Method for Improving Multi-stage Compressor Parameters using the
IOSO Optimizer
Evgenii Goriachkin, Grigorii Popov
a
, Oleg Baturin, Valery Matveev
b
and Andrei Volkov
Samara National Research University, Samara, Russia
Keywords: Parametric Model, Optimization, Efficiency, CFD Simulation, Numerical Model Settings, Multistage
Compressor, Profiling.
Abstract: In the presented work, an algorithm was developed for finding the optimal configuration of the blades of
multi-stage axial compressors using 3D CFD modeling as the main tool and using commercial optimization
programs. When developing the algorithm, special attention was paid to the development of a method for
parameterizing the shape of the blade and a program based on it, which allow you to automatically change
the shape of the blade of the axial compressor. They were used by the authors during optimization as a tool
that converts variable parameters into the “new” blade geometry. The created algorithm can be used to
improve the basic parameters of the compressor (efficiency, pressure ratio, mass flow rate, etc.) due to the
correction of the shape of the blade profiles and their position relative to each other. In this case, the algorithm
considers the possible presence of various constraints.
NOMENCLATURE
GTE - gas turbine engine
MAC - multistage axial compressor
FV - finite volume
RB - rotor blade
RW - rotor wheel
GV - guide vane
𝜋
∗
- pressure ratio
𝜂
∗
- compressor efficiency
Ks - stability margins
n - rotational speed
G - mass flow rate of the working fluid
- flow angle in absolute motion
1 INTRODUCTION
One of the most important tasks in gas turbine engine
building is to increase the energy efficiency of the
engines (to reduce fuel consumption). It is determined
by many multidirectional influencing parameters
characterizing all components and the entire engine.
One of the most significant is the compressor
efficiency. The shortfall in the efficiency of each
a
https://orcid.org/0000-0003-4491-1845
b
https://orcid.org/0000-0001-8111-0612
compressor by 1.0% can increase the specific fuel
consumption of a gas turbine engine by up to 0.5%
(Kulagin, 2002).
The compressor efficiency is laid at the design
stage. Therefore, increasing the efficiency of the
design process and the design tools can significantly
help to achieve high compressor efficiency.
Recently, compressor design methods have
evolved significantly due to the numerical
simulations based on the Navier-Stokes equations and
the exponential growth of computer capabilities.
These factors made it possible to conduct not only a
detailed 3D simulation of the working processes of
multistage axial compressors, but also to optimize the
spatial shape of the blades using mathematical
optimization methods.
The latter circumstance allows to create the design
variants of the compressor in an automated mode that
best satisfy all the design requirements, considering
the existing constraints of various kinds. At the same
time, the blade that best suits the task can have
complex spatial shape (offsets of the sections in axial
and circumferential directions, the complex law of
changing the chords along the blade height etc.).
There may be an opinion that optimization is a
magic tool that allows the engineer to get the best
Goriachkin, E., Popov, G., Baturin, O., Matveev, V. and Volkov, A.
Method for Improving Multi-stage Compressor Parameters using the IOSO Optimizer.
DOI: 10.5220/0009769601630170
In Proceedings of the 10th International Conference on Simulation and Modeling Methodologies, Technologies and Applications (SIMULTECH 2020), pages 163-170
ISBN: 978-989-758-444-2
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
163
compressor variant for each case, with minimal user
involvement, which reduces the requirement for the
qualification of the designer and the likelihood of
errors. However, the use of mathematical
optimization in the design and development of the
MACs has not yet become widespread. Today, only a
small number of successful applications of this
method are known, and most of them relate only to
individual blade rows and stages.
Among the main difficulties hindering the
widespread use of optimization are the following.
Firstly, for successful optimization, a 3D numerical
model of the MAC workflow is required, which can
adequately predict the effect of changes in the design
parameters of the compressor on its workflow.
Secondly, the mathematical model of the compressor
must have an acceptable calculation time, since often
at least 1000-3000 iterations with the computational
model are necessary for solving the optimization
problem. Thirdly, stable parametric models of
compressor blades are required coupled with the
geometry of the computational domain, which can
automatically rebuild the 3D model of the blades. To
describe the three-dimensional shape of a compressor
blade in a parametric form, many variables are
required, and their maximum available number is
limited when solving the optimization problem. All
the components of the optimization system must be
combined within a single automated software that
works stably in the entire possible variation range of
the parameters with minimal user involvement.
The contradictory nature of the requirements and
the absence of stable working parameterization tools
are the main reasons why multicriteria optimization
techniques are currently used to a limited extent when
modernizing multistage compressors.
In the presented work, the authors set as the goal
the development and practical testing of methods and
tools for multicriteria optimization of the MAC
flowpath elements using numerical parametric three-
dimensional models of their working process.
Hereinafter, the MAC efficiency criteria are
understood as: efficiency 𝜂
∗
, pressure ratio 𝜋
∗
and
gas-dynamic stability margin Ks.
2 REVIEW OF THE
OPTIMIZATION METHODS
AND TOOLS FOR THE
COMPRESSOR
At the first stage, an analysis of the MAC
optimization experience was carried out based on the
available scientific and technical publications.
Summary of the information showed that the usage of
optimization methods is one of the most promising
ways for improving the design methods and gas-
dynamic modernization of the MAC.
In the works (Safari et al., 2013; Ning et al., 2016;
Yan et al., 2017), there are examples of optimizing
compressor stages using genetic optimization
algorithms (genetic algorithm). A genetic algorithm
is a search algorithm used for the optimization and
simulation problems by randomly selecting,
combining, and varying the desired parameters using
mechanisms like natural selection.
In papers (Yang et al., 2016; Zamboni et al., 2016;
Vasilopoulos et al., 2017), the adjoint methods are
used to find the optimal shape of the axial compressor
blades. With this approach, the objective function, as
well as the gradient function are calculated after the
creating the vector of independent variables. Then,
the necessary changes in the vector of independent
variables are calculated based on the gradient
function, and the cycle is repeated until the desired
result is achieved. An important advantage of this
method is that the rate of convergence of the
optimization problem is practically independent of
the number of variable parameters.
In (Barsi et al., 2014), the examples of optimizing
the shape of the axial compressor blades using neural
networks (artificial neuron network) are shown.
The papers (Sonoda et al., 2014; Zhaoyun et al.,
2016) show the examples of the optimization problem
using the particle swarm optimization method. This is
a computational method that optimizes a problem
iteratively trying to improve a candidate’s solution
with respect to a given quality score. During
optimization with the swarm method, an initial set of
solutions is formed, called particles, which move
around the project space based on the simple
formulas. The movement of particles obeys the
principle of the best position found in this space,
which constantly changes when particles find more
favorable positions.
Also, commercial optimization packages are used
in several studies. In (Ling et al., 2014) the iSight
package was used. The examples of using the IOSO
optimization program (IOSO, 2020) are shown in
(Marchukov et al., 2019; Vinogradov et al., 2018). In
several works, researchers use in-house codes
(Kuzmenko et al., 2007; Kröger et al., 2012; Aulich
et al., 2013; Komarov et al., 2014).
Summary of the analysis results showed that
today there is no unequivocal opinion on which
method is best suited for optimizing the MACs. The
choice of the method is often based on the traditions
SIMULTECH 2020 - 10th International Conference on Simulation and Modeling Methodologies, Technologies and Applications
164
of the research team and affordable software.
Moreover, the following general elements can be
distinguished in all optimization algorithms found
during the review:
a parameterization component used to create a
geometric model of the blades and blade rows
based on a set of variable parameters;
a component intended for the automated
creation of a FV model of the MAC flowpath
with a modified geometry;
component of the mathematical model of the
MAC workflow, which is used to determine the
parameters of interest for the investigated
object.
In all studies, it is noted that for successful
optimization, all these components must be combined
into a single computational algorithm.
It was also noted that only one or two blade rows
are considered in most works on the optimization of
axial compressors, which indicates the difficulties
encountered in the application of optimization
methods for the entire flowpath of the MAC and
confirms the relevance of the work.
3 PARAMETRIZATION OF
COMPRESSOR BLADE
PROFILES
One of the key technologies of the multicriteria
optimization method for the MAC flowpath elements
is parameterization of the blade shape. Hereinafter,
parameterization refers to a set of independent
variables that fully describe the shape of the blade
profile of in conjunction with the algorithm for its
construction.
The authors of the article developed and
implemented their own method of parameterizing
compressor blades. It is carried out in 2 stages (Figure
1, Table 1).
At the first stage, a description of the shape of the
planar control sections (cylindrical or conical
sections, the rotational axis of which coincides with
the rotational axis of the turbomachine) is performed
in the Profiler program (Dmitrieva ana Shabliy,
2014). It was developed at the Department of Aircraft
Engine Theory of Samara National Research
University (Samara University, 2020). This program
can convert the coordinate table, which in the design
drawing describes the shape of the blade, into text
files of the initial data for constructing design models
of turbomachines in the NUMECA and TurboGrid
programs. The Profiler also can change the shape of
the midline, the stagger angle of the profile, and
several other important characteristics of the shape of
the blade profile (Dmitrieva ana Shabliy, 2014). The
appearance of the Profiler interface is shown in
Figure 2.
The second stage of parameterization is carried
out in the Profiler 3D program developed by the
authors of the article (Popov, et al., 2017). It can
perform the followings:
change the relative position (shifts in axial,
radial and circumferential directions) of the
control sections of the blade based on the
selected stacking law of the sections along the
blade height;
scale the thickness and chords of the cross
sections of the blade by correcting the laws of
change in scaling factors along the height of the
blade.
Figure 1: Schematic diagram of the created parameterization scheme.
Method for Improving Multi-stage Compressor Parameters using the IOSO Optimizer
165
Table 1: Parameterization stages and their characteristics.
Stage 1 2
Implemented
in the program
Profiler Profiler 3D
What changes
at the stage?
‒ Stagger angle
of the middle
line
‒ Position of
the control
points on the
middle line
‒ Shift of individual
sections in the axial
and circumferential
direction
‒ Scaling of the
profile chord
‒ Scaling of the
profile thickness
How is the
pattern of
shape change
set?
The coordinates
or parameters
of each
corrected
section and the
midline points
are directly
changed
The dependence of the
change of the adjusted
parameter along the
blade height is set and
the parameters of the
control points of the
dependence are
modified
The algorithm underlying the Profiler 3D was
built considering the characteristics of the compressor
workflow. It is well known that the flow in the blade
row has a complex spatial nature, and depends on the
loading of the blade rows, which can be different for
different stages. Therefore, the parameterization
scheme was chosen based on physical ideas about the
flow structure in blade rows, so as to be able to
purposefully influence the shape of the blades in the
characteristic areas of the blade passages: in the flow
core, near the endwall regions of hub and shroud.
The second feature is that the number of blade
rows in the MAC can be large and exceed the value
of 30. Considering that the number of variable
parameters during the optimization process is usually
limited, the selected parameterization scheme for the
MAC blades provides the user with the opportunity to
change the number of variable parameters per one
row depending on the dimension of the task.
Figure 2: Profiler software.
The main idea of a parametric description of the
relative position of the sections along the blade
height, implemented in the Profiler 3D, is to use the
dependence of the variable parameter distribution
along the radius x
i
=f(r) (for example, the
displacement of the section along the coordinate axes)
(Figure 3). The linkage changes by correcting the
value of the variable in the control points of the
dependence x
i
=f(r).
In the developed program, the user can
fundamentally change the law of distribution of
parameters along the radius by choosing the number
of control points on the dependence x
i
=f(r). In
principle, the following laws can be implemented
(Figure 3):
linear – by two control points (shroud and hub);
dependence of degree 2 – by three control
points (shroud, hub and intermediate);
dependence of degree 3 – by four control points
(shroud, hub and two intermediate);
dependence of an arbitrary degree (with an
arbitrary number of control points).
Figure 3: Different ways of describing parameter changes along the radius in Profiler 3D.
SIMULTECH 2020 - 10th International Conference on Simulation and Modeling Methodologies, Technologies and Applications
166
The values of variables in arbitrary points of the
dependence x
i
=f(r) are calculated by the equation of
a polynomial of the corresponding degree (Flanders,
1973). The patterns of parameter changes along the
radius can be different for different rows of the same
MAC.
The fundamental choice of parameter changing
law (the number of control sections) along the height
of the blade gives the user an effective tool to reduce
the number of variables describing the shape of the
profile. As the law becomes more complicated, the
user gets more flexibility during optimization, which
will help to achieve a better result, but the required
number of variables for describing the profile
increases significantly. The impact on the radial
position of the control points can adjust the degree of
deformation along the blade and change the blade to
a greater extent where it is really needed (differently
in the core and near the endwall regions).
The law of scaling the chords and thicknesses of
the blade profiles is set similarly to how the sections
are aligned along the blade height.
A coupling of Profiler and Profiler 3D programs
(Figure 1) receives the value of independent variables
as the input describing the shape of the blades in
accordance with the accepted parameterization
schemes. As a result, files are generated for each row
that describe the geometry of the blades in the
.geomturbo format adopted in the NUMECA
AutoGrid 5 (Numeca AutoGrid, 2020). There, a mesh
of finite volumes for the new flowpath is generated.
The same program can adjust the axial position of the
rows relative to each other, as well as to set, if
necessary, a circumferentially variable pitch of the
blades. In the process of optimization, the required
values of the displacement of the blades in the blade
rows are automatically calculated by a special macro
and recorded in a script executed during the
optimization process.
4 MULTI-STAGE COMPRESSOR
OPTIMASATION ALGORITHM
Based on the literature review and practical
experience, an algorithm for multicriteria
optimization of the shape and relative position of the
MAC blades using commercial optimizer and
numerical parametric 3D model of its workflow was
developed. The algorithm was implemented based on
the Numeca software system (Numeca FineTurbo,
2020) and the IOSO optimizer program (IOSO, 2020)
using in-house programs described above (Dmitrieva
ana Shabliy, 2014; Popov et al., 2017).
Any mathematical optimization algorithm or
commercial program can be used for the
optimization. The developed algorithm is universal
and the choice of the best mathematical method for
finding the optimum function is not the goal of this
study. The authors of the article tested their
algorithms using the IOSO program available on the
market. Its choice is due to the large number of results
of its successful application in the tasks of aircraft
engine building, including by the team of authors of
the article (Marchukov et al., 2019; Vinogradov et al.,
2018; Popov et al., 2018; Popov et al., 2016; Popov
et al., 2019; Baturin et al., 2017). The specified
program was used as a finished commercial product.
No upgrades were made to the optimization
algorithms. A description of the algorithms used in
the program can be found on the website and
publications of the program developer (IOSO, 2020).
The flow chart of the algorithm is shown in Figure
4. The task of optimizing the MAC is solved
iteratively. Before the optimization, variable
parameters are set (usually this is the blade geometry
using the parameters specified in Section 2), their
ranges, criteria (usually the pressure ratio, efficiency,
working fluid flow rate or the stability margins) and
constraints (strength, structural or technological). The
adopted set of variable parameters ensure complete
change of the shape of the blade (angles, thicknesses,
the shape stacking line of profiles in the radial
direction).
The optimization cycle is implemented in the
following sequence. Initially, the optimization
program (for example, IOSO), based on a list of
variable data and a special mathematical algorithm,
generates a vector of variable parameters 𝑥
𝑥
,…,𝑥
, which represents the values of the
variables of the blades’ parametric model and their
relative position for the formed variant of the MAC.
The values of the vector of variable parameters are
automatically written to text files, which are used as
initial data for the programs for parametric
construction of blade rows Profiler and Profiler 3D
(see section 2). These programs generate files with
the geometry of the blades in the .geomturbo format,
which are then transferred to the NUMECA AutoGrid
5, where the FV grid is created (in accordance with
the recommendations of Section 3).
Then, the MAC workflow is calculated for one or
more operating modes in the CFD software
NUMECA FINE/Turbo. It should be noted that the
compressor workflow is calculated using a joint
model that considers all stages at the same time and
Method for Improving Multi-stage Compressor Parameters using the IOSO Optimizer
167
Figure 4: Flow chart of the developed optimization algorithm.
their mutual influence. If the configuration proposed
by the optimizer does not work stably for some
reason, the CFD solution does not converge at this
point and this was considered when the optimizer is
working.
At the end of the calculation, a text file is formed
with the values of the relevant compressor operation
parameters. The values of these parameters determine
the vector of output parameters 𝑦
𝑦
,…,𝑦
,
which is automatically transferred to IOSO. The
vector of output parameters may contain the values of
the integral parameters of the flow, for example, the
flow rate, the values of pressures and temperatures in
the cross sections of the MAC flowpath, as well as
complex parameters determined by mathematical
expressions based on the integral parameters of the
flow, for example, the margin of gas-dynamic
stability, the efficiency of the MAC. In IOSO, an
analysis of the obtained compressor variant and its
saving in the search history of the problem are
performed based on a distinctive mathematical
algorithm. As a result of the analysis, a front of
Pareto-compromise solutions is formed (particular
solutions in which an improvement of one of the
criteria cannot be achieved without deterioration of
the others) among the best MAC variants that satisfy
the given constraints, and also a vector of variable
parameters for a new iteration is created.
The developed optimization algorithm has been
repeatedly tested by the authors in solving various
industrial problems. A brief description of some
tasks, as well as links to publications that describe
them in detail, are given in Table 2.
5 CONCLUSION
The paper describes an algorithm developed by the
authors for finding the optimal configuration of the
blades of multistage axial compressors using 3D CFD
modeling as the main tool and using commercial
optimization programs. An important element of the
algorithm is the original way of parameterizing the
shape of the blades and the program based on it,
which allow to automatically change the shape of the
axial compressor blades. They were used as an
important part of the optimization algorithm as a tool
that converts variable parameters into the “new”
blade geometry. The created algorithm for searching
for the optimal shape of the compressor blades can be
used to improve the basic parameters of its operation
(efficiency, pressure ratio, flow rate, etc.) by
correcting the shape of the profiles of the blades and
their position relative to each other. In this case, the
method takes into account the possible presence of
various constraints.
SIMULTECH 2020 - 10th International Conference on Simulation and Modeling Methodologies, Technologies and Applications
168
Table 2: The results of some optimization tasks solved using the developed algorithm.
Example 1 (HPC) 2 (LPC) 3 (Three-spool compressor)
Number of optimized
parameters
1 2 2
Number of optimized
parameters
Number of constraints no 4 3 Number of constraints
Number of variable
parameters
3 15 61
Number of variable
parameters
Variable parameters
Stagger angle of the entire
blade
+ + -
Stagger angle of the entire
blade
Stagger angles of individual
profiles
- - +
Stagger angles of individual
profiles
Position of the points of the
profile middle line
- - +
Position of the points of the
profile middle line
Shift of individual section
relative to the initial
position
- - +
Shift of individual section
relative to the initial position
Chord scaling - - - Chord scaling
Blade thickness scaling - - - Blade thickness scaling
Results
Efficiency increase
0.3% at 100%
mode
1.2% at 95%
mode and 0.5 at
100% mode
1.3 at 100% mode Efficiency increase
Change in the pressure ratio - no
+4% (according to
the task)
Change in the pressure ratio
Change in stability margins no no no Change in stability margins
Change in mass flow rate -3% no
- 8 % (according
to the task)
Change in mass flow rate
Reference Marchukov, 2017 Goryachkin, 2015 Popov, 2019
The developed optimization algorithm can solve a
problem with an unlimited number of variable
parameters, constraints and optimization criteria.
However, it is obvious that their increase will
significantly complicate the search for the optimum
and increase (up to the unacceptable) time to search
for a solution. However, in practice, the authors did
not solve problems in which the number of
optimization criteria was more than two (due to the
complexity of analyzing the results with a larger
number of variables), and the number of variable
parameters was not more than 99 (due to limitations
of the available license for the IOSO optimizer
program).
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