Semnan University Press
Journal of Heat and Mass Transfer Research
2345-508X
2383-3068
4
1
2017
04
01
New Achievements in Fe3O4 Nanofluid Fully Developed Forced Convection Heat Transfer under the Effect of a Magnetic Field: An Experimental Study
1
11
EN
Mohammadhosein
Dibaei
Department of Mechanical Engineering, Shahrood Branch, Islamic Azad University, Shahrood, Iran
mhdibaei@gmail.com
Hadi
Kargarsharifabad
0000-0001-8145-5127
Energy and Sustainable Development Research Center, Semnan Branch, Islamic Azad University, Semnan, Iran
hadikargarsharif@gmail.com
10.22075/jhmtr.2016.486
Fe3O4 nanofluid fully developed forced convection inside a copper tube is empirically investigated under the effect of a magnetic field. All of the investigations are performed under laminar flow regime (670≤Re≤1700) and thermal boundary conditions of the tube with uniform thermal flux. The tube is under the effect of a magnetic field in certain points. This research aims to study the effect of various parameters, namely use of nanofluid, nanoparticles volume percent, Reynolds number of the flow, constant magnetic field, and alternating magnetic field with various frequencies on flow behavior. To validate the experiment set-up, distilled water is utilized as working fluid. The results are compared with Shah’s equation and acceptable agreements are achieved. The results suggest that owing to complex convectional flows developed in the fluid as a result of Fe3O4 nanoparticles-magnetic field interaction, increased alternating frequency of the magnetic field and increased volume fraction lead to increase heat transfer to maximum value 4.62. As Reynolds number increases, the rate of the said increase is reduced and reached to 0.29. At a constant Reynolds number, increased frequency of the alternating magnetic field results in an increased local heat transfer coefficient. However, this increase is unproportional to increase in frequency. In high frequencies, increased frequency leads to a slight increase in the heat transfer coefficient.
Ferrofluid,Nanoparticles,Convection,alternating magnetic field,Experimental Study
https://jhmtr.semnan.ac.ir/article_486.html
https://jhmtr.semnan.ac.ir/article_486_a078d02092f9d4583296dee84268386e.pdf
Semnan University Press
Journal of Heat and Mass Transfer Research
2345-508X
2383-3068
4
1
2017
04
01
Experimental study of free convective heat transfer in a direction-sensitive open cavity
13
20
EN
Mostafa
Rahimi
Academic staff in University of Mohaghegh Ardabili
rahimi@uma.ac.ir
10.22075/jhmtr.2016.506
The aim of the present study was to propose a panel being sensitive to the direction of heat transfer. For this purpose, a vertical rectangular cavity with prescribed dimensions was prepared and filled with water as the working fluid. A vertical mid-plane solid partition was installed within the cavity. Two relatively wide openings were created at the top and bottom of the partition and they were so equipped to operate as a pair of one-way flow controllers. The cavity was then fixed between two thick aluminum blocks by which, the contact surfaces of the cavity were maintained at almost constant but different temperatures. Heat transfer rate through the cavity was evaluated for the same temperature difference applied in the two opposed directions. Based on the results, heat transfer rate in one direction was about 30% higher than that of the reverse direction. The difference in the heat transfer rate was obviously due to the individual flow patterns developed within the modified cavity. As a result, the proposed cavity is capable of restricting heat transfer rate in one direction compared to the other, when applying the same temperature difference across the cavity.
Free convection,direction-sensitive heat transfer,vertical cavity
https://jhmtr.semnan.ac.ir/article_506.html
https://jhmtr.semnan.ac.ir/article_506_a65867bdfaf3c713f8a118938cf6360b.pdf
Semnan University Press
Journal of Heat and Mass Transfer Research
2345-508X
2383-3068
4
1
2017
04
01
Analysis of heat transfer in the pyrolysis of differently shaped biomass particles subjected to different boundary conditions: integral transform methods
21
34
EN
Gbeminiyi
M
Sobamowo
University of Lagos
mikegbeminiyi@gmail.com
Sunday
Joshua
Ojolo
University of Lagos
ojolosunday@yahoo.com
Chalse
Attah
Osheku
University of Lagos
charles.osheku@cstp.nasrda.gov.ng
A.
J.
Kehinde
University of Lagos
akehinde@unilag.edu.ng
10.22075/jhmtr.2017.1503.1100
The conversion and utilization of biomass as an alternative source of energy have been subjects of interest in various countries, but technical barriers to the technology and design of conversion plants have considerably impeded the development and use of alternative power sources. Theoretical studies on the conversion process enhance our understanding of the thermochemical conversion of solid fuels. Carrying out such research necessitates the development of thermal and kinetic models of pyrolysis, on which the conversion process integrally depends. Another requirement is to analytically solve the aforementioned models to derive valuable insight into the actual process of biomass conversion. Accordingly, this study used Laplace and Hankel transforms to obtain analytical solutions to heat transfer models of rectangular, cylindrical, and spherical biomass particles. Pyrolysis kinetic models were also analytically solved using the Laplace transform. The study then investigated the effects of particle shape, particle size, isothermal and non-isothermal heating conditions, and convective and radiative heat transfer (calculated using a modified Biot number) on the pyrolysis of a biomass particle. This work is expected to substantially contribute to the design of pyrolysis reactors/units and the optimal design of biomass gasifiers.
Energy,Biomass particles,Pyrolysis,Heat transfer,Integral transform method,Analytical solutions
https://jhmtr.semnan.ac.ir/article_2357.html
https://jhmtr.semnan.ac.ir/article_2357_36229d2f8b41a7a9c78e97b20290117e.pdf
Semnan University Press
Journal of Heat and Mass Transfer Research
2345-508X
2383-3068
4
1
2017
04
01
Numerical simulation of transient natural gas flow in pipelines using high order DG-ADER scheme
35
43
EN
Ali
Falavand Jozaei
Department of Mechanical Engineering, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran
falavand78@yahoo.com
Ali
Tayebi
Yasouj University, Yasouj, Iran.
tayebi@yu.ac.ir
Younes
Shekari
Yasouj University, Yasouj, Iran.
shekari@yu.ac.ir
Ashkan
Ghafouri
Department of Mechanical Engineering, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.
a.ghafouri@iauahvaz.ac.ir
10.22075/jhmtr.2016.497
To increase the numerical accuracy in solving engineering problems, either conventional methods on a fine grid or methods with a high order of accuracy on a coarse grid can be used. In the present research, the second approach is utilized and the arbitrary high order Discontinues Galerkin Arbitrary DERivative (DG-ADER) method is applied to analyze the transient isothermal flow of natural gas through pipelines. The problem is investigated one dimensionally and the effect of friction force between the pipe wall and fluid flow is considered as a source term on the right-hand side of the momentum equation. Therefore, the governing equations have a hyperbolic nature. Two real problems with available field data are simulated using this method. The results show that using DG-ADER method, high accurate results can be obtained even on a coarse grid. Furthermore, the conventional small-amplitude oscillations of DG-ADER scheme do not appear in the transient natural gas flow problems, due to the smoothness of flow field properties.
transient natural gas flow,Numerical simulation,high order DG-ADER scheme,isothermal flow
https://jhmtr.semnan.ac.ir/article_497.html
https://jhmtr.semnan.ac.ir/article_497_ee46c84cff5529def581b619047a3648.pdf
Semnan University Press
Journal of Heat and Mass Transfer Research
2345-508X
2383-3068
4
1
2017
04
01
Heat Transfer under Double Turbulent Pulsating Jets Impinging on a Flat Surface
45
52
EN
Morteza
Ataei
Semnan University
morteza_ataei65@yahoo.com
Reza
Tarighi
Semnan University
tarighireza@yahoo.com
Ali
Hajimohammadi
Semnan University
ali.hajimohammadi@gmail.com
Mehran
Rajabi zargarabadi
Faculty of Mechanical Engineering
rajabi@semnan.ac.ir
10.22075/jhmtr.2017.1369.1093
In this study, the numerical analysis of turbulent flow and heat transfer of double pulsating impinging jets on a flat surface has been investigated. The unsteady two-dimensional numerical solution for two similar and dissimilar jets was performed using the RNG k-ε model. The results showed that the RNG k-ε model has more satisfactory predictions of the Nusselt number distribution. Comparisons show that for two identical jets with constant frequency and amplitude, increasing Reynolds number leads to the considerable increase of time-averaged Nusselt number. Also, with increasing oscillation amplitude, the averaged Nusselt number of surface increased. The results show that increasing the phase difference angle of pulsating jets leads to the increase of mixing between jets, which consequences the increase of Nusselt number in this zone. It should be mentioned that for two jets by equal frequency and phase angle, increasing oscillating amplitude of one jet leads to an asymmetric distribution of the Nusselt number. In this case, the averaged Nusselt number between two jets increased. Furthermore, the array of double jets with different oscillating type (intermittent and sinusoidal) leads to the increase of averaged Nusselt number considerably in the stagnation region between the jets.
turbulent flow,Impingement Heat Transfer,Pulsating jet,Average Nusselt Number
https://jhmtr.semnan.ac.ir/article_2352.html
https://jhmtr.semnan.ac.ir/article_2352_93c9296fb3d5b8fca98c16cc252a67dc.pdf
Semnan University Press
Journal of Heat and Mass Transfer Research
2345-508X
2383-3068
4
1
2017
04
01
Temperature proﬁle of a power-law ﬂuid over a moving wall with arbitrary injection/suction and internal heat generation/absorption
53
64
EN
Hamideh
Radnia
university of isfahan
hamide.radnia@gmail.com
Ali Reza
Solaimany Nazar
University of Isfahan
asolaimany@eng.ui.ac.ir
10.22075/jhmtr.2017.519
The heat transfer for a non-Newtonian power-law fluid over a moving surface is investigated by applying a uniform suction/injection velocity proﬁle. The ﬂow is inﬂuenced by internal heat generation/absorption. The energy equation is solved at constant surface temperature condition. The Merk-Chao series is applied to obtain a set of ODEs instead of a complicated PDE. The converted ordinary differential equations are solved numerically, adopting the fourth order Runge–Kutta method coupled with the shooting technique. The effects of the fluid type, suction/injection and heat source/sink parameters on heat-transfer are discussed. It is observed that thermal boundary layers for pseudo plastic fluids are thicker than that of the dilatants. There exists a direct relation between dimensionless temperature and the injection parameter or the heat generation parameter rise. Injection of a ﬂuid to the surface generates more flow penetration into the fluid, which causes an increase in the thermal boundary layer and the temperature.
Heat transfer,Moving wall, Merck-Chao,Power-law
https://jhmtr.semnan.ac.ir/article_519.html
https://jhmtr.semnan.ac.ir/article_519_539ab224ddd6de88bb8c221ef9bbf6b3.pdf
Semnan University Press
Journal of Heat and Mass Transfer Research
2345-508X
2383-3068
4
1
2017
04
01
Analysis of Gasketed-plate Heat Exchanger Performance Using Nanofluid
65
72
EN
Navid
Bozorgan
Islamic Azad University of Abadan
n.bozorgan@gmail.com
Maryam
Shafahi
California State Polytechnic University, Pomona, California, USA
maryam.shafahi@email.ucr.edu
10.22075/jhmtr.2017.1089.1077
A heat exchanger using nanofluid needs to operate at optimum mass concentration level to get the maximum heat transfer performance. A numerical analysis is performed on the heat transfer and pressure drop of water-based γ-Al2O3 nanofluid gasketed-plate heat exchanger to specify its optimum conditions. Cold water will be heated by γ-Al2O3/water nanofluid. The results showed that optimal volume concentration of γ-Al2O3/water nanofluid based on a maximum performance index is about 0.016. The heat transfer rate at the optimal concentration of nanofluid is approximately 12.3% higher than that of pure water (base fluid), while pumping power is increased by 1.15%. With regard to 1% enhancement in heat transfer rate with increasing ϕ values from ϕ=0.016 to ϕ=0.028 (optimum volume concentration for maximum heat transfer rate) and the pumping power required for nanofluid, the optimum concentration for maximum performance index is selected as the best level of particle volume fraction for γ-Al2O3/water nanofluid in this research.
Nanofluid,Particle volume fraction,Gasketed-plate heat exchanger,Heat transfer,Pressure drop
https://jhmtr.semnan.ac.ir/article_2331.html
https://jhmtr.semnan.ac.ir/article_2331_ebad0cffe382a79247786cb98d2a462b.pdf