DE1286333B - Ring-shaped guide device for gas turbine engines with axial flow - Google Patents

Description

Measurement cross-sections carried out and the emergence of excitation forces accepted, with attempts have been made to keep these excitation forces within acceptable limits. For example, -5 wise the guide device as a one-piece ring with the same flow cross-sections between adjacent ones Shovels made. This ring was then divided into segments that were in the engine with mutual Spacing were installed. These segments

adjacent segments smaller than the cross-sections between the other blades. This difference is determined by the thickness of the slot that is created when the ring is cut into segments.

However, there are numerous cases in which the excitation forces are created by unequal flow cross-sections cannot be admitted. Guiding devices must therefore be provided, which at normal operating temperature between

Such guide devices can expand at the operating temperature in such a way, both turbines and compressors can be provided. Before they touch each other. The guide device according to the invention will therefore be in contact with one another, in order to reduce leakage losses between the combustion chambers and the turbine wheel. When such a guide device of a gas turbine engine is arranged around the hot normal operating temperature, combustion products are to be fed to the turbine wheel, the cross sections leading between the end blades. The guiding device converts the flow of the
hot combustion products, the high pressure
into a stream at high speed
around; this is guided against the turbine wheel at the required angular direction. The force, 20
which the hot gas flow exerts on the turbine wheel,
depends on both the speed and on
the direction of flow; they are therefore around the
Circumference of the turbine wheel around only then

same when the flow is uniform through the guide 35 adjacent blades see equal cross-sections Device is fed. exhibit. For this purpose, a one-piece ring

If, however, a turbine wheel is manufactured around its construction, but the blades around which are unequal forces, then the same distances can occur, that is, unequal cross-sections, damaging vibrations can occur. If namely exist between adjacent blades. This lent the turbine wheel rotates, so the individual guide device is then again subjected to pulsating forces in segments, which are divided into blades and which are installed in the engine. The undesired vibrations and loads create unequal distances between the blades. If these excitation forces counteract the width of the cut-out material sufficiently strongly, they can destroy the turbine runner. rials in such a way that at normal operating temperature it is therefore of great importance that the flow 35 all flow cross-sections in the guide device of the hot gas in such a way towards the turbine runner are the same. Such guiding devices are directed, however, that around the entire circumference of the
Impeller around the same forces are exerted.
This can be done in such a way that all flow cross-sections between adjacent blades of the 40th
Guide device at normal operating temperature
are the same as the local forces of the hot combustion gases through these flow cross-sections
are determined.

In practice, however, it has not been so far 45
teres possible to realize this in a simple manner. A guide device, which has the same flow cross-sections between adjacent blades, can be designed as a one-piece ring. A
However, such a structure cannot always be implemented because of the temperatures one at a time from the center at equal intervals to which the guide device is exposed during operation in the circumferential direction on both sides. Because of the bore and a larger bore or high thermal stresses occurring, the longitudinal slot is slidably attached to the support ring. As is well known, the guiding device is often divided into segments. these segments have circumferentially shaped and guided expansion enables a gap against each other so that they can be In the drawing, an embodiment of the

extremely difficult to manufacture and because of the unequal spacing of the blades required so very expensive.

The present invention has for its object to provide a guide device in which with The simplest means ensured the same spacing of the blades from one another at any operating temperature will.

According to the invention this is achieved in that the annular flange of each segment by means of a screw bolt, which is arranged in a fitting bore located in the circumferential direction in the middle of the segments is. firmly and by means of two screw bolts that are inserted into

expand and contract with temperature changes. When expanding neighboring Segments move the end blades towards each other. However, this reduces the current flow cross-section between these blades, while the adjacent blades are within the Move individual segments away from each other, so that the flow cross-section between them

Invention shown. It shows

F i g. 1 a longitudinal section through the guide device,

F i g. 2 shows a cross section through FIG. 1 along line 2-2,

FIG. 3 is a view of a segment from plane 3-3 of FIG. 1 and

F i g. 4 shows an angled circumferential section longitudinally

Shovels enlarged. The line 4-4 in FIG. 1.

feared uneven loading of the door. Part of a gas turbine engine is shown in FIG. 1

inner wheel a. shown, which has a housing 10, which consists of

So far there has been an operation with unequal Strö ring sections 11 and 12, which are attached to the flanges

13 and 14 see one another by means of screw bolts 15 are attached. An annular space 16 is formed between the housing 10 and an inner load-bearing component 17 formed. An annular combustion chamber 18 with an inner space 19 lies within the annular space 16.

An annular guide device 20 is arranged at the rear end of the combustion chamber 18 to the hot combustion products the turbine blades 21 at the appropriate speed and to feed at the right angle.

The guide device 20 is composed of segments 25. Each segment 25 has an outer one Ring 26, an inner ring 27 and a number of blades 28 which extend radially between the rings 26 and 27 are arranged and attached to them. * 5 A flange 31 extends radially from the outer ring 26 near the trailing edges 30 of the blades 28 outward. A flange 32 extends radially inward from the inner ring 27. A bore 33 is arranged in the flange 32 in the circumferential direction in the center of each ao segment 25; there are also holes 34 and 35 are provided at the same distance from one another on both sides of the bore 33 in the circumferential direction. The bores 34 and 35 can have larger diameters than the bore 33, as shown is. Lugs 36 and 37 are provided on one end of the outer ring 26 and the inner ring 27. The lugs 36 and 37 extend circumferentially beyond the end of the rings and overlap the ring ends of the adjacent segment 25 in the assembled state to the To reduce leakage flow.

Each segment 25 of the guide device 20 can extend over 60 °, which has proven to be advantageous has, and is manufactured according to the usual manufacturing technology. The parts of the segments 25 can be made for example from sheet metal and be welded together. The segments 25 can but can also be cast as a single component and then machined. The guide device 20 can also consist of twelve 30 ° segments. In general, any number of segments can be used by which the total number of blades is divisible. This will ensure that everyone Segments have the same number of blades.

The bores 33, 34 and 35 are arranged in the flange on a certain radius R ₁ , which starts from the center of curvature of the segments. As in Fig. 4, the blades 28 of each segment 25 are attached to the outer ring 26 and the inner ring 27 such that the flow areas, which are proportional to the distance T between adjacent blades, are equal. Since the circumferential distances X between adjacent blades 28 are proportional to the distance T , the same flow cross-sections between adjacent blades 28 can be ensured in that the circumferential distances X between adjacent blades 28 are the same. The outer ring 26 and inner ring 27 of each segment 25 extend circumferentially beyond the end vanes of the segments by circumferential distances Y and Z at opposite ends of the segments. There is no prescribed relationship between the sizes of the distances Y and Z except that their sum must be equal to the distance Z. It is clear that the flow cross-sections between all blades 28 of the guide device 20, including the flow cross-sections between the end blades of adjacent segments 25, are the same when all segments 25 bear against one another. Assuming tension-free expansion and contraction, this applies to every temperature at which the segments 25 come into contact with one another.

As the F i g. 1 and 2 show, a conical support ring 40 is attached to the component 17, for example by means of screw bolts 41. This has bores 42 which are arranged at a distance R ₂ from the axis of the engine. The distance between the bores 42 in the circumferential direction is the same as the distance between the bores 33, 34 and 35 of the segments 25. These are arranged in the gas turbine plant such that the bores 33, 34 and 35 are each aligned with one of the bores 42. First, a screw bolt 43 is passed through each bore 33 and the associated bore 42. The screw bolt 43 and the bores 33 and 42 have a snug fit so that the center of the segment 25 is held in an exact position. The bolts 44 and 45 are loosely received in the bores 34 and 35 so that the ends of the segments 25 can expand and contract circumferentially relative to their fixed means. If it is desired to make the bores 34 and 35 as large as the bore 33, the screw bolts 44 and 45 must have a smaller diameter than the screw bolt 43. If the segments 25 have a tendency to tilt around the bolts 43 , instead of the bores 33 and 34, elongated slots can be formed in the circumferential direction.

When the segments 25 are mounted at a distance R ₉ from the axis of the engine, there is a gap C between adjacent segments 25, since R _{2 is} greater than R ₁ . The radii R ₁ and R ₂ and the gap C are selected such that the segments expand at the normal operating temperature of the guide device 20 in such a way that they abut one another. Then the flow cross-sections between all adjacent blades 28 of the guide device 20 are the same at the normal operating temperature.

The particular choice of R ₁ , R ₂ and C will depend on a number of factors which must be determined with respect to the particular engine in which the control device 20 is to be used. For example, consideration must be given to the particular material from which the segments 25 are made, as different materials have different coefficients of thermal expansion. The normal operating temperature of the baffle and the temperature at which the segments 25 are assembled must also be taken into account. Furthermore, the expansion of the ring 40 must be taken into account. This expansion is generally relatively small since the ring 40 is exposed to the relatively cool, compressed air in the space 16 and not to the hot products of combustion.

To hold the guide device 20, a flange 46 extends radially from the housing 10 inside, on the downstream side of the flange 31, which extends from the ring 26 to the outside extends. The high pressure combustion products entering the baffle 20 enter, the flanges 31 hold against the flange 46.

Lugs 36 and 37 overlap the joints between the rings of adjacent segments 25. Die Lugs prevent high-pressure air from leaking out of the annulus 16 through the joints into the areas under relatively low pressure on the Trailing edges 30 of blades 28.

It can be seen that the constructed according to the invention Guide device at normal operating temperature, the same flow cross-sections between all Has shovels. The invention is applicable to any stator assembly which has significant temperature changes exposed during operation.

Claims (1)

Claim: ¹ p Annular guide device for gas turbine engines with axial flow, which at least has two segments carrying guide vanes, which in the circumferential direction against each other such a gap and one radially inwardly extending on a support ring attached annular flange have that the end parts of adjacent segments at operating temperature abut one another, characterized in that the annular flange (32) each segment (25) by means of a screw bolt (43) which extends in a circumferential direction in the center of the segments located fitting bore (33,42) is arranged, fixed and by means of two Screw bolts (44,45), each one from the center at equal intervals in the circumferential direction fitting bore (42) located on both sides and a larger bore or a longitudinal slot (34,35) is slidably attached to the support ring (40). 1 sheet of drawings