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Convective Heat Transfer of Al2O3 and CuO 
Nanofluids Using Various Mixtures of Water-

Ethylene Glycol as Base Fluids 
 

Karima Boukerma  
Department of Physics 

Faculty of Science, University of 
20 Août 1955 Skikda, Algeria 

phy_karima@yahoo.fr 

Mahfoud Kadja 
Department of Mechanical Engineering 

University of Constantine 1 
Constantine, Algeria 

kadja_mahfoud@yahoo.fr
 

 

Abstract—In this work, a numerical study has been performed 
on the convective heat transfer of Al2O3/Water-Ethylene Glycol 
(EG) and CuO/(W-EG) nanofluids flowing through a circular 
tube with circumferentially non-uniform heating (constant heat 
flux) under the laminar flow condition. We focus on the study of 
the effect of EG-water mixtures as base fluids with mass 
concentration ranging from 0% up to 100% ethylene glycol on 
forced convection. The effect on the flow and the convective heat 
transfer behavior of nanoparticle types, their volume fractions 
(φ=1-5%) and Reynolds number are also investigated. The 
results obtained show that the highest values of the average heat 
transfer coefficient is observed between 40% and 50% of EG 
concentration. The average Nusselt number increases with the 
increase in EG concentration in the base fluid, and the increase in 
the Reynolds number and volume fraction. For concentrations of 
EG above 60%, and for all volume fractions, the increase of 
thermal performance of nanofluids became inversely 
proportional to the increase of Reynolds number. In addition, 
CuO/(W-EG) nanofluids show the best thermal performance 
compared with Al2O3/ (W-EG) nanofluids. 

Keywords-enhanced heat transfer; nanofluids; numerical 
study; concentration; performance index  

NOMENCLATURE 

Cp specific heat, J kg-1 K-1 
D tube diameter, m 
d nanoparticle diameter, m 
h heat transfer coefficient, W m-2 k-1 
k thermal conductivity, W·m-1·K-1 
L length of the tube, m 

Nu Nusselt number 
P Pressure, pa 
qw uniform heat flux, W m

-2 
Re Reynolds number (ρwinD/μ)  
r radial direction 
T temperature, K 
u tangential velocity, m s-1 
v radial velocity, m s-1 
w axial velocity, m s-1 

Z axial direction 
Greek symbols 

P  pressure drop, Pa 
θ angular coordinate 

μ Viscosity, kg m-1 s-1 
φ volume fraction 
ψ volume fraction of mixture 
  density, kgm-3 
κ Boltzmann constant,   1.38110-23, J k-1 

Subscripts 
ave average 
b bulk 
bf base fluid 
in inlet 
nf nanofluid 
p nanoparticle 
w wall 

I. INTRODUCTION  
The efforts to enhance the heat exchangers performance in 

many industrial sectors (automotive, electronics, etc.) require 
the intensification of heat transfer by convection. 
Improvements in exchange surfaces are a pathway already 
widely explored and reach their limits [1]. New optimization 
pathways must be considered. One of them is to use new fluids 
able to increase heat transfer such as the nanofluids. The 
nanofluids are nano-sized particle dispersions in a base fluid in 
order to improve certain properties. The diameter of such 
particles (called nanoparticles) is typically less than 100 nm 
[2]. In the case of a cooling liquid, one of the leading 
parameters to be taken into account to evaluate the potential for 
heat exchange is the thermal conductivity. However, the most 
widely used fluids, such as water, ethylene glycol (EG) or oil 
have only a low thermal conductivity relative to that of the 
solid. With nanofluids, the idea is to insert the nanoparticles in 
a base fluid in order to increase the effective thermal 
conductivity of the mixture.  

In [3], authors studied the nanofluids by preparing a mix of 
100 nm of Cu nanoparticles with water and oil. They found that 



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the thermal conductivity of nanofluids increases considerably 
with the concentration of nanoparticles. Then they proposed a 
correlation to calculate the Nusselt number as a function of 
Peclet number for nanofluids. In [4], authors experimentally 
studied the forced convection laminar flow of CuO/water and 
Al2O3/water nanofluids in a tube under constant temperature. 
They indicated that there is an increase in heat transfer with an 
increase in volume concentration for both nanofluids, but they 
found that Al2O3 nanoparticles are more performant. In [5], 
authors studied a two dimensional laminar flow inside a 
triangular duct with the existence of a vortex generator. Three 
types of nanofluids (Al2O3/EG, CuO/EG and SiO2/EG) with 
volume concentrations ranging from 1 to 6% were considered. 
Their results show that SiO2/EG has the highest value of 
Nusselt number compared to other nanofluids. On the other 
hand, the value of the friction coefficient is the same for all 
nanofluids and nanoparticles concentrations considered.  

 Due to its relatively low molecular weight, ethylene glycol 
greatly lowers the water freezing point. Therefore, the mixture 
of water–ethylene glycol was often used in cold countries [6-7]. 
Several researchers measured experimentally the rheological 
properties of nanofluids with an EG-water mixture base fluid 
[8-10], and they proposed correlation equations for the 
thermophysical properties such as: viscosity, thermal 
conductivity and specific heat [11-12]. These properties were 
used to develop correlations for Nusselt number and/or friction 
factor from experiments, as a function of these properties and 
the nanoparticle volume concentrations [13-15]. In [16], 
authors conducted an experimental study on the forced 
convective heat transfer of TiO2 nanoparticles with mixture of 
EG-water (40:60 by volume) in a copper tube under laminar 
conditions. Moreover, they studied the effect of mixtures of 
water and EG base fluid with different volume fractions 
(ranging from 0 % up to 50 % ethylene glycol) on local Nusselt 
number. They found that there is 8.25 –20.52% increase in 
Nusselt number when the EG fraction in water increases from 0 
to 50%. In [17], authors measured the heat transfer coefficient 
of the secondary refrigerant based CNT (carbon nanotubes) 
nanofluid in a tubular heat exchanger at different operating 
temperatures. The base fluid was a mixture of EG -water 
(30:70 by volume). The obtained results showed that at 40 °C 
with a 0.45 Vol. % CNT nanofluid the increase in thermal 
conductivity and average convective heat transfer coefficient 
was 19.73% and 159.3% respectively. They concluded that 
such increases occur because of the micro convection effects of 
the chaotic movement of the carbon nanotubes. In another 
study [18] with the same nanofluid cited above they 
investigated the convective heat transfer in various lengths of a 
tubular heat exchanger. They reported that contrary to what is 
customary for heat transfer, the Nusselt number decreases with 
an increase in the Reynolds number as the MWCNT 
(multiwalled carbon nanotubes) concentration increases in the 
base fluid.  

Most of the articles, which dealt with the experimental or 
numerical research on heat transfer and nanofluid flow with an 
EG-water mixtures base fluid, are for fixed EG fractions in 
water and only a few considered different volume fractions, but 
in maximum up to 50%. This research focuses on the study of 
the effect of ethylene glycol based Al2O3 and CuO nanofluids 

on forced convection in a circular tube with circumferentially 
non-uniform heating. The EG-water mixtures used in the 
computations have EG mass concentrations which vary in the 
interval from 0% up to 100 %. Heat transfer with 
circumferentially non-uniform heating occurs in many 
applications such as evaporators, boilers and solar collectors 
[1]. 

II. NUMERICAL SIMULATION 

A. Geometry  
In this study, we considered laminar forced convection flow 

of a nanofluid in a straight cylindrical pipe with a diameter D 
of 0.01m and the length L of 1m. The length was chosen so as 
to obtain hydrodynamically and thermally fully-developed flow 
at the outlet section. The tube was heated on one side (upper 
half) with a constant heat flux and insulated over the lower 
side. The problem treated is shown schematically in Figure 1. 

 

 
Fig. 1.   Geometry and boundary conditions  

B. Governing equations  
Our problem is modelled as laminar, steady flow and the 

three-dimensional one phase model for the nanofluid was used. 
Pressure work and dissipation are neglected. The 
thermophysical properties of the nanofluid are assumed to be 
constant. Under these assumptions the governing mass, 
momentum and energy equations for the nanofluid can be 
written as follows: 

Continuity equation: 

  0 Vnf     (1) 
Momentum equations: 

   VPVV nfnf    (2) 
Energy equation: 

    TkTVC nfnfp    (3) 
C. Boundary conditions 

The nanofluid enters the channel at the inlet with a uniform 
axial velocity that is specified according to the flow Reynolds 
number. The inlet temperature Tin is taken as 300 K. The no-
slip boundary conditions at the walls are implemented in the 
present study, and a constant heat flux (5 kW/m2) is applied 
through the top half of the tube, while the bottom wall is 
considered adiabatic. For the channel outlet, the fully 
developed flow boundary condition is adopted. The boundary 
conditions can therefore be expressed as: 

• At the inlet of tube (z=0): 
inin TTandvuww  0,   (4) 



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• At the fluid-wall interface (r=D/2): 
0 wvu    (5) 

w
nf

nf q
r

T
k 




 :0   (6) 

0:2 




r

T
k nfnf  (7) 

• At the tube outlet (z=L): the outflow boundary condition 
is applied, in which the flow velocity and temperature 
profiles are unchanging in the flow direction. 

C. Thermophysical properties 
The base fluid is a mixture of water and EG in different 

mass concentrations, their thermophysical properties are 
calculated as follows [19]: 

  WaterEGm   1   (8) 
Where m refers to “mixture”, ψ is the volume fraction of 

the mixture and ζ is the fluid physical property, for example: 
density, specific heat, thermal conductivity and viscosity. The 
thermophysical properties of the mixture are greatly modified 
by the addition of nanoparticles. Many parameters 
characterizing these nanoparticles can have a significant effect 
on the values of the thermophysical parameters of the nanofluid 
obtained (the volume fraction φ, the size of the nanoparticles, 
the thermal conductivity of the base fluid and that of the 
nanoparticles, the temperature of the medium, etc.).  The 
thermophysical properties of water, Ethylene Glycol (EG), 
Al2O3 and CuO are summarized in Table I. In this work, we 
assume that the nanoparticles are well dispersed in the base 
fluid. In order to calculate the thermophysical properties of the 
nanofluid, we use the equations given below which were found 
in the literature. In [9], author compared their density 
measurements of different nanoparticles in a base fluid of 
60:40 ethylene glycol/water with predictions using equation (9) 
which was proposed in [20], and they found an excellent 
agreement between them.  

  pbfnf   1   (9) 
Where

nf , bf  and p  are the nanofluid, base fluid and 
nanoparticles densities, respectively, and φ is the volume 
fraction. 

The specific heat of nanofluids 
pnfC  is computed using 

Xuan and Roetzel’s equation [21]. 
 

nf

ppppbfbf
pnf

CC
C


 


1   (10) 

Where 
pbfC  and ppC  are specific heat at constant pressure 

of the base fluid and nanoparticles, respectively. 

The thermal conductivity formula proposed by Vajjha and 
Das [8] was used in this study. It incorporates the classical 
Maxwell model and the Brownian motion effect and is given 
by: 

 
   







,105
2

22 4 Tf
d

T
Ck

kkkk

kkkk
k

pp
pbfbfbf

pbfbfp

pbfbfp
nf 


  (11) 

Where the empirical function  ,Tf  for the nanofluids 
Al2O3 and CuO is given by: 

( ) ( )2 3
0

, 2.8217 10 3.917 10
T

f T
T

f f- -
æ ö÷ç ÷ç= ´ + ´ +÷ç ÷÷çè ø

 

 ( )2 33.0669 10 3.91123 10f- -- ´ - ´   (12) 
The factor   is presented in Table II. It is found using the 

experimental data of [8], and it represents the fraction of the 
liquid volume that travels with a particle. 

The viscosity of the nanofluid μnf is function of the volume 
fraction and viscosity of the base fluid μbf and is evaluated 
using the following equation [23]: 

 
bf

A
nf eA 

2
1  (13) 

Where A1 and A2 are constants, their values are given in 
Table III. 

TABLE I.  THERMOPHYSICAL PROPERTIES OF NANOPARTICLES AND BASE 
FLUIDS AT T=300 K [22, 27] 

Properties Water EG Al2O3 CuO 
Density (kg/m3) 997 1,114.4 3,600 6,500 

Thermal Conductivity 
(W/m K) 

0.613 0.252 36 17.65 

Specific Heat (J/kg K) 4179 2415 765 533 

Viscosity (N/m2 s) 0.000855 0.0157 - - 

TABLE II.  THE VALUES OF THE FACTOR b  FOR AL2O3 AND CUO 
NANOPARTICLES. 

Type of 
particles 

β concentration Temperature 

Al2O3 8.4407(100φ)
-1.07304 1%≤φ≤10% 298k≤T≤363k 

CuO 9.881(100 φ)-0.9446 1%≤φ≤6% 298k≤T≤363k 

TABLE III.  VISCOSITY COEFFICIENTS FOR AL2O3 AND CUO 
NANOPARTICLES. 

nanoparticles A1 A2 concentration 

Al2O3 0.983 12.959 1%≤ φ ≤10% 

CuO 0.9197 22.8539 1%≤ φ ≤6% 

III. NUMERICAL METHOD AND VALIDATION  
The simulation was carried out using FLUENT. The 

resolution of (1)-(3) is performed by discretizing the 
computational domain. In this way, all the discrete points 
constitute the computational domain mesh. At each discrete 
point of the domain, FLUENT uses the finite volume method 
for obtaining algebraic expressions which replace the non-
linear partial differential equations and which can be solved 
numerically. The resulting set of algebraic equations predicts 
the mass, momentum and energy in all the discrete points of the 
mesh. The finite volume method consists of integrating the 
conservation equations over each control volume in the mesh. 
The convective and viscous terms are discretized with a second 
order upwind scheme for more accuracy. The SIMPLE 
algorithm is used for pressure-velocity coupling. The 
convergence of the iterative process is determined by the 
concept of residues. In this study, the discretized equations are 
considered converged when all the equations have a residue 
less than 10-6. The Gambit software was used to perform a 3D 
mesh. After several trials, we obtained the threshold of the 



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grids finesse above which the calculated solution becomes grid 
independent.  

The simulation was carried out on three types of grids 
(5  32  500, 7  40  500, 10  64  500) for pure water.  
Figure 2 shows the independence test for the calculated local 
Nusselt number along the tube on the grids used. According to 
the result of this test the mesh chosen is that with an average 
number of discretization points equal to (740500). We can 
also notice in Figure 2 that our numerical results are in good 
agreement with the correlation developed in [28]. The 
validation of the CFD code has also been tested using the 
experimental results obtained by [24]. This result concerns the 
laminar flow in a circular tube heated by a constant flux where 
the heat flux (qw) equals to 9000 W/m

2 and the Reynolds 
number (Re) is about 799.53. The results for the local Nusselt 
number (Figure 3) agree well with our results. 

 

 
Fig. 2.  Comparison of local Nusselt number values for different grids 

 
Fig. 3.  Comparison of numerical local Nusselt number with the 

experimental values of [24] 

The local Nusselt number and local heat transfer coefficient 
are calculated using the following equations: 

k

Dzh
zNu




)(
)(   (14) 

 
   bw

w

zTzT

q
zh


   (15) 

Where D and T(z)w are the tube diameter and wall 
temperature respectively, and T(z)b is the bulk fluid 
temperature calculated as follows: 




A
z

A
z

b
dAV

dATV
zT




)(   (16) 

The average heat transfer coefficient (have) and Nusselt 
number are expressed as [25]: 

bw

ave
TT

q
h


    (17) 

k

Dh
Nu aveave


   (18) 

Where 
wT  and bT  are the wall and fluid average temperature 

respectively. 

IV. RESULTS AND DISCUSSION  
The convective heat transfer was numerically investigated 

for flow of Al2O3 and CuO nanofluids in a horizontal 
cylindrical tube which was heated on one side. Mixtures of 
Ethylene glycol/water as base fluid with mass concentration 
ranging from 0% to 100% ethylene glycol were used (so we get 
eleven base fluids). The computations were carried out with the 
Reynolds numbers of 250, 500, 750 and 1000, and with 
different volume fractions of the nanoparticles which vary from 
0% to 5%. Figure 4 shows the average heat transfer coefficient 
(have) of base fluid mixtures of water/EG at different Reynolds 
numbers. The highest values of the average heat transfer 
coefficient is observed between 40% and 50% of EG 
concentration, for instance at Re=250 the values are 681.3 and 
683.7 (W/m2K) respectively. As expected the heat transfer 
coefficient increases when the Reynolds number increases. At a 
given Reynolds number, the base fluid mixtures of water-EG 
(with different mass. % of EG) have highest average heat 
transfer coefficients, followed by ethylene glycol and pure 
water respectively. The effect of volume fraction (φ%) on 
average heat transfer coefficient for Al2O3/W-EG nanofluids at 
Re=1000 is depicted in Figure 5. 

 The average heat transfer coefficient increases as the 
volume fraction of Al2O3 nanoparticles increases in the base 
fluid. Also we can see that the highest values of have are 
between 40% and 50% of EG concentration. The influence of 
the Reynolds number and the volume fraction on average 
Nusselt number is illustrated in Figures 6 and 7. Figure 6 shows 
the effect of Re on the average Nusselt number (Nuave) for a 
low volume fraction (1%) of Al2O3 nanoparticles.  Nuave of 
Al2O3/(water-EG) nanofluids is found to be higher than that of 
Al2O3/water and lower than that of Al2O3/EG. The reason being 
that the thermal conductivity of water is greater than that of 
water-EG mixtures and EG, respectively. Figure 7 represents 
the variation of Nuave with volume fraction of CuO/(water-EG) 
nanofluids at Re=1000. The average Nusselt number of the 
nanofluids is greater than that of base fluids. Nuave increases as 
the concentration of ethylene glycol in the base fluid or the 
Reynolds number or the volume fraction increase. The 
enhancement of thermal performance with CuO nanofluids is 
higher than that with Al2O3 nanofluids especially at great 
values of Reynolds number and volume fraction.  

Figure 8 shows the thermal performance of nanofluids 
using different concentrations of ethylene glycol in the base 
fluid. The curves present the results of the average heat transfer 
coefficient ratio (hnf/hbf) between the nanofluid and the base 
fluid (it should be noted again that each concentration of EG 
represents a base fluid) at different volume fractions. As can be 
noticed there is an increase in heat transfer ratio as the 



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nanoparticle volume fraction increases. In the case of Al2O3 
nanoparticles and at Re=250 the heat transfer coefficient ratio 
increases with the increase of the concentration of EG in the 
base fluid; but for other values of Re the ratio hnf/hbf increases 
and then it decreases, for instance at Re=500 and 1,000 the 
decrease in the ratio occurs at 80% and 40% of EG, 
respectively. Consequently, it is observed that the increase in 
the ratio hnf/hbf is directly proportional, as expected, to the 
increase of the Reynolds number for concentrations situated 
between 0% to 20% of EG. For concentrations between 30% 
and 40% of EG this ratio has approximately the same value. 
We find that from 50% of EG the ratio hnf/hbf decreases with 
increasing Reynolds number and that this decrease appears 
more clearly from 80 % of EG in the base fluid. 

 

 
Fig. 4.  Effect of Reynolds number and water-EG mixture on average heat 

transfer coefficient 

 
Fig. 5.  Variation of average heat transfer coefficient with volume fraction 

for Al2O3/(W-EG) nanofluids 

Concerning the CuO nanoparticles, we always get the same 
behavior as regards the influence of the concentration of EG on 
the heat exchange ratio for the different Reynolds numbers. But 
we note that the decrease of the ratio hnf/hbf appears at a 
concentration of EG more advanced (about 30% of EG at 
Re=1,000 and φ=4%) and in a faster manner than that of  Al2O3 
nanofluids, and the inverse proportionality occurring between 
the heat transfer ratio and the Reynolds number happens early 
at a concentration of 40% of EG in the base fluid. We can 
clearly observe from Figure 8 that the CuO/(W-EG) nanofluids 
have the best average heat transfer coefficient ratio (heat 
transfer enhancement) compared with Al2O3/(W-EG) 
nanofluids. The inverse relationship that occurs between the 
convective heat transfer ratio and the Reynolds number and 
which increases with the volume fraction and the concentration 
of EG in base fluid, is probably caused by the increase in the 
viscosity upon the addition of nanoparticles and also because of 

the high viscosity of the EG compared to water, and may be at 
low Reynolds numbers the increase of concentration of EG in 
the base fluid makes the nanoparticles more effective. 

 

 

Fig. 6.  Variation of Nusselt number with Reynolds number for Al2O3/(W-
EG) nanofluids 

 

Fig. 7.  Variation of Nusselt number with volume fraction for CuO/(W-
EG) nanofluids. 

From the above observations the nanofluids appear to be 
ideal when considering an increase in the thermal performance 
of heat transfer equipment. The addition of nanoparticles in a 
fluid allows an increase of the thermal conductivity but 
unfortunately also the viscosity which usually leads to an 
increase in pressure loss in the system. In the industrial 
applications of nanofluids, although an improvement of heat 
transfer is observed, the required pump power is increased 
compared with the case of the conventional fluid. A significant 
increase in the viscosity of the nanofluid could lead to an 
unfavorable energy performance of the industrial system. To 
illustrate this, we used a performance index "η" [26], where η 
represents the ratio between heat transfer enhancement and 
pressure drop in the system: 

,

,

ave nf nf

ave bf bf

h P

h P
h

æ ö æ öD÷ç ÷ç÷ç ÷ç÷= ç ÷ç÷ ÷ç ÷ çD ÷çç ÷ç è øè ø

 (19) 

Where
bfaveh ,  and bfP  are the average heat transfer 

coefficient and pressure drop of base fluids. 

To determine the effectiveness of each nanofluid, relative to 
its base fluid, Figure 9 shows the variation of the performance 
index with Al2O3/(W-EG) and CuO/(W-EG) nanofluids for 
various volume fractions at Re=500. In this case have,bf and ΔΡbf 
are the average heat transfer coefficient and pressure drop of 
the water-EG base fluid, respectively. As shown in this figure 
the performance index is below 1. So we can conclude that the 
base fluid (W-EG) is more effective, from the thermal point of 



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view, than the nanofluids. It is noted that the performance 
index decreases with the increase of the volume fraction of the 
nanoparticles, but it does not change with the concentration of 
EG (that is why we stopped at 50% of EG in this figure). We 
also see that the performance index of Al2O3 nanofluids is 
higher compared to the one of CuO nanofluids. 

 

 
 

 

Fig. 8.  Effect of different base fluids on heat transfer enhancement for 
various Reynolds numbers and nanoparticles. 

Figure 10 shows the evolution of the performance index as 
a function of the Reynolds number in the case of water-EG 
based fluids. We can see that all the values corresponding to 
the base fluids (W-EG) are above those corresponding to the 
case of pure EG. This means that the performance index of 
base fluids, as it is defined, is favorable for the whole range of 
the concentration of EG. However, this performance index has 
significantly decreased with an increase of the concentration of 
EG in the base fluid. For example when the concentration of 
EG varies from 10% to 90%, η decreases from 49.36 to 1.36 
for Re=1,000. On the other hand, there is a small change in the 
value of the performance index with Reynolds number. 

The evolution of the performance index with Al2O3/(W-
EG) nanofluids for different volume fractions at Re=500 is 
depicted in Figure 11. We note that the performance index 
decreases when the volume fraction of nanoparticles and the 
concentration of EG increase. For the concentration of EG 
varying from 10% to 70% in the base fluid we have a 
performance index greater than 1, which implies the use of 
nanofluids is favorable than pure EG. But from 80% of EG 
onwards the performance index becomes less than 1 for some 
volume fractions. For example η is less than 1 at φ= 4 % for the 
concentration of 80% of EG and at φ=2%, for the concentration 
of 90% of EG. 

 
 

 
Fig. 9.  Variation of the performance index for different volume 

fractions.with Al2O3/(W-EG) and CuO/(W-EG) nanofluids 

 
Fig. 10.  Evolution of the performance index as a function of the Reynolds 

number for different base fluids 

 
Fig. 11.  Variation of the performance index with Al2O3/(W-EG) nanofluids 

for different volume fractions. 

Figure 12 shows the variation of the performance index 
with CuO/(W-EG) nanofluids for different volume fractions at 
Re=500. It is observed that the performance index is greater 
than 1 up to 50% of EG, and then begins to decrease when the 
volume fraction and the concentration of EG increase. For 
instance, η is less than 1 at φ=5% for the concentration of 60% 
of EG and at φ=3% for the concentration of 80% of EG. 



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According to the two figures, we see that the performance 
index is always greater than 1 for φ=1%, and we also see that 
the Al2O3/(W-EG) nanofluids have the highest performance 
index that the CuO/(W-EG) nanofluids. 

 

 
Fig. 12.  Variation of the performance index with CuO/(W-EG) nanofluids 

for different volume fractions 

V. CONCLUSION 
We investigated in the present research the effect of water- 

EG based nanofluids with various compositions on convective 
heat transfer performance. Heat transfer due to Al2O3/(W-EG) 
and CuO/(W-EG) nanofluids flow inside a circular tube is 
studied numerically. The top half of the tube is heated with 
constant heat flux while the bottom is insulated. Based on the 
presented results, the following conclusions can be drawn: 

• Between 40% and 50% of concentration of EG, the average 
heat transfer coefficient has highest values. This coefficient 
increases when the nanoparticle volume fraction and 
Reynolds number increase. 

• The average Nusselt number of nanofluids with W-EG base 
fluids is found to be higher than that of water based 
nanofluids and lower than EG based nanofluids. 

• The average heat transfer coefficient ratio (hnf/hbf) increases 
when the volume fraction of nanoparticles increases. 
However, from 60% of concentration of EG, these ratios 
decrease with the increase of the Reynolds number. 

• The use of the nanofluids Al2O3/(W-EG) and CuO/(W-EG) 
is unfavorable compared to the use of pure water or water-
EG base fluids, but its use is favorable compared to the use 
of pure EG, except at higher concentration of EG and some 
volume fractions of nanoparticules. 

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