Article


 

  AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 215–222 
 

   

       Contents lists available at http://qu.edu.iq 

 

Al-Qadisiyah Journal for Engineering Sciences 

  
Journal homepage: http://qu.edu.iq/journaleng/index.php/JQES  

  

 

* Corresponding author.  

E-mail address: akramalkhanfar@gmail.com (akram Luaibi) 

 

https://doi.org/10.30772/qjes.v13i3.661  

2411-7773/© 2020 University of Al-Qadisiyah. All rights reserved.                                This work is licensed under a Creative Commons Attribution 4.0 International License.  

   

  

Cooling Process of Gas Turbine Blade: A Comparison Study  

 Akram Luabi a,b*, Naseer Hamza  a 

a Mechanical Engineering Department, University of Al-Qadisiyah, Ad'Diwaniyah 58001, Iraq 
b Al-Diwaniyah Gas Turbine Power Plant, Ad'Diwaniyah 58001, Iraq 

  

A R T I C L E  I N F O 

Article history:  

Received 02 June 2020 

Received in revised form 10 July 2020 

Accepted 20 July 2020 

 

Keywords: 

Gas turbine 

Blade 

Film cooling 

Internal cooling 

 

A B S T R A C T 

The gas turbine engines are occupied an important sector in the energy production and aviation industry and 

this important increase day after day for their features. One of the most important parameters that limit the 

gas turbine engine power output is the turbine inlet temperature. The higher is the turbine inlet temperature, 

the higher is the power output or thrust but this increases of risks of blade thermal failure due to metallurgical 

limits. Thus the need for a good and efficient process of blade cooling can lead to the best compromise 

between a powerful engine and safe operation. There are two major methods: film or external cooling and 

internal cooling inside the blade itself. . In the past number of years there has been considerable progress in 

turbine cooling research and this paper is limited to review a few selected publications to reflect recent 

development in turbine blade film cooling. The maximum drop in the surface temperature of the gas turbine 

blade and associated thermal stress – due to incorporating cooling systems- were 735 ˚C, 1217 N/mm2 

respectively. 

© 2020 University of Al-Qadisiyah. All rights reserved.    

1. Introduction 

The experimental, theoretical, and computational in the recent different 

investigations relevant to this work were presented such as the effect of 

raise the number of cooling duct and the coupled heat transfer (conjugate ) 

of gas turbine bucket. Literature scanning mentions that conjugate heat 

transfer CHT examination performs an important function to guide the 

temperature distributions for the heat transfer representations.  

The turbine inlet temperature is the most important parameter that 

influences the thermal efficiency of the power plants. Gas turbines are run 

at high inlet temperatures to satisfy the requirements of the power plants 

like the improved thermal efficiency and increasing the production of the 

energy. Innovative internal and external cooling methods are introduced for 

the new gas turbine engines to cool the blades and avoid material failure at 

extreme temperatures. Improved cooling techniques will allow the turbine 

operation to be closer and closer to the maximum permissible temperature 

for combustion and thus meet the power output requirement, especially at 

peak load. The cooling systems in the gas turbine blade are very 

complicated even that some times each application has its cooling scheme. 

Fig. 1 show the cooling passages inside the blade. The mathematical model 

of cooling systems is based on the forced convection heat transfer equations 

majorly and related formulas. 

 

 

 

 

 

 

 

Figure 1. Stage-1 high-pressure turbine rotor blade for the GE CF6 

engine. [1] 

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https://doi.org/10.30772/qjes.v13i
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216 AKRAM LUABI  , NASEER HAMZA  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 215–222 

 

There are many surveys done to scan the outcomes of researchers in the 

field of gas turbine technology and to continue this effort, this study aims 

to compare recent studies especially to cover recent last years. 

2. Analysis of turbine blade cooling mechanisms 

In the brief review below some of the pertinent work available in the open 

literature. At the summary review below some of the relevant study which 

available in the modern literature. 

2.1. External cooling (Film cooling) 

Film cooling is used to protect a solid surface from a high temperature 

of the mainstream by releasing a coolant on the surface. This secondary 

fluid can be considered as a heat sink for the heat flow from the hot 

mainstream or as an insulating layer between the hot mainstream and the 

surface. 

Few researchers performed experimental work for instance many 

references cited the work of  Luckey et. al. [2] empirical examination is 

used to simulate the airfoil profile of leading edge by using the stagnation 

zone of a cylinder mounted in a cross-flow a cylindrical with some of film 

cooling lines. They associated their outcomes for the optimal value of the 

blowing ratio and insertion angle. Experiments were fulfilled with an 

individual row of spanwise angled cooling channels for a domain of the 

coolant blowing ratio with independent flow-to-wall temperature.  

The local heat flux data measurements are offered for injection angles 

of cooling channel at 25°, 35°, and 45° with the row of passages located at 

three sites comparative to the stagnation line on the drum. Results see that 

path of (channel-to-channel) variations of heat flux shorthand due to film 

cooling and indicate the optimum performance for film cooling conditions 

Mehendale et. al. [3].  

Yao et al. [4] carried out an experimental investigation to study the 

performance of the cooling film for a consoles of single row set on a curved 

plate model in order to simulate the suction side of the blade. Numerical 

simulation was accomplished in order to disclose the detailed feature of the 

consoles film cooling (consoles on a curved surface). The results were 

compared to a mode of cylindrical holes. Martini et al. [5] studied the heat 

transfer and the cooling performance of the film of the cutback of the gas 

turbine airfoil trailing edge by using IR thermography method for different 

forms of internal cooling. The internal design effect on the cooling effect 

for the ejection slots was studied as well. The results showed that the 

shedding of the vortex from the side lip pressure was the main reason 

beyond the degradation in the cooling effectiveness of the film. 

  Je-Chin Han et al. [6] performed the experiments in three zones of a 

stator blade of the gas turbine which are blade platform, span, and tip. The 

blade platform and span investigations were done on the rotor blade of the 

high pressure turbine in median flow situations. Film-cooling performance 

or degree of cooling was appreciated in terms of cooling duct form, blowing 

ratio, and mainstream to coolant density ratio. The blade crest study was 

carried out in a blow-down flow turn in a transonic flow medium. The 

cooling degree was valued in terms of tip clearance and blowing ratio. 

Confined heat transfer coefficient evaluations were also performed.  

Mainstream pressure wastage was measured for blade platform and tip film-

cooling. Results showed that the blade platform cooling demands a 

collection of purge flow at upstream and discrete film-cooling channels 

downstream to cool the total platform.  

The formed cooling passages provided that vast film covering and 

higher film-cooling performance than the circular passages whereas also 

producing minimum mainstream pressure losses.  

Colban et al. [7] performed the film-cooling effectiveness of cylindrical 

channels and compared them with the vane-formed ducts on a turbine blade 

end wall. They had several experimental data for setup closes to that as the 

present work, with two passages having the same layout, one with circular 

holes and the other with vane-formed ducts. The missing aspect in the 

research that has been done in the examination into the effect of variance 

channels configuration and form on the blade cooling of the gas turbine and 

comparing the result in obvious parameters. Yang et al. [8] anticipated the 

cooling effectiveness of the film and the coefficient of heat transfer for three 

different types of the arrangement of the film and the hole. In the first one, 

the holes were designed to be located on the tips mid-camper line. In the 

second, the holes were created to be set in the stream of leakage flow (on 

the tip) and the region of heat transfer. While the third arrangement was the 

combination between the first and the second, respectively. The results of 

this study showed that the second configuration provided better 

performance than the others. 

Acharya et al. [9] presented that the cooling injection of the film 

decreased the ratio of the local pressure and changed the leakage vortex 

nature. High adiabatic effectiveness of the film and low coefficient of heat 

transfer were noticed lengthways the trajectory of the coolant with very 

small values of the cooling jet cross spreading. Better efficiency of the 

downstream of the coolant might be provided by increasing the gap of the 

tip.  However, at the smallest gap, the coolant directly impinged on the 

shroud surface resulting in a high effectiveness at the point of impingement.  

Hohlfeld et al. [10] presented a numerical study about losses of the 

cooling flow and the microcircuit channels. The advantages of the cooling 

flow of the external film that resulted from using microcircuit was 

presented. The results predicted that the microcircuit exits blowing and the 

cooling of the mid chord were independent. Besides, for all modes of the 

cooling of the microcircuit film presented in this study, aside vortex of the 

pressure was developed. In addition, good cooling effectiveness was 

obtained from the exiting of the holes of the dirt purge when the tip gap was 

small. However, low cooling effectiveness was observed for the larger gap 

of the tip.  

Goldstein R. J et. al. [11] presented the cooling of the film by 

introducing fluid (secondary) along the high temperature surface in order 

to protect these surfaces.  Ito et al. [12] presented a film cooling effect on 

the blade of a gas turbine by calculating the cooling effectiveness of the 

film holes for the surfaces of different convexities and curvatures. Kumar 

et. al. [13] presented a detailed investigation about film cooling of the 

blades of a gas turbine. ANSYS WORKBENCH V. 15.0 software was used 

for the numerical simulation and solving the governing differential 

equations. Effect of using different configurations of the holes that changes 

the cooling effectiveness was also investigated. The results of this study 

showed that the conclusions presented by other researchers about using 

cooling channels were correct reasonable. In addition, the increasing in 

cooling efficiency due to using cooling channels was due to heat transfer 

enhancement. Increasing the flow rate of the mass was a good factor for 

increasing cooling effectiveness (an optimal mass flow rate was required).  

2.2. Internal cooling (cooling holes)  

Khari brahmaiah et.al. [14] discuss the four various models to analyze 

the heat transfer through a gas turbine blade, blade is analyzed without and 

with channels that have different hole numbers (5, 9&13). According to this 



AKRAM LUABI  , NASEER HAMZA  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 215–222                                                                                      217 

 

study, the temperature distribution and transfer rate for the blade with 13 

holes are optimal.  

Structural analysis is done by the ANSYS software with blade at 

different materials, Inconel-718 and Chromium steel. The thermal 

properties of Inconel-718 material are better whereas induced stresses are 

lesser as compared to the Chromium steel.  

Josin et al. [15] showed a comprehensive study and design of the 

cooling passages of the blades of a gas turbine. The geometrical modeling 

was created by CATIA V.5. Both thermal and structural analyses were 

performed by using ANSYS 14.0 finite element software which is 

commercially available in its student edition. GDT-11, U-500, and IN-738 

alloy were considered as the material that used in this study. The first step 

of the analysis was to choose the material that shows better results for the 

first stage of the turbine blades. The next step was the modeling of the blade 

by modifying its geometry into a serpentine model in addition to increase 

the number of the hole. Temperature distribution from the thermal analysis 

and maximum elongation from the structural analysis were calculated and 

observed at the tip and the root sections of the blade, respectively. The 

comparisons between the three materials used in this study showed that 

GTD-11 offered the maximum deformation, maximum stresses, and could 

withstand higher temperatures around 8570 Co without any damage to the 

blade because of the higher melting temperature. 

Öztekin et al. [16] observed that the numerical results are in perfect 

coincidence with experimental results when developed wall functions and 

the model of k-ε turbulence in the principle of local alteration of the 

pressure coefficient. Maximizing the dimensionless blade-to surface space 

produced deficiency the coefficient of pressure (Cp) at the stagnation end.  

B.H. Dennis et al. [17] presented an optimized design for the cooling 

passage of a gas turbine blades by using the reduced method of conjugate 

heat transfer. The compressor last stage in the gas turbine presented in this 

study provided the cooling air. It was noted that the shape of the cooling 

channels and its location affected the heat transfer amount, temperature 

gradient inside the blades, temperature distribution, and cooling air-mass 

flux. Air was designed to flow inside the blades from its root and leave from 

its tip or trailing and leading edges.  

Ni et al. [18] simulated a methodology and an analysis of heat transfer 

and applied it for studying the cooling process of an air force film of a 

turbine van with 648 holes. The results of this work showed that air flows 

from the holes (cold air) created a protective layer all around the surface of 

the airfoil and the end walls. Lower temperature values were noticed on the 

entrance to the holes as well as the surfaces that were subjected to a high 

temperature hot gas.  Choo et al. [19] tested the micro-scale jet 

impingement on a heated flat plate and estimated the characteristics method 

of heat transfer by using correlation equations with experimental data on 

average and local Nu number in terms of Reynolds number and blade-to-

plate distance. Numerical study, using Reynolds-averaged Navier-Stokes 

(RANS), coupled with the k-ε model has been appointed as an important 

norm design and the simulation analysis. B. Deepanraj et al. [20] used a 

numerical analysis thermal effectiveness due to loading status. Titanium- 

Aluminum alloy properties and variant cases with different hole numbers 

of (7, 8, 9, 10, 11, and 12) were performed. Thermal stress, temperature 

distribution, and deflection were obtained using ANSYS software for 

several number of channels. The results explained that the decrease in the 

temperature values and the reduction in the temperature drop was motivated 

by the increasing number of the blade channels.  Reddy et al. [21] has tested 

the stainless steel thermal and structural analysis. Four variant cases 

containing of blade without and with different number of passages (7, 8, 9, 

and 10) were examined to discover the perfect cooling channels number. It 

is found that as the number of cooling channels increases the temperature 

distribution rise up. The SOLID WORKS software is used to simulate the 

structural analysis.  

The results showed that the blade with 10 № of holes is more stresses 

than the other models. Lastly, the model with nine holes has produced the 

optimum solution.  A.B. Moskalenkoa et al. [22] the numerical calculations 

were carried out using CFD based on the FEM. The coefficient of heat 

transfer and heat distribution of the bucket from the cooling domain to the 

cooling hole wall were selected as the standard of cooling efficiency. 

Abdulla R. Al Ali et al. [23] was fulfilled the numerical analysis of 

different heat transfer methods of jet impingement on a half-circular face. 

The comparison of these cases was based on the effective heat transfer by 

obtaining top Nusselt number and minimum surface temperature as heat 

transfer by convection is becoming the dominant situation and by compared 

between central and side jet configuration based on average Nusselt number 

at different Reynold numbers. The results were obtained to be in convention 

with the experimental investigation. For more highlight physics of the flow, 

a sensibility test on the jet impingement configuration and flow status were 

specified and was demonstrated to the internal cooling of the first stage 

bucket. HARSHA D A et al. [24] investigated the effects of material on 

thermal and structural analysis of blade designed with 12 holes as shown in 

Fig. 2. He compared the Titanium alloy with aluminum and observed that 

the total rate of heat transfer and the leading edge temperature were 

maximum and minimum for the 12 holes blade, respectively.  

 

Figure 2. Geometry model with boundary walls [24]. 

Soo-Yong Cho. et al. [25] investigated the conjugate Heat transfer on a 

blade of a gas turbine for various cases without and with different number 

of cooling channels. It was noted that the temperature of the leading edge 

was minimum while the overall heat transfer rate was higher for the blade 

within 13 holes. The analysis was examined for two alloy constructions, 

Inconel 718 and Chromium steel. The results showed the maximum value 

of the heat flux for the Inconel 718 blade with 13 channels and the thermal 

stresses were under allowable limits. K. Mazaheri et al. [26] examined the 

optimization of the configuration of the blade cooling holes. The goal was 

maximization of the temperature distribution. The conjugate heat transfer 

technique was applied to perform the analysis. The internal and external 

heat transfer was performed in a central scheme to find out the optimal 

function. Results showed that the method of temperature gradient in 

moving the fourth hole a far from the trailing edge and also reducing the 



218 AKRAM LUABI  , NASEER HAMZA  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 215–222 

 

volume of all holes, while the criterion of maximum temperature results 

maximize in their volume.  

A. Ziaei-Asl et al. [27] studied the effects of varying the thickness of a 

Thermal Barrier Coating (TBC) on the style of temperature distribution for 

a turbine blade. The blade was modeled to contain several cooling channels 

to increase the cooling efficiency. Several micro-passage were designed to 

be located on the blade tip in order to take out the coolant. The TBC is 

considered as an elastic material and the elastic modulus was computed 

from the stress-strain curve. A.Hasanpour et al. [28] solved the conjugate 

heat transfer of a metal blade designed in four different hole shapes and 

configurations. Four cylindrical holes in shape with k- ε (RKE) for 

turbulence modeling were used in this work.  

Couch. et. al. [29] examined a novel technique for cooling called a 

microcircuit technique. This technique combines the injection of the 

pressure side and the internal convection on the tips of the turbine blades. 

The dirt purge holes were designed to be on the tip to expel the dirt from 

the blade. In order to check the effectiveness of the holes on the tip along 

with the suggested microcircuit technique, the design was tested 

experimentally using wind tunnel tests. Both blowing ratio and gap size of 

the tip were variables for different cooling configurations. From the results 

of this study, a significant cooling increasing was provided by the dirt purge 

holes. The injected coolant out from these holes affected the shroud and 

flooded the tips that resulted in reducing the leakage of the tip flow.   

Chandrakant et al. [30] conducted a comparison study between the 

turbulator and using a helicoidally ducted blade for several geometrical 

proportions to estimate which is better on cooling. It was noted a significant 

enhancement for the characteristics of cooling of the turbine blade when 

using turbulator geometry of the larger ratio of the radial thickness of the 

turbulator to the helicoidally duct outer diameter (e/D). Htwe et al. [31] Gas 

turbines have an indispensable part in electric power generation. Gas 

turbine innovation is utilized as a part of a ranking of arrangements for 

electric power epoch. The leading and trailing edge of the turbine rotor is 

the most critical segment in the gas turbine power plant. John et al. [32] 

designed and analyzed a gas turbine blade. CATIA and ANSYS were used 

for the design and the finite element analysis, respectively. Life assessment 

and post processing were included in this work as well. ANSYS milieu 

facilities were used for the complex mesh generation and application of the 

working and boundary conditions. 

Han et al. [33] turned the light on the techniques used for the blade 

cooling, such as rib-turbulated cooling, pin-fin cooling, and jet-

impingement for two cases,  rotating and fixed blades. Priyanka Singh et al. 

[34]  used numerical analysis to study the heat transfer of gas turbines for 

six completely different models containing (5,9,13) in a single line row of 

passages and compared with another model that has (9,13) holes set in the 

3 row. They developed a new model with 14 passages in the staggered 

arrangement. They found that the temperature gradient on the 13 passages 

was consistently distributed along the surfaces of the blade compared to 13 

single line row. Heat transfer increased in the arrangements of 13 and 14 

staggered holes. 

Allen and Kofskey et al. [35] performed some visualization tests to see 

what these secondary flows looked like. Additionally, they also studied the 

effect of ejecting flow from the turbine tips on the shape of the secondary 

flows. At the time of these tests, engine temperatures were not so high as to 

require cooling of the turbine blades for operation. The cooling of the 

turbine blade could be considered as a necessary aspect of engine design. 

The cooling method of the rotor blade of the turbine by air passing inside 

the hollow blades and taking out it from the tip of the blade can be 

considered one of the most practical ways of varying the pattern of the 

secondary flow. 

G. Narendranath et al. [36] analyzed the 1st stage of the rotating gas 

turbine blade using ANSYS 9.0. The blade material used in the analysis is 

N155 alloy. The structural and thermal analyses were conducted 

numerically (FEM). The temperature gradient from LE to the TE on the 

surface of the blade was ranged from 839.531 ˚C to 735.162 ˚C at the blade 

tip. It is noticed that the minimum thermal stress was 1450 which is less 

than the yield strength of the material and the maximum thermal fatigue 

was 1217. 

V.Vijaya Kumar et al. [37] investigated a specific power turbine design 

in order to maximize the turbojet engine. For an obvious awareness of the 

compound thermal and mechanical stresses for the centrifugal and axial 

mechanical forces. The circumferential rotor speed and stream velocities 

were preserved in the feasible range to reduce the losses. The base profiles 

are completed using the potential flow method taking into consideration all 

flow conditions during the analytical solution process. 

The last stage of the compressor provides the cooling air for the blade 

holes. The configurations of the interior cooling holes influence the amount 

of transferred heat rate and the distribution of the temperature at the interior 

of the blade; besides that, the cooling air mass flow rate will affect the total 

turbine efficiency. The trivial choice for holes or passages is a circular 

shape, and the coolant fluid enters the blade hub and then comes out from 

its tip or the trailing edge. In the modern design of blades, the flow inside 

the adjacent holes takes various orientations B.H. Dennis et al [38]. 

Dulikravich et al. [39, 40] applied these optimization algorithms for 

analyzing the aerothermal –elastic characteristics of the blade of the 

turbine.  

The channels were split using ribs and their thicknesses and locations 

were specified according to a genetic algorithm. A restriction in the 

research development scope is appeared by using this model. Another study 

Kennon et. al. [40] investigated the optimized number, location, and size of 

the circular channels that were placed near the surface of the blade. The 

number of channels was limited by using the upper and lower limits of the 

channel diameter for minimizing the total transferred heat. 

Verstraete et al. [41, 42] optimized the position and size of the five 

channels having circular shapes in the 3D blade. Maximizing the blade 

lifetime and limiting the flux of the cooling air mass are the main objectives 

of the study.  

Namgoong et al. [43] utilized alternative models and experiment 

optimization design methods for reducing the loss in the pressure for the 

3D U-bend duct having 4-edges. Two edges were fixed, while the 

remaining two edges were permitted to change at 8-points within the 

channel.  A recent study by Nagaiah et al. [44] used the quadrilateral 

channel with an internal cooling system represented by the tabulating the 

ribs of channel walls. A semi-cylinder shape of ribs was adopted. The 

external flow on and close to the blade was not considered. A multi-

objective optimization was adopted for increasing the convection 

coefficient of the transferred heat, the effective surface of heat transfer, and 

decreasing the loss in the pressure of the channel pressure.  

The main emphasis of the previous studies is on the predefined 

channels. This can remove from our research scope many optimal shapes.  

Nowak et al. [45] optimized the maximum thermal gradient and 

temperature using the genetic algorithm method with four curves of Bezier. 

Some controlling points were constrained for decreasing the design variable 

numbers. This led to losing the smoothness control on the surface channel, 

in which many unsmooth corners and shapes were included. 

The results of the reviewed previous researches were summed up in table 1. 



AKRAM LUABI  , NASEER HAMZA  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 215–222                                                                                      219 

 

Table 1. Summary of results of significant literature studies. 

Results Method Year Author 

The second configuration provided better performance than 

the others. 

 

Three different types of the arrangement of the 

film cooling 

2004 Yang et al [8] 

The temperature gradient from LE to the TE was ranged 

from 839oc to 735oc at the blade tip. The minimum thermal 

stress was 1450 N/mm2 which is less than the yield strength 

and the maximum thermal fatigue was 1217 N/mm2. 

Analyzed the 1st stage of the rotating gas 

turbine blade using Ansys 9.0 by used n155 

alloy 

6002 G. Narendranath et.al [36] 

Using (rans), coupled with the k-ε model has been appointed 

as an important norm design and the simulation analysis. 

Using correlation equations with experimental 

data of nu number. 
6002 

 

Choo et al [19] 

Air flows from the holes (cold air) created a protective layer 

all around the surface of the airfoil and the end walls. Lower 

temperature values were noticed on the entrance to the holes 

as well as the surfaces that were subjected to a high 

temperature hot gas. 

Apply the cooling process of an air force film 

of a turbine van with 648 holes 
2011 Ni et al. [18] 

The decrease in the temperature values and the reduction in 

the temperature drop was motivated by the increasing 

number of the blade channels. 

Used titanium- aluminum alloy properties and 

variant cases with different hole numbers of (7, 

8, 9, 10, 11, and 12) 

6022 
 

B. Deepanraj et.al [20]  

The blade with 13 holes is optimal and the thermal properties 

of Inconel-718 material are better whereas induced stresses 

are lesser as compared to the chromium steel. 

Discuss the four various models without and 

with channels that have different hole numbers 

(5, 9&13) with different materials, Inconel-

718, and chromium steel. 

6022 
K hari brahmaiah et.al 

[14] 

Blade with 10 № of holes is more stresses than the other 

models. Lastly, the model with nine holes has produced the 

optimum solution. 

Tested the stainless steel thermal and structural 

analysis. Four variant cases containing of blade 

without and with different number of passages 

(7, 8, 9, and 10) 

6022 Reddy [21] 

Increasing the flow rate of the mass was a good factor for 

increasing cooling effectiveness 

Used for the numerical simulation and solving 

the governing differential equations 
6022 Kumar [13] 

The shape of the cooling channels and its location affected 

the heat transfer amount, temperature gradient inside the 

blades, temperature distribution, and cooling air-mass flux. 

Using the reduced method of conjugate heat 

transfer 

 
 

6022 

 

B.h. Dennis [17] 

A sensibility test on the jet impingement configuration and 

flow status was specified and was demonstrated to the 

internal cooling of the first stage bucket. 

Numerical analysis of different heat transfer 

methods of jet impingement on a half-circular 

face. 

6022 Abdulla r. Al ali et al [23]  

Coolant steam is more efficient than the air when examined 

using the same conditions. 

Comparison of coolant air and steam was 

carried out 
6022 Moskalenkoa et al [22]  

The location and the form of the last hole showed a 

significant role for all goal functions. 

The internal and external heat transfer was 

performed in a central scheme to find out the 

optimal function 

6022 K. Mazaheri et al [26] 

The coating thickness has a critical impact on the thermal 

and mechanical characteristics of the blade besides 

increasing the working period of the blade (blade life). 

Studied the effects of varying the thickness of 

a thermal barrier coating (TBC) on the style of 

temperature distribution for a turbine blade 

2017 A. Ziaei-asl et al [27] 

    

 
 

3. Discussion of Analysis Results 

During the last decade, the studies of optimization were significantly 

advanced. The optimization algorithms are now used broadly especially in 

engineering applications due to the development in the computational 

hardware that used the numerical methods in solving the problems. The 

cooling system of the turbine blade is one of the applications that could be 

modeled and analysed using these algorithms. The result of Titus.R et. al. 

[15]  showed that increasing holes number with reducing its size and 

reducing the gap between them led to a good design. The existing design 

and the modified design (increasing the number of the holes) showed 

1250K and 1191.6K, respectively. However, the serpentine design is cost 

effective and requires more effort because of the difficulties in the 

manufacturing processes compared to the other available designs. 

Results of Moskalenko et al. [22] showed the comparison of coolant air 

and steam was carried out, and the computations were done using ANSYS 

Fluent tool. The coolant steam is more efficient than the air when examined 

using the same conditions as shown in Fig. 3. 

 

 



220 AKRAM LUABI  , NASEER HAMZA  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 215–222 

 

 

Figure 3. Shows the result of A.B. Moskalenkoa et al. [22]. 

Results of H.D.A et. al. [24] showed that, for all materials used in the 

blade modeling, the Nusselt number and the coefficient of the heat transfer 

were constant at the surfaces of the hole while the coefficient of the heat 

transfer was high at the entrance as shown in Fig. 3. 

 

 

 

Figure 4. Shows the result of HARSHA D A et al. [24]. 

 

The results of Ziaei-Asl et. al. [27] temperature distribution, thermal 

stress, and thermal strain showed that the coating thickness has a critical 

impact on the thermal and mechanical characteristics of the blade besides 

increasing the working period of the blade (blade life) as shown in Fig. 5. 

 

Figure 5. Average and maximum temperature vs. the TBC thickness 

[27].  

The result of Narendranath et. al.  [36] noticed that the temperature 

gradient from LE to the TE on the surface of the blade was ranged from 

839.531 oC to 735.162 oC at the blade tip. The minimum thermal stress was 

1450 which is less than the yield strength of the material and the maximum 

thermal fatigue was 1217. 

And the results of Hasanpour et. al. [28] showed that temperature 

distribution at the mid-span of the external surface of the blade was in a 

good agreement compared to the experimental data as shown in Fig. 6. The 

maximum value of the temperature was noticed at the trailing edge of the 

van right at the very thin metal of the van. This value of the temperature 

was closer to the passage free stream temperature than that corresponding 

of the coolant, because of thermal resistance which was greater than the 

external conduction or convection resistance within the metal. 

 

 

Figure 6. Experimental and calculated data of [28]. 

 

 



AKRAM LUABI  , NASEER HAMZA  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 215–222                                                                                      221 

 

4. Conclusions 

The usage of a cooling process in the gas turbine blade is essential. It 

may be an external or internal cooling according to the area of application. 

Some of application like aviation engines require very high turbine inlet 

temperature and thus usage either external or internal is not sufficient and 

need to incorporate both of them. Some applications need only internal 

cooling like in medium size gas turbine used in electric power plants. The 

interest in the development of internal cooling increased considerably in the 

last decade due to its efficient merits in minimizing hot spots that occurred 

due to high turbine inlet temperature. In addition, some researchers are 

interested to investigate the effect of adding ribs inside the serpentine 

passages of cooling holes and the optimum distribution of them. The 

selection of appropriate method is a matter of economic justification 

according to the area of application.  

The goal of previous studies aforementioned is to minimize the hot 

spots that may occur due to severe conditions and resulted in thermal 

stresses as stated in Table 1. This goal is achieved via different approaches 

as stated in this comparison study and the great achievement belongs to 

Narendranath et. al. [36] where the maximum temperature is lowered by 

12%  and thermal stress was lowered by  .% 22  

 

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