CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 70, 2018 

A publication of 

 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Timothy G. Walmsley, Petar S. Varbanov, Rongxin Su, Jiří J. Klemeš 
Copyright © 2018, AIDIC Servizi S.r.l. 

ISBN 978-88-95608-67-9; ISSN 2283-9216 

Design and CFD Modelling of a Low Pressure 

Turbine for Aeroengines 

Christina Salpingidoua, Charalampos Deralasa, Dimitrios Misirlisb*, Zinon 

Vlahostergiosc, Kyros Yakinthosa 

aAristotle University of Thessaloniki, Laboratory of Fluid Mechanics and Turbomachinery, Egnatia Street Thessaloniki, 

 Greece  
bTechnological Educational Institute of Central Macedonia, Department of Mechanical Engineering TE, Terma Magnesias, 

 Serres, 62124, Greece 
cDemocritus University of Thrace, Laboratory of Fluid Mechanics and Hydrodynamic machines, Xanthi, Greece 

 misirlis@eng.auth.gr  

During the last decades, the reduction of aeroengines fuel consumption is becoming an issue of high 

importance, due to economic and environmental reasons. One of the main parameters that can severely affect 

the fuel consumption and the whole performance of the engine is the efficiency of its turbomachinery 

components. In this work, a detail design study of a low-pressure turbine (LPT), which is integrated in a turbofan 

engine, is presented. The LPT is designed based on a thermodynamic cycle analysis of the turbofan engine, 

based on specific requirements such as: mass flow rate, inlet pressure, temperature, power etc, targeting always 

to an aerodynamic design of increased efficiency. In the first part, the development of a computational tool (0D 

analysis) based on the book of Saravanamuttoo et al. (2001) on gas turbine theory and the work by Kacker and 

Okapuu (1982) on axial-flow turbines, capable to calculate the main geometrical and thermodynamic 

characteristics of the turbine (e.g. inlet and outlet flow and blade angles, aspect ratio, pitch to chord ratio, root 

and tip radius, pressures, temperatures and densities at each stage) is presented. In order to have a proper 

evaluation of the design methodology, a 3D CAD of all the turbine stages is created and detailed 3D CFD 

computations are performed. The CFD analysis and the results are presented in the second part of this work. 

The ANSYS commercial software is used for the design, meshing and prediction of the flow field through the 

turbine. Additionally, grid independency study is conducted also, in order to determine and conclude to the size 

of grid that will provide grid-independent results. Finally, the results of the 0D analysis are compared with those 

of the 3D CFD computations. A very close agreement is achieved, with a deviation in efficiency values less than 

1 %. Thus, it can be concluded that the 0D computer tool can be used as a first low-computational-cost and 

accurate presizing tool for the calculation of the engine turbine performance.  

1. Introduction 

The low-pressure-turbine (LPT) is considered one critical part for the proper and efficient operation of an aero 

engine. Many researchers are trying to optimize the LPT (Burton et al., 2007) and suggest methodologies for 

an efficient way for optimization of blade profiles (Trigg et al., 1999). The aim of this work is the conceptual 

aerodynamic design of a low pressure axial turbine and it is accomplished in two stages. During the first stage 

a 0D computer code is developed for the calculation of the geometrical characteristics of the blade, the 

thermodynamic performance and the velocity triangles, for specific inlet conditions and power requirements, 

aiming always the maximization of LPT efficiency. At the end of this stage, a design which leads to increased 

efficiency is determined. The main goal and motivation of this work is to show that the 0D methodology is 

accurate and can lead to an LPT design in a very short time. 

During the second stage the calculated geometrical parameters are used for the design of the turbine CAD 

model in order to carry out a Computational Fluid Dynamics (CFD) analysis. The commercial software ANSYS 

Turbogrid (ANSYS, 2016) is used for the mesh generation and the commercial CFD software ANSYS CFX 

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1870117 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Salpingidou C., Deralas C., Misirlis D., Vlahostergios Z., Yakinthos K., 2018, Design and cfd modelling of a low 
pressure turbine for aeroengines , Chemical Engineering Transactions, 70, 697-702  DOI:10.3303/CET1870117   

697



(ANSYS, 2016) for the modeling of the turbine. A grid independence study is conducted for deciding the 

sufficient number of computational nodes. Proper comparative values were selected in order to conclude on the 

deviation between the 0D code and the CFD results and thus, estimate the accuracy of the 0D code. 

2. Computational tool based on 0D model 

For the conceptual design of the LPT an in-house tool is developed. The main steps of the procedure are shown 

in Figure 1.  

 

 

Figure 1: Conceptual design algorithm 

Three dimensionless parameters are most commonly used in turbine design mostly affecting the main design 

of the blades. The first one is called stage loading coefficient or temperature drop coefficient, , and expresses 

the work capacity of the stage and is given by Eq(1). Parameter Cα is the velocity in the stationary frame and U 

is the blade linear velocity. Symbols α and β are used for the angles of the velocity triangles. The index 1 is 

used for the stator entry, 2 for the stator outlet and 3 for the rotor outlet. Cp is the specific heat capacity and ΔΤ0 

is the total temperature difference. 

ψ=
2CpΔT0s

U
2

=2
Cα

U
(tanβ

2
+tanβ

3
) (1) 

Another parameter is the degree of reaction, Λ, which represents the ratio of static enthalpy or temperature drop 
in the rotor to the total enthalpy (or temperature) drop in the stage: 

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Λ=
Τ2-Τ3

Τ1-Τ3
 (2) 

 

For constant axial velocity through the turbine, Eq(1) can be transformed to Eq(3):  

Λ=
Cα
2U

(tanβ3-tanβ2) (3) 

Finally, the last parameter is called flow coefficient and it represents the ratio of the axial flow velocity to the 
blade velocity: 

φ=
Cα

U
 (4) 

Combining Eq(1) to Eq(4), the angles of the velocity triangles α and β can easily be calculated if these 3 

dimensionless parameters are initially defined. These dimensionless parameters constitute the main user 

defined input. Moreover, providing the linear blade velocity U, all the other velocities can be calculated. 

Considering the power required for a stage, Ws, the first law of thermodynamics, and an estimation of the stage 

efficiency, ηs, and of the temperature loss coefficient for the nozzle blades, λN the temperature and pressure 

values can be calculated. 

The next step is the calculation of the density values and annulus area at stator and rotor inlet and exit. The 

density values can be easily calculated from the static pressure and temperature values obtained above with 

equation of state while the annulus areas can be calculated with continuity equation 

The heights (h) and radii of root (rr), meanline (rm), and tip (rt), of the blades can be calculated from the following 
Equations, where N show the revolutions per minute and A the blade area: 

rm=
U

2πN
 (5) 

h=
AN

U
 (6) 

rt

rr
=

rm+
h
2

rm-
h
2

 (7) 

For the selection of pitch to chord ratio, s/c, and aspect ratio, h/c, of the blades, already existing literature data 

are used Saravanamuttoo et al. (2001). Since the main geometrical characteristics and the velocity triangles of 

each blade have been calculated the blade angles should also be calculated. A choice must be made for the 

incidence (i=αin - α΄in), the deviation (δ= αout - α΄out) angles, the stagger angle and maximum airfoil thickness to 

chord ratio. For determining the incidence, various correlations exist. An empirical correlation is given by Eq(8), 

Kenny (2005) :  

i=0.175αin-1.5 (8) 

where αin is the inlet flow angle, α΄in is the inlet blade angle, αout is the outlet flow angle and α΄out is the outlet 

blade angle. 

For the estimation of the blade stagger angle and the maximum airfoil thickness to chord ratio, graphs given 

from Kacker and Okapuu (1982) can be used. The selection of appropriate deviation angle is also important, 

since it is directly related with the performance of the turbine. The formula for the deviation angle calculation is 

given from Zhu and Sjolander (2005), Eq(9), where Φ is the stagger angle and tmax is the maximum thickness of 

airfoil and is valid from Mach numbers up to 0.6. 

δ=
(s c⁄ )

0.05
(αin+αout)

0.63cos2(Φ)
(tmax

c
⁄ )

0.29

30+0.01(αin
' )

2.07
tanh

Re
200000

 (9) 

Up to this point, the basic elements of the airfoil design are complete, and a calculation of the LPT stage 

efficiency is needed, so that the previous calculations, based on an estimated efficiency, can be performed 

again based on the new calculated efficiency. For the efficiency calculation, a method outlined by Kacker and 

Okapuu (1982) is adopted. 

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3. CFD model 

In order to obtain results from a CFD analysis the next steps are followed: 

1. Turbine stages design with the use of ANSYS BladeGen 

2. Mesh creation with the use of ANSYS TurboGrid 

3. Grid independence study 

4. CFD simulation with the uses of ANSYS CFX 

The first step is the creation of the blade CAD model and the periodic flowpath, as shown in Figure 2. Three 

computational grids are considered in an initial simulation only for one stage, in order to determine the sufficient 

number of computational elements. More specifically, for the stator there are three grids consisting of 300×103, 

600×103 and 1.2×106 elements. For the rotor, the three grids consist of 450×103, 900×103 and 1.8×106 elements 

respectively. After a comparison between the CFD results using three study, the final selected grid consists of 

600×103 elements for the stator and 900×103 elements for the rotor. These values are selected due to the fact 

that an increase of the mesh quality beyond the aforementioned values lead to insignificant changes in the flow 

simulation results (less than 0.2 %), meaning that using this element number a grid independent solution is 

obtained. 

 

  
(a) (b) 

Figure 2: (a) Mesh of fourth stage rotor. (b) Mesh of fourth stage rotor, 3D view  

Steady state simulations are performed. The total pressure inlet (322 kPa) and the mass flow at the outlet 

(17 kg/s) are provided, as boundary conditions. Since high accuracy in the solution was the scope of this work, 

the chosen turbulence model for this simulation was the Shear stress transport model of Menter (1994). This is 

a two-equation eddy viscosity model that combines a k-ε model away from the wall boundaries and a k-ω model 

in the near wall regions. The SST model was designed to give highly accurate predictions of the onset and the 

dimensions of flow separation under adverse pressure gradients, with the proper modelling of the behaviour of 

the turbulent shear stress transport by the introduction of appropriate eddy-viscosity limiters. This lead to a major 

improvement regarding flow separation prediction. The superior performance of this model has been 

demonstrated in a large number of validation studies, (Costa Rocha et al., 2016) 

For the computations, the turbulence intensity is defined at 5 %. Simulations with very complex and.      

turbulence-generating components upstream will have a very high incoming turbulence level. For example, a 

high-pressure turbine just downstream of a turbulence generating combustor might have incoming turbulence 

levels up to 20 %. Fans and low-pressure compressors with not many components upstream might have as low 

incoming turbulence level as 1 %. For components between these two extreme examples, like high-pressure 

compressors or as this example, low-pressure turbines, a turbulence level of around 5 % seems realistic. The 

turbulence length-scale is often even more difficult to estimate than the turbulence level. The best way to make 

a realistic assumption is by using the geometrical characteristics of the upstream components. The incoming 

turbulence length-scale can be estimated as say the thickness of upstream blades or somewhere between 2 % 

and 20 % of the incoming channel height. In the present case, the length scale is considered equal to the mean 

maximum blade thickness at the mean radius.   

The mesh of the stator is modeled as a stationary domain and the mesh of the rotor as a rotating domain. The 

interface-interaction between these two domains is performed using a general connection interface model. This 

is a powerful model and can be used (and is actually necessary) to apply both a frame change and a flow path 

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change/pitch change (when both domains do not present an exact periodic flow path as aforementioned) in the 

interaction between the stator and the rotor. When a general connection interface is used, the frame 

change/mixing model and the pitch change must be specified. The Stage model (also known as the Mixing-

Plane model) as a frame change model is used. It performs a circumferential averaging of the fluxes through 

bands on the interface. Steady-state solutions are then obtained in each reference frame. This model enables 

steady-state predictions to be obtained for multi-stage machines. The stage averaging at the frame change 

interface incurs a one-time mixing loss. This loss is equivalent to assuming that the physical mixing supplied by 

the relative motion between components is sufficiently large to cause any upstream velocity profile to mix out 

prior to entering the downstream machine component. The Stage model usually requires more computational 

time than other models to converge.  

4. CFD results 

Figures 3 summarizes some of the most important CFD results. Figure 3 shows the pressure distribution and. 

The CFD results are in very close agreement with those of the 0D methodology. The pressure distribution in 

Figure 3 is similar with the results of the 0D methodology.  

 

 

Figure 3: Pressure profile 

  
(a) (b) 

Figure 4: (a) Total pressure discrepancies between 0D code and CFD results. (b) Total pressure discrepancies 

between 0D code and CFD results 

Finally, Figure 4 provide a comparison of the CFD results and the 0D computational tool, the approximation line 

are added in order to show the deviation between the two results. As it can be seen, the CFD results are in good 

agreement with the zero-dimensional tool. Discrepancies could be contributed to the fact that the 0D analysis 

cannot predict the velocity component in the third dimension and also the selection and modification of the total 

area size brings a significant change to the flow field. The modification of areas according to the blade height is 

not entirely accurate and also does not take into account the blockage imposed by the boundary layer. 

0D
Mth

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Sutherland’s formula for the calculation of the viscosities could also bring minor changes, since there is a small 

variation of the viscosity values taken from the table to the viscosity values calculated by the formula. 

5. Conclusions 

The main conclusions are the following. 

• The 0D methodology is time efficient and can lead to results in very short time. 

• The CFD results are in very good agreement, with a deviation less than 5 % with those of the 0D 

methodology. 

• Therefore, the 0D results can be used for the conceptual design of an LPT. 

Acknowledgments 

Christina Salpingidou would like to thank Alexander S. Onassis Public Benefit Foundation for the scholarship. 

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