Aviation Gas Turbine Engine Bearings and Seals PDF

Summary

This document provides learning objectives and details about the constructional features and principles of operation of engine bearings and seals for gas turbine engines. It discusses different types of bearings, such as ball and roller bearings, and the reasons for not using plain bearings in turbine engines. It also analyzes the advantages and disadvantages of various sealing methods and their importance in maintaining engine performance.

Full Transcript

Bearings and Seals (15.8)
Learning Objectives
15.8.1 Describe engine bearings constructional features and principles of operation (Level
2).
15.8.2 Describe seal constructional features and principles of operation (Level 2).

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 Engine Bearings
Purpose of Engine Bearings
Engine main bearings are assigned the critical function of support and are located along the length of
the rotor shaft. The number of bearings necessary is determined, in part, by the length and weight of
the rotor shaft. For example, since a dual-spool axial compressor typically has a greater number of
rotating components, it requires more main bearings than a centrifugal compressor.

The main bearings of a gas turbine engine are either ball or roller anti-friction types. The minimum
number of bearings required to support one shaft is one deep-groove ball bearing and one straight
roller bearing. Ball bearings support the main engine rotor for both axial (thrust) and radial
(centrifugal) loads. The roller bearings support only the engine rotor’s radial loads. Because of their
greater surface contact area than ball bearings, they are positioned to absorb the bulk of the radial
loading and to allow for axial growth of the engine during operation. The diagram shows one
con guration of bearing positions.

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Main bearing locations

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 Plain bearings are not used as main bearings in turbine engines, as they are in piston engines, because
turbines operate at much higher speeds and friction heat build-up is prohibitive. The primary loads
acting on main bearings are from the following sources:

Weight of the rotating mass (compressor and turbine) magni ed many thousands of times by
radial g-forces
Axial forces from power changes and thrust loading
Gyroscopic effect of heavy rotating masses trying to remain in place as the aircraft changes
direction
Compression and tension loads between the stationary casings and the rotor system caused by
thermal expansion
Vibrations induced by the airstream, the airframe and the engine itself.

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 Main Bearings
The main bearings support the rotor assemblies and then transfer the various loads through the
bearing housings and support struts to the outer cases of the engine, and ultimately into the aircraft
mountings.

The number of main bearings varies from one engine model to another. One manufacturer might
prefer to install three heavy bearings, and another ve or six lighter bearings to accommodate the
same load factors.

The bearings are made up of an inner and outer race, with the cage holding the rollers or balls. This
cage keeps the roller or balls aligned between the two races, which support the turning shaft. Straight
roller bearings can accept only radial loads and will not support the shaft under thrust (axial loads).
The thrust load is carried by the ball bearing, which can carry radial and thrust loads.

Each engine con guration differs, but a common method is using one ball bearing and one or more
roller bearings per spool shaft. Roller bearings offer a larger bearing contact surface than ball
bearings and are preferred where thrust loads are not present. The ball bearing handles the thrust
load, and roller bearings provide additional supports where needed. This con guration allows the
engine exibility when it expands and contracts due to temperature changes while operating.

Ball and roller bearing

Disadvantages of both ball and roller bearings include their vulnerability to damage caused by foreign
matter and their tendency to fail without appreciable warning. Therefore, proper lubrication and
sealing against entry of foreign matter are essential. Commonly used types of oil seals are labyrinth,
helical thread and carbon.

Main engine bearings are housed in a bearing support or housing. The support forms a chamber
which separates the bearing from the engine core cavity. Bearing seals keep the lubricating oil and oil
mist from entering the engine core. Oil leakage into the core cavity enters the air ow and gas stream.

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 Aviation Australia
Bearing chamber

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 Bearing Chamber Sealing
Labyrinth Seals
Labyrinth seals are commonly used for main bearing chamber sealing. They have no contacting parts.
They prevent oil leakage out by controlling opposing air leakage into the chamber. Compressor bleed
air, which is at a greater pressure than bearing chamber vent pressure, causes air to ow from the
outside to the inside of the chamber.

Air cooling of the engine bearing chambers is not normally necessary since the lubrication system is
adequate for cooling purposes. Additionally, bearing chambers are located, where possible, in the
cooler regions of the engine. In instances where additional cooling is required, it is good practice to
have a double-skinned bearing housing with cooling air fed into the intermediate space.

There are several variations of labyrinth seal design.

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Bearing chamber

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 Labyrinth Air Seal
A labyrinth seal used as an air seal comprises a nned rotating member with a static bore which is
lined with a soft abradable material or a high-temperature honeycomb structure. On initial running of
the engine, the ns lightly rub against the lining, cutting into it to give a minimum clearance.

The clearance varies throughout the ight cycle, depending on the thermal growth of the parts and
the natural exing of the rotating members. Across each seal n is a pressure drop which results in a
restricted ow of sealing air from one side of the seal to the other.

Labyrinth seal

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 Labyrinth Air/Oil Seal
To prevent excessive heat build-up due to seal rub caused by shaft exing, a non-heat-producing seal
is used where the abradable lining is replaced by a rotating annulus of oil. When the shafts de ect,
the ns enter the oil and maintain the seal without generating heat. Labyrinth air/oil seals have
greater n clearance than air seals.

Labyrinth air/oil seal

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 Thread Type Labyrinth Seal
The ns on thread type labyrinth seals form a helical path similar to a screw thread. As the seal
rotates, it ‘threads’ the oil back into the bearing chamber. As with labyrinth seals, ns allow for a
metered amount of compressor air to ow into the bearing chamber. Pressure within the bearing
chamber is maintained slightly above atmospheric.

Thread type labyrinth seal

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 Hydraulic Seals
The hydraulic method of sealing is often used between two rotating members to seal a bearing
chamber. Unlike the labyrinth or ring seal, it does not allow a controlled ow of air to traverse across
the seal. Hydraulic seals are formed by a seal n immersed in an annulus of oil which has been created
by centrifugal forces. Any difference in air pressure inside and outside of the bearing chamber is
compensated by a difference in oil level on either side of the n.

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Hydraulic seal

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 Ring Seals
A ring seal comprises a metal ring which is housed in a close- tting groove in the static housing. The
normal running clearance between the ring and rotating shaft is smaller than that which can be
obtained with the labyrinth seal. This is because the ring is allowed to move in its housing whenever
the shaft comes into contact with it.

Ring seals are used for bearing chamber sealing, except in the hot areas where oil degradation due to
heat would lead to ring seizure within its housing.

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Ring seal

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 Carbon Seals
Carbon seals consist of a static ring of carbon which constantly rubs against a collar on a rotating
shaft. Several springs are used to maintain contact between the carbon and the collar. This type of
seal relies on a high degree of contact and does not allow oil or air leakage across it. The heat caused
by friction is dissipated by the oil system.

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Carbon seals

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Seal race mounted on rotating shaft

The seal race is mounted on the rotating shaft.

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 Carbon seals are brittle and need to be handled carefully. Special care should be taken not to damage
the polished sealing surfaces.

Brush Seals
Brush seals are circumferential seals which may be used in place of traditional labyrinth seals in large
or small gas turbine secondary and tertiary ow gas paths.

They are manufactured from materials such as high-temperature nickel-cobalt alloy bristles. Brush
seals are comprised of an array of densely packed, high-temperature resistant, low wear bristles
con gured on an angle of approximately 45° with the tangent of their adjacent shaft. Current brush
seal mating surface material can be ceramic, chromium carbide, tungsten carbide or alumina,
depending on where it is located in the engine and brush material.

The bristles form a exible porous medium, reducing leakage by up to 5 times that of a typical
labyrinth seal. The seal takes up slightly more radial room than a conventional straight-toothed
labyrinth, but signi cantly less axial space, and weighs far less than machine labyrinths.

Brush seals are being applied in today’s gas turbines as replacement for labyrinth, other air-to-air
seals and oil seals to improve engine ef ciency, reduce fuel consumption and increase engine thrust.

Brush seal

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 Brush seal example

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