles, an increased high temperature strength and an improved behavior of acceleration is desired. These requirements could be fulfilled by the use of ceramic materials in the turbocharger turbine. Ceramic materials, such as silicon nitride or silicon car¬ bide, have a nearly constant high strength in the range of temper- ature under consideration, and have a density which is only one-third of that of a metallic material.

Due to the high temperature strength of such materials, the operating temperatures can be raised without danger, while the mass moment of inertia, due to the relative low density of the ceramic turbocharger rotor, can be reduced to about 40% of the moment of inertia of a metallic type rotor, and therefore, the time of response of the turbocharger correspondingly improves.

The experiments to develop such turbine wheels out of ceramic materials have up to now not yet led to the desired success, as there have resulted difficulties in the production process of the wheel, as well as other problems. Inadmissable defects to the components were found in the preferred, low-cost process, in which the radial turbine wheels, produced out of the ceramic material, are first of all fabricated as so-called green parts by injection molding or slip- casting techniques and afterwards subjected to a burn-out procedure for the binder followed by sintering or nitriding procedures. These

defects are mainly attributed to a prevented escape of the gases produced by the burn-out of the- binder as well as by a non-uniform shrinkage of the wheel with the* solid body of the hub. A central, hollow bore, which would be favorable for the production proc- ess, is however not realizable for strength reasons, as by that sha the tensions resulting in operation would be increased to double th value of a hub without a bore.

The object of this invention is therefore construction of a ceramic turbine wheel, which, although it has a sufficient high temperature strength, does not show the above described difficultie in production.

Disclosure of Invention

This invention, accordingly, provides a ceramic turbine wheel, comprising: (a) a body portion, symmetrical about an axis;

(b) a plurality of blades, integral with and extending o wardly from the body portion; and

(c) a hub portion, integral and coaxial with the body portion, symmetrical about the axis, and connectable with a turbine shaft; characterized in that the body portion is provided with a holl central core, on the side of the body portion opposite the hub portion.

By providing the body portion with a hollow central core, gase can emerge from the burn-out of the binder and escape out of the bo so that the formation of flaws is largely prevented.

In addition, according to this invention, the portion of the turbine from which the blades extend outwardly, will become more elastic, so that deformations of the blades can be taken up sooner without damage.

A radial turbine wheel, designed according to this invention, producible without large difficulties by inexpensive production pro esses like injection molding or slip casting out of ceramic materia e.g. silicon nitride and silicon carbide, wherein particularly the

O

before mentioned difficulties in the necessary procedures of burn¬ out of the binders as well as in sintering and nitriding are prevented.

Especially with the material alpha silicon carbide, which shows in the mentioned production processes under high temperatures a large shrinkage, this design enables production with substantially reduced difficulties. See U.S. Patents 4,124,667 and 4,144,207, regarding sintering and injection molding of alpha silicon carbide.

In addition, the design of the hub, according to the invention, results in a further reduction of the mass moment of inertia, already lowered by the use of ceramic material.

Brief Description of Drawing

In the drawing an example of design of the invention is shown, which will be explained in the following. The drawing shows sche- atically a presentation of a cross section, according to the invention, of a preferred embodiment of a ceramic radial turbine wheel for the turbocharger of a combustion engine for a motor vehicle, in which the hub portion is cylindrical.

Best Mode for Carrying Out the Invention

In the drawing there is designated by 1, the radial turbine wheel as a whole; by 2, the blades which extend outwardly, usually radially, from the body portion; and by 3 the body portion, which is formed in one piece with blades 2 and the hub portion 4. The hub portion 4 is provided for connection with a usually metallic, so e- times ceramic turbine shaft, which is not shown here.

The blades 2 are described as "radial", i.e. not "axial". In the turbocharger art, the two main types of blade arrangements are "radial" and "axial". In the "radial" type, portions of the blades 2, near the hub portion 4, are located along radii of the body portion 3; and portions of the blades 2, further from the hub portion 4, are curved gently in the same direction.

According to the invention, the body portion 3 has on the side opposite to the hub portion 4 a hollow central core 5, whose outer diameter, designated with D--, should preferably not exceed

smallest outer diameter, designated with D ₃ . . of the body portion 3; and whose length, designated with Lr, should preferably not exce 60% of the axial blade length, designed by L. It should be noted that Lc extends only from the base of the hollow central core 5 to the extremity of the blades 2, and not to the extremity of the hollow central core 5. In other words, at least 40% of the blade length L should extend from a non-hollow part of body portion 3. With such proportions, no noticible increases in tension appear in the body portion 3. In the case of less stressed turbine wheels, t hollow central core 5, rounded at its bottom, could be placed even deeper, in consideration of expediency.

It is preferred that the minimum outer diameter, D-, . , of the body portion 3, be at the side of the body portion 3 opposite to th hub portion 4, and that the maximum outer diameter, D ₃ , of the body portion 3, be at the side of the body portion 3 adjacent to th hub portion 4, of the turbine wheel 1.

For the relative proportions of the outer diameters D., . and ^D 3max ^ ^ ^s P ^reτ"errec * that these should amount to about 25% and 50% respectively, of the outer diameter of the wheel, D. In following these rules, in view of strength and production requirements, an optimized turbine wheel can be obtained.

The hub portion 4 preferably has a diameter D» of about 15 to 25%, more preferably 15 to 20%, of the outer diameter D of the whee According to one preference, the hub portion 4 has a length L _* of, at most, twice its diameter D-. According to another preferenc the hub portion 4 is integral with the shaft, not shown. The shaft can be either a solid or hollow cylinder, made as an extension of hub portion 4, ranging from about 6 up to about 12 times the diameter D, of the hub portion 4. On the hub portion 4, as shown in the drawing, there can optio ally also be provided a hollow central core 6, rounded at its botto whose diameter D _β amounts to at most up to about 60% of the diamete of the hub portion 4 and whose length L _fi is at most 60S of the leng L _* of the hub portion 4. Finally, at the transition 7 from the hub portion 4 to the bod portion 3, there should preferably be provided a radius of at least 20% of the diameter of the hub portion 4.

By adherence to these rules of dimension for the production out of ceramic materials an optimally designed radial turbine wheel results, which offers favorable properties regarding to its strength as well as regarding to its production process. The embodiment shown in the drawing has a cylindrical hub portion 4. In the case of an alternate conical design of the hub portion 4, not shown, the basic diameter measured at about 60% of its length, measured from its end, corresponds to the diameter D, of the cylindri¬ cal design. The cone angle of this design can amount to between 20° and 30° inclusive, preferably about 25°.

Also, this conical hub portion, in consideration of expediency, can possess a hollow central core, whose diameter is at most 60% of the minimum diameter of the conical hub portion and whose axial length is at most 60% of the length of the hub portion. In addition, it is advantageous that the hollow central core, according to this embodiment of the invention, is rounded at its bottom.

Finally, it is suggested that, as with the cylindrical embodiment, the transition from the conical hub portion to the body is rounded with a radius of at least 20% of the diameter of the hub portion.