DE3016817A1 - High strength gas turbine rotor - has ceramic blades extending radially inward from cylindrical metal rotor body wall and radially outward stator blades - Google Patents

Abstract

The gas turbine rotor has high mechanical strength at elevated temp. so that it can be run at higher temp. and/or speed than hitherto used. It comprises a hollow metal cylinder (1) having high temperature-resistant ceramic rotor blades (2) (e.g. in silicon carbide, silicon nitride, boron nitride etc.) secured on its inner wall so that the blade tips point radially inward. The stator blades (4) point radially outward and are fixed on a stator ring concentrically arranged within the rotor. The outer wall of the rotor provides the bearing surface for bearings (3) arranged in the turbine housing and is provided with seals (5) and external teeth (6) to transmit the developed power.

Description

Gas turbine rotor with extremely high heat resistance.

The invention relates to a gas turbine rotor with extremely high heat resistance.

The higher the heat resistance, the higher the efficiency of a gas turbine of the materials used. A good overview of the state of the art in the realization of gas turbine rotors with high heat resistance one can found in P. Walzer et al in MTZ-Motortechnische Zeitschrift- 37 (1976) 11 + 12, page 479-489,525-529 and at.Siebmanns in reports of the German Ceramic Society Volume 55 (1978) number 8 page 406409.

From these two examples it can be seen that it has not yet succeeded is to design gas turbines that are more efficient than equivalent Diesel engines or steam turbines. It is particularly problematic in gas turbine rotors high heat resistance.

The invention is based on the object of having a gas turbine rotor to create higher heat resistance than in previous gas turbines.

The task will be f i n u n g s m ä ß å g d a d u r c h g e l ö s t that the impeller made of metal (1) is designed as a hollow cylinder, and that on the inner jacket of the hollow cylinder, the impeller blades (2) made of high-temperature ceramic (for example SIC, SI3N4, BN) are attached. In previous constructions are the vane rivers attached to the outside of the impeller cylinder, and the ends the The blades point in the direction of the housing. In this design are the shovel feet attached to the hollow cylinder inner jacket, and the ends of the blades show in the direction of the hollow cylinder center line. The fixed guide vanes of the stator (4) are attached in the same way as the rotor blades in previous designs. Of the The outer jacket of the hollow cylinder is used for bearing (3) the impeller, for discharge of the torque (6) and the Kilhluneg of the metallic hollow cylinder.

This construction of a gas turbine rotor has the following advantages: - The ceramic, which in previous constructions mainly as a result of centrifugal force was subjected to tensile force, in this construction is only dependent on compressive force mainly used. As is well known, the compressive strength of all ceramics much higher than their tensile strength. It is one with this composite construction Material-appropriate loading of metal and ceramics realized. The ceramics is mainly subjected to compressive stress at high temperatures and the Metal parts mainly on tensile stress at low temperatures. The ceramics also serves as a heat insulator to keep the low temperatures of the metal hollow cylinder to enable.

- That is why there is a higher maximum process temperature and a higher one Impeller speed than previously possible.

- The shovel attachment can be realized without sharp notches.

- The ceramic geometry is simpler and has smaller dimensions than before, which leads to more homogeneous ceramics with better Weibull factors and which also increases the thermal shock stability of the ceramic elevated.

- Each ceramic part is non-destructive for homogeneity before installation testable, which further improves the Weibull factor.

- Ceramics can also be used that only have high compressive strength and whose tensile strength is very small.

As an exemplary embodiment of the invention, I have used a Curtis turbine. There are other types of turbine impellers as embodiments of this invention (for example according to Laval, Zoelly and Parson) conceivable. The drawing (Figure 1) should serve only to explain the principle of the invention.

Important individual parts of the exemplary embodiment are: (1) impeller, (2) Impeller blades, (3) impeller bearings, (4) stator for stator attachment, (5) seals, (6) gear. The mechanical energy could be due to the high speed of the rotor can also be removed favorably with a friction wheel or electromagnetically by induction. The optimal arrangement, selection and dimensioning of the seals, bearings and other details must be determined by experiment and depending on the application.

Claims (1)

Claim. Gas turbine rotor with extremely high heat resistance d a d u r c h g e It is not shown that the impeller is made of metal (1) and is a hollow cylinder is, and that the impeller blades (2) on the inner surface of the hollow cylinder High-temperature ceramics (for example SIC, SI3N4, BN) are attached. With previous Constructions, the blade feet are attached to the outside of the impeller cylinder, -and the ends of the blades point in the direction of the housing. With this construction The blade feet are attached to the inner shell of the hollow cylinder, and the ends of the blades point in the direction of the hollow cylinder center line. The fixed ones The guide vanes of the stator (4) are attached as in previous designs the blades. The outer jacket of the hollow cylinder is used to support the impeller, to derive the torque and to cool the metallic hollow cylinder.