DE1919310A1 - Turbine rotor - Google Patents

Description

191931Q

Applicant: Aerostatic Limited

AO Nuffield Road, Nuffield Industrial Batate, Fleets Bridge, Poole, Dorset, England

"Turbine rotor"

The invention "relates to turbines such as Gas turbines.

¹ Ss is the object of the invention to provide an improved turbine rotor.

The turbine rotor according to the invention is characterized by an outer annular part, a coaxial part with a radial spacing an inner annular member disposed from the outer annular member and one between the inner and outer Part of the planned first turbine spoil. Within the A second turbine blading can be arranged in the inner annular part and / or outside the outer annular part be. The outer and / or the inner annular part can or can be elongated and tubular. In the case of a gas turbine, for example, it is the compressor part driving turbine part arranged within the compressor part, both enclosed in a single rotor are. This not only reduces the overall axial length of the rotor, but it is also achieved that a single one

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Bearings or a single set of bearings is sufficient to do both. To hold both the drive and the output part »

The outer and inner annular part can be of the first turbine blades coaxially with a radial spacing being held.

In operation, a turbine rotor, for example the The rotor of a gas turbine can be exposed to relatively high temperatures if combustion products are used for propulsion.

_fc A major problem in the design and operation of gas turbines is that the high temperatures and strong centrifugal forces that occur cause some materials that are used to construct the rotor and its blades to creep. That is why special types of steel and alloys are produced. “However, the extreme conditions mean that disruptive factors in the operation of such gas turbines and steam turbines cannot be eliminated.

It is well known that certain ceramic substances

* Can withstand increased operating temperatures, but they are very brittle and can break much more easily than metals under stress. Nonetheless, certain ceramics, particularly silicon nitride, can withstand high temperatures and be desirably machined with compressive strengths in the range of 200/300 meganewtons / m . ■

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According to a further feature of the invention, the inner ring-shaped part of ceramic material, which is held τοη an externally radially arranged enclosure «, In particular, the second door hinge blading can be made of ceramic Material "exist.

The rotating parts are designed in such a way that the

Ceramic material of rigid retaining elements radially on the outside is held »It follows that the ceramic material, as far as the" centrifugal forces occurring at high speed are affected, worked under pressure

In an advantageous construction of a machine that has a gas turbine and one driven by the turbine Has compressor, are the gas turbine part and the compressor part coaxially arranged In this construction, the outer bracket for the ceramic parts of the rotor Part of the compressor itself, for example an essentially tubular holder for a compressor blade, be «, with such a construction the ceramic absorbs Material, silicon nitride, due to its extremely stable conditions at elevated temperatures the generated Heat while the outer steel bracket from the cooler air pumped through the outer compressor area, is kept at a much lower temperature.

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In certain cases it is desirable to have all storage means for a turbine rotor one or more fluid bearings eu use. It has been found that ceramic material, in particular silicon nitride, can be used advantageously, to form the bearing surface that forms the bearing gap of such fluid bearings limit, and in particular to ensure reliable operation and to achieve insensitivity to damage and abrasion, if the bearing surfaces accidentally come into contact with each other at high speed.

w The ceramic material is preferred for the radial

outboard of the two bearing parts used, of which the Bearing gap is formed. If the outer bearing part is stationary, it is not subjected to any centrifugal tension forces, but is only under a radially effective pressure, which is exerted by the fluid in the bearing gap.

According to a further feature of the invention, the turbine rotor is supported by one or more fluid bearings. In a first embodiment, a fluid axle bearing is provided, the bearing gap of which is radially outside the outer annular one Partly is arranged · Preferably the bearing gap bounded inside by the outer annular part. This facilitates the manufacture and supply of the or each bearing facilitated and both axially and radially a crowded one Construction of the rotor allows.

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Such a construction also permits a most composite construction in which each separate unit consists of a many units of existing rotor on the same axis and each rotating unit at different speeds. which depend on changes in the angle of the turbine blade being driven, whereby different pressure ratios can be obtained in each unit.

Another embodiment is a fluid axle bearing vorgesshea, the bearing gap of which is radially inside the Prepare Turbine blading lies in the third ring-ferrous TtIl can be arranged coaxial old radial »distance within the inner annular part and delimit the bearing area radially on the inside.

In the drawings, the three exemplary embodiments of the door * bines with rotors according to the invention seigen, lsti fig 1 an axial section through a first execution

example of a multi-stage coaxial gas turbine with schiits-like fluid bearingsj

Tig. 2 shows an axial section through a further exemplary embodiment of a multistage coaxial gas turbine with slot-like fluid bearings, and

3 shows an axial section through a multistage coaxial turbo compressor with schiltz-like fluid bearings. Pig. 1 leigt a self-propelled gas turbine, the two having axially spaced apart rotor units, each a driven turbine element 1 made of ceramic material

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BAÖ ORIQJNAL

exhibit. The turbine elements in one compreeaer element: 2 bearings made of steel. For example, silicon nitride is used as the ceramic material.

Each turbine element 1 waiat a hub 3, dia dia Task has

a) to include centrifugal clutches 4 working with centrifugal force,

b) to carry driven turbine housing 5 aua ceramic material, and

"ο) a with a tubular ceramic-without llemant 6 a Channel for dia varnish saga su an Auapuff xu form.

Sa «tubular ceramic hernent 6 is in a tubular tail 7 daa compressor element Z made of steel galagart and is held by this galagan the effect of forces acting radially outwards.

Daa Kompreaaorelement 2 consists of dam tubular tail 7, compressor blades 8, the radially extending from dam T "il 7, j and an outer tubular member 9 · Di · cylindrical Aufanfläche dea T _e iles 9 forms the inner Begrenmungsfläche a radially outside this part 9 lying gap 10 of a fluid bearing. The outer boundary surface of this gap 10 consists of the cylindrical inner surface of a ceramic ring device which belongs to a pair of ceramic ring devices 11, so that each rotor unit is one of two

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axially, .spaced, cylindrical fluid bearings will. The parts 9 are each axially supported between two annular walls 12, and each end part and the adjacent one annular wall delimit fluid pressure bearing gaps 13 ·. Each rotor unit is consequently of the fluid pressure bearings in held against axial forces in each direction. The cylindrical column 10, which serve as the axle bearing column, are via lines. 14, which are connected to the annular storage spaces 15 stand, fed with pressurized fluid. The ceramic ring devices 11 each consist of a cylindrical Sleeve 11 yes and two. End parts 11b and 11 pounds. The axial End faces of the sleeve 11a are axially cut so that a number of symmetrically equidistant from one another arranged angular recesses with parallel sides is formed. A flat radial surface of the respective end portions 11b and 11 £ rests on each recessed end face, so that a number of feed slots are formed that are distributed over the perimeter of the storage area and a connection between the storage spaces 15 and the gap

10 of the fluid bearing. Any ceramic ring device

11 has two axially spaced circumferential rows of this type Slits open.

Method of making such slots and structures of fluid bearings with such slots are disclosed in British Patent Nos. 1099560 and 1099730 as well in published British Patent Application No. 1555330

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ORDINAL

191931Q

and 1146313 of the applicant in detail " In addition, UK Patent Applications No. 279O4- / 67, dated June 16, 1967, relate to it

No. 48068/67 of October 23, 1967 No. 48931/68 of October 15, 1968

the applicant the same subject matter as the above Pre-publications "

The fluid pressure bearing columns 13 are all fed with fluid that comes from the ends of the respective column 10 of the axle

camp escaped. =.

During operation, air is sucked in through an inlet 16, which flows through fixed guide blades 17a and onto the Strikes compressor blades 8 of a rotor unit. Afterward If the air flows through the second stationary guide blades 17b and hits the compressor blades 8 of the other rotor unit, the air then flows through the third stationary one Leaflets 17 pounds and through ducts 18 which lead the air to a Return combustion chamber 19, which is via a nozzle inlet) direction 20 is fed with fuel. The combustion gases then flow through first stationary guide blades 21a, then through the turbine blades 5 of one unit of the rotor, through second stationary guide blades 21b the turbine blades 5 of the other rotor unit and through third stationary guide blades 21c_, whereupon they finally can be delivered through an output 22.

An output shaft 23 serves to take off the power separately driven turbine 23a.

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In this embodiment, the "outer ring-shaped part" mentioned in the introduction to the description the "two outer tubular parts 9 meant, which each form the inner boundary of an axle bearing gap" .. The "inner annular part "" refers to the establishment of the tubular ceramic element 6, which sits in the tubular part 7 made of steel. The "first turbine blading" "refers to the rotating compressor blades 8. The "Second turbine blading" "refers to the rotating one driven turbine blades 5

In Fig »2 a similar, multi-stage gas turbine is shown, which differs from the gas turbine shown in Fig. 1 essentially in that the two rotor units are each carried by two fluid axle bearings, which are in the rotor itself and not on the outside of the "outer" annular part "are stored.

The rotor has two rotating units A and B arranged at a distance. These units each consist of an outer shell 24 made of steel, a ceramic ring and ceramic compressor blades 25, which are mounted in the shell made of steel and are held by it, an inner ceramic Hing 26, driven ceramic turbine blades 27 and a ceramic hub 28 _o The two units A and B are each fixed between sheets C, D and E, which are provided in pairs.

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Fluid axle bearings for each of the rotor units have cylindrical bearing gaps 29 located within the second turbine housing 27, each of which is delimited by an outer cylindrical surface of the hub 23 and an inner cylindrical surface of a stationary body 30. In each body 30 a ceramic 3ing device 30a according to FIG. 1 is provided in order to feed the bearing gap 29 with fluid via slots. Each body 30 has a storage space 31 which is fed via lines 32. It can be seen that the "outer annular member" refers to the steel shell 24 and the ceramic material contained therein. The "inner annular part" refers to the ceramic ring 26. The "first turbine blade" refers to the compressor blades 25. The "second turbine blade ^11" refers to the driven ceramic blades 27. The bearing gaps 29 are formed by bearing elements (Hub 28, body 30), which are arranged radially inside the turbine blades 27. The "third annular part" refers to the body 301 in which the ceramic ring device 30a is provided, which is coaxially spaced radially within the "inner annular part "is attached and which forms the radially outward boundary of the bearing gap.

In F il separate thrust bearing are provided on the inner annular T _e, which is fed via the lines 32

will. -.

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Pig «3 shows a multistage coaxial turbo compressor _f which has a rotor which consists of two coupled, axially spaced rotor units L and M" ₀ Each unit consists of an outer cylindrical tube element 33 "in which an inner tube element provided with KOfapressorschaufeln 34 35 made of steel is provided "In the inner tubular element 35 a ceramic device is arranged, which consists of a ceramic tubular element 36" which is held by the tubular element 35 against radial forces, and driven ceramic blades 37, which are mounted on a ceramic hub 38, consists"

Each unit L, M is held iron in an outer fluid bearing. The ring device 40 is similar to the device 11a, 11b, 11 £ in Fig. 1 designed in three pieces. Fluid is passed from storage spaces 41 through slits 42, which are arranged in two circumferential cleanliness per unit, to the bearing gap 39. Between the ends of each tubular element 33 made of steel and the adjacent fixed radial wall of the stator are end pressure bearing gaps 4-3, which are at the end of the associated bearing gaps 39 exiting fluid are fed ₀

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BATH

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In this construction, "the" refers to the outer annular shape Part "refers to the tubular member 33 made of steel. The" inner annular part "" refers to the establishment of the ceramic element 3S and the tubular member 35 made of steel. The "first tower blading" refers to the compressor blades 34 ο The "second tur" bines "inspect" "refers to the blades 37"

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Claims (1)

^ 91931Q- - 13 claims 'O ■ i Iy turbine rotor, characterized by an outer ring-shaped Part (9,24,33), an inner arranged coaxially at a radial distance from the outer annular part annular part (6,26,35j36) and one between the inner and the. outer part provided first turbine blading (8,25,34) » 2. Turbine rotor according to claim 1, characterized in that that the outer annular part (9,24,33) and / or the inner annular part (6,26,35,36) is elongated and tubular is or are ο 3ο turbine rotor according to claim 1 or 2, characterized in that that the outer annular part (9,24,33) and the inner annular part (6,26,35,36) from the first Turbine blading (8,25,34) with radial spacing coaxial being held" ' 4ο turbine rotor according to any one of claims 1 to 3, characterized in that the inner annular part (6,26,36) ceramic material, which is of a outside radially arranged enclosure (7,35) is held. 5 β turbine rotor according to claim 4, characterized in that that a second turbine blading (5,27,37) is provided, which is inside the inner annular part (6,26,35,36) and / or is arranged radially outside the outer annular part (9,24,33) and made of ceramic material consists. 909843/132? 19193T0 - 14 - · ■. ■■■ ■■ .-. β ο turbine rotor according to any one of claims 1 "to, 5, characterized in that a multi-axle bearing is provided whose bearing gap (1O) is radially outside the outer, annular part (9) is arranged » 7 »turbine rotor according to claim 6, characterized in that the bearing gap (10) inside from the outer annular Part (9) is limited, 8 »Turbine rotor according to any one of claims 1 to 5, characterized in that a fluid axle bearing is provided is, whose bearing gap (29) lies radially inside the second turbine blading (27). 9. turbine rotor according to claim 8, characterized in that a third annular part (30) is coaxial with the radial Distance is arranged within the inner annular part (26) and delimited the bearing gap (29) radially on the inside 9098Α3 / 132Γ