DE977380C - Adjustable diffuser for jet engines with supersonic flight speed - Google Patents

Description

Adjustable diffuser for jet engines with supersonic flight speed The appropriate design of a multi-impact supersonic diffuser is simple if the engine, to which the supersonic diffuser feeds the combustion air, only ever works at a certain operating mach number. Constructions can be made for every Mach number specify multiple shock diffusers that work optimally with the Mach number in question. But since an engine always works over a certain Mach number range must (when starting from Mach number zero starting up to the Labor Mach number and ascending), operational difficulties arise with one designed for the marching number optimal supersonic multiple shock diffuser. In particular, one shows for a marching figure designed multi-impact diffuser is not always the right one for smaller Mach numbers Mass flow and in its narrowed 'feil a completely inadequate geometry, which leads to blockages in the inlet. At the start, however, there is a high mass throughput and good compression is required in order to quickly reach the favorable design march number to be able to come. This has led to the fact that in modern turbo and ramjet engines adjustable inlet diffusers are used. A multi-bump diffuser can work with flat or rotationally symmetrical impact or abutment surfaces.

To explain these known diffuser designs, reference is made to Fig. I and a referenced. Fig. 1a shows a planar three-impact diffuser at smaller Mach number, Fig. I b a planar three-impact diffuser with a high Mach number, Fig. 2 a shows a rotationally symmetrical three-impact diffuser with a small Mach number, FIG. 2 b a rotationally symmetrical three-impact diffuser with a high Mach number.

The numbers i, 9, 17.25 mean streamlines of the outer flow, 2, ro the first abutment surfaces (wedge) resp.

18,26 the first abutment cones, 3, i r the second abutment surfaces and 19,27 the second shock cones, 4,12,20,28 the traces of the first compression shock, 5, 13,: 21,: 29 the traces of the second shock wave, 6, r4, 22, 3o the traces of the third Compression shock, 7, 15, 23, 31 the diffuser cutting edge, 8, 16, 24., 32 the subsonic parts of the diffuser. The flat diffusers have various disadvantages: moderate quality, Necessity of boundary layer suction. It also prepares the transition from the flat Diffuser in the rotationally symmetrical compressor part of the engine difficulties.

Diffusers are also known, each consisting of several parts, which are displaceable in the axial direction, the air flow in every position the axially displaceable parts passes between these parts. So it will the air flow through several annular blades in several essentially parallel flow paths divided up. While with these diffusers the usable transverse cross-section of a If the occurrence is to be changed, the object of the invention is based on the task the highest pressure recovery at any blow Mach number through a variable To achieve contour, so. just redirect the airflow.

There are also multi-impact diffusers, including Oswatitsch diffusers or cone diffusers called, known, in which conical oblique angles are formed by a series of coaxial cones Compression shocks are triggered. The opening angles of the cones are adjusted, namely by means of thin mutually adjustable, overlapping metal sheets, which together form a cone. These sheets are inclined with respect to the direction of flow. So there can only be broken ones, from conical ones, straight on the surface line limited pieces composed, the abutment surfaces formed body as far as they are rotationally symmetrical diffusers. It follows from this that with such diffusers one is not in a position to achieve that to generate the necessary curved contour of the shock-free Prandtl-Meyer flow. as Adjusting means are used eccentrics in such diffusers.

In contrast, in diffusers according to the invention, a Prandtl-Meyer flow is intended can be achieved in which most of the compression occurs smoothly isentropically goes, whereby it is irrelevant whether the compression field with a weak leaning Shock begins or not, and that the compression field downstream by a straight Push finds its limit. In the Prandtl-Meyer flow, the flow becomes deflected smoothly on a curved contour. That such diffusers with the "Prandtl-Meyer contour" the "Oswatitsch cone multi-impact diffusers" in relation to the level of pressure recovery are superior is known, but has not yet been exploited because the Prandtl-Meyer-Kontur only works satisfactorily with the Mach number, for which it is designed so that even with a small change in the Mach number, a completely another contour is required for good pressure recovery.

The invention is intended to remedy this deficiency. It will therefore, starting from adjustable diffusers for supersonic blowing with a multi-part, the abutting surfaces having body, its parts as a function are mutually adjustable by the respective Mach number, proposed according to the invention, the body having the abutment surfaces from a package can be displaced against one another To let layers exist whose layer boundaries are parallel or nearly parallel run towards the direction of flow. The shifting of the layers is dependent controlled by the flight and flow condition, for example by eccentrics. Also at As is known, it is recommended for these diffusers to the one having the abutting surfaces Assign body suction channels and these as that of the blown step-shaped Forming contour braked boundary layer material discharging channels, their total passage cross-section should be changeable depending on the shift of the layers. Act If it is a planar supersonic diffuser, then the layers consist of planes Panels, it is a rotationally symmetrical supersonic diffuser, then the layers consist of thin-walled, coaxially arranged hollow cylinders. the The front surfaces of the layers which run obliquely to the direction of flow are expediently designed in such a way that they form a smooth, closed surface at the Marschmach number.

By adjusting the layers against each other, you can adjust the abutment surfaces give a desired contour. The stepped surface is the previous smooth one Only a slight disadvantage compared to surfaces. With enough small and enough in many stages the current envelops the layers of layers. About effective suction To reach the braked boundary layer material, you can use the suction channels like this arrange and design that when shifting the layers in any direction, for example, transverse to the direction of flow, the total cross-section of the suction channels is enlarged or reduced while shifting the layers in order to Change of the surface contour of the diffuser in the direction of flow should take place. As a flat diffuser is to be designed, FIGS. 3 a and 3 c show; the design a rotationally symmetrical diffuser is shown in FIGS. 4a and 4c.

In Fig. 3a, the layer package forms the contour of a so-called Prandtl-Meyer diffuser (English: isentropic diffuser) for a small Mach number.

3b shows the pattern of the suction channels of two layers; Fig. 3c illustrates the same diffuser as a Prandtl-Mever diffuser adjusted for a higher Mach number and Fig. 3d shows the pattern of the suction channels between two superposed plates according to the embodiment of Fig. 3b, from which it follows that the suction with increasing Mach number has been reinforced.

FIGS. 4a and 4c show a rotationally symmetrical adjustable diffuser with Prandtl-Mever contour for two different Mach numbers, while FIGS. 4b and 4d show the diagrams of the suction slots for a small Mach number and for a large Mach number.

The streamlines are with 33, 45, 57 and 66, the Mach lines with 34, 46, 58 and 67, the final joint with 35, 47, 59 and 68, the plates of the stack of layers with 36, 48 and the hollow cylinders of the stack of layers with 6o and 69, pivot bolts with 37 and 49, sliding bolts with 61 and 70, eccentric discs with program contour with 38 and 5o, rotating arms with program contour with 62 and 71, suction channels with 39, 51, 63 and 72, the upper cover plates with 40 and 52, the diffuser cutting edges with 64 and 73, suction channels in the top plate with 43 and 55, suction channels in the bottom plate with .14. and 56 and the subsonic part denoted by 65 and 74.

Claims (6)

PATENT CLAIMS: i. Adjustable diffuser for jet engines with Supersonic flight speed, with a multi-part, the impact surfaces having Body, the parts of which can be adjusted against each other depending on the respective Mach number are, characterized in that the body having the abutment surfaces consists of a Package consists of mutually displaceable layers, the layer boundaries of which are parallel or run almost parallel to the direction of flow. 2. Inlet diffuser according to claim i with the suction channels associated with the body having the abutting surfaces, thereby characterized in that the channels as that of the blown step-shaped contour braked Grenzschichtma.terial are designed to dissipate. 3. Inlet diffuser according to claims i and z, characterized in that the total passage cross-section the channels can be changed depending on the shift of the layers, 4 .. Fin run diffuser according to one or more of claims i to 3, characterized in that that the layers when arranged in a planar supersonic diffuser made of planar plates exist. 5. inlet diffuser according to one or more of claims i to 3, characterized characterized in that the layers when arranged in a rotationally symmetrical Supersonic diffuser consist of thin-walled, coaxially arranged hollow cylinders. 6. Inlet diffuser according to one or more of claims i to 4 or i to 3 and 5, characterized in that the front surfaces of the layers which run obliquely to the direction of flow are designed so that they form a smooth closed surface at the Marschmach number. Documents considered: German Patent No. 964 193; French Patent Nos. i 147 igi, 995 173; U.S. Patent Nos. 2,638,738, 2,540,594.