residual thermal deformation of the gas-turbine engine
TRANSCRIPT
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Residual thermal deformation of the gas-turbine engine exhaust assembly
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- The analyzed problem was reported during acceptance
tests, when the turbine performance deteriorated after a
number of starts.
- Part of the deterioration is due to the exhaust assembly
deformation.
- Usually, after a few starts turbine performance stabilized.
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- Obviously, the residual deformation is due to multicyclic
thermal load, because of plastic behavior of the exhaust
assembly material.
- The engine operation cycle consists of starting, engine
operation and shutting down, which produces a non-
uniform thermal cyclic load in the exhaust assembly.
- After the next operating cycle the exhaust assembly does
not return to the same deformed original configuration
because of the kinematic (cyclic) plasticity material
behavior.
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The thermal load on the exhaust assembly
Non-uniformly distributed in
peripheral direction high
temperature exhaust gases
The frontal surface
is exposed to the
turbine cooling air
The outer surfaces are exposed to
the outer environment free
convection
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Isotropic and kinematic hardening plasticity
Isotropic hardening accounts for the change in size of the yield surface.
Kinematic hardening, on the other hand, accounts for the translation of the yield surface.
Combined hardening, on the other hand, accounts for both aforementioned effects.
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(a)
(b)
one-dimensional
case
two-dimensional
case
one-dimensional
case
two-dimensional
case
yield surface
translation
yield surface
expansion
Isotropic plasticity
Kinematic plasticity
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When a specimen undergoes loading and unloading for a number of cycles the stress-strain relationship takes an hysteresis loop form.
Cyclic hardening or cyclic softening occurs if the subsequent loading-unloading hysteresis loops tend to converge.
Non-proportional loading occurs when the relation between stress components increment is not a constant.
Ratcheting is the accumulation of the plastic strain cycle-by-cycle for some stress amplitude with a non-zero mean stress.
Isotropic and kinematic hardening plasticity
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(b)
(a)
An illustration of the
cyclic hardening, cyclic
softening and
ratcheting effects in
kinematic plasticity
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Isotropic and kinematic hardening plasticity
A well developed material kinematic plasticity model must include a quantified description of:
the correct non-linearity of stress-strain loop under cyclically stable condition
the Bauschinger effect
the cyclic hardening/softening effects
the ratcheting effect
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The chosen cyclic plasticity model was checked on the
standard tensile test specimen fixed at both ends.
The specimen is loaded by the cyclic non-uniformly
distributed thermal load.
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Isotropic plasticity case
Kinematic plasticity case
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The goal of the presented study is to decrease residual
thermal deformation after machine cooling (end of the
cycle).
It can be achieved by decreasing plastic deformation at
the peak temperature deformed configuration.
One possible way to decrease plastic deformation in
our case is to remove (or weaken) the thermal load on
the exhaust assembly.
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Non-uniform cyclic thermal load is created by
the following convection BC:
By non-uniform peripheral distribution of the high
temperature exhaust gases
By presence of the cooling air at the front surface
By free convection at the outer surface
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Thermal boundary condition
free convection
surfaces
exhaust gases
forced convection
surfaces
forced cooling
convection
surfaces
constant
temperature on
the flange
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Finite
Element
Model of
the
Exhaust
Assembly
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Structural non-linear kinematic plasticity analysis
(loaded with obtained temperature distribution)
Structural non-linear kinematic plasticity analysis
(thermal loads removed)
Results:
1. Plastic strain at machine operation cycle
2. Residual deformation at machine shut-down cycle
Thermal analysis
(to obtain steady-state temperature distribution)
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Temperature distribution analysis results
inside the exhaust assembly (existing design)
thermal
gradient
regions
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Von-Mises plastic strain distribution at the peak temperature deformed
configuration (Gray color represent the regions where plastic strain
exceeded 0.2%).
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temperature gradient
no longer exists
(a)(b)
The effect of thermal insulation adding at the
front surface on nozzle temperature distribution
OriginalImproved
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The effect of thermal insulation at the front
surface on nozzle plastic strain distribution
plastically strained
region
no longer exists
(a)(b)
OriginalImproved
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(a)(b)
temperature gradient
no longer exists
The effect of thermal insulation adding at the front surface as
well as at the outer piping on nozzle temperature distribution
OriginalImproved
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The effect of thermal insulation at the front surface as
well as at the outer piping on nozzle plastic strain distribution
(a)(b)
plastically strained
region
no longer exists
OriginalImproved
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Temperature distribution analysis results inside the exhaust
assembly when temperature distribution of the exhaust gases
in the peripheral direction is uniform
(a)(b)
temperature gradient
no longer exists
OriginalImproved
Symmetric
temperature
distribution
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The effect of uniform peripheral distribution of exhaust
gases on nozzle plastic strain distribution
Symmetric
plastic
strain
distribution
(a)(b)
plastically strained
region
no longer exists
OriginalImproved
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Analysis results:
Use of the thermal insulation at the front surface of
the exhaust assembly decreased non-uniformity in
radial deformation at the peak temperature
configuration by ~8.9%.
Use of the thermal insulation at the front surface of
the exhaust assembly as well as at the outer region
decreased non-uniformity in radial deformation at
the peak temperature configuration by ~21.5%.
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Use of the thermal insulation at the front surface of
the exhaust assembly increased non-uniformity in
residual radial deformation at the cooled deformed
configuration by ~15.4%.
Use of the thermal insulation at the front surface of
the exhaust assembly as well as at the outer region
decreased non-uniformity in residual radial
deformation at the cooled deformed configuration by
~30.1%.
Analysis results:
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Conclusions:
Although a thermal insulation reduces the residual deformation by 30%, some steps must be taken to reduce temperature non-uniformity of the exhaust gases.
The analysis results were verified by turbine tip clearance measurement. The same level of tip clearance non-uniformity was obtained which validate the chosen approach.