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Sains Malaysiana 49(4)(2020): 899-908
http://dx.doi.org/10.17576/jsm-2020-4904-19
Analisis Kestabilan Aliran Genangan bagi Bendalir
Mikrokutub terhadap Permukaan
Mencancang dengan Fluks Haba Ditetapkan
(Stability Analysis of Stagnation Flow of a Micropolar Fluid towards
a Vertical Surface with Prescribed Heat Flux)
FATINNABILA KAMAL1,
KHAIRY ZAIMI1 & ANUAR ISHAK2*
1Institut Matematik Kejuruteraan, Kampus Pauh Putra, Universiti Malaysia
Perlis, 02600 Arau, Perlis, Malaysia
2Pusat Pengajian Sains Matematik, Fakulti
Sains dan Teknologi, Universiti Kebangsaan Malaysia, 43600 UKM Bangi,
Selangor Darul Ehsan, Malaysia
Received:
18 September 2018/Accepted: 27 December 2019
ABSTRAK
Tujuan penyelidikan ini adalah untuk mengkaji kestabilan
aliran bendalir bagi masalah aliran genangan dalam bendalir mikrokutub
terhadap permukaan mencancang yang telap dengan fluks haba ditetapkan.
Persamaan menakluk dalam bentuk persamaan pembezaan separa tak linear
dijelmakan kepada sistem persamaan pembezaan biasa tak linear menggunakan
penjelmaan keserupaan seterusnya diselesaikan secara berangka menggunakan
penyelesai masalah nilai sempadan, bvp4c dibina dalam perisian MATLAB.
Keputusan berangka diperoleh bagi pekali geseran kulit, nombor Nusselt
setempat serta
profil
halaju dan suhu
bagi beberapa
nilai parameter menakluk yang
terlibat. Penyelesaian dual
didapati wujud bagi julat-julat tertentu parameter keapungan
atau parameter olakan campurandalam
kedua-dua aliran
membantu dan aliran
menentang. Analisis kestabilan
dilakukan untuk
menentukan penyelesaian yang
stabil dalam masa panjang. Didapati bahawa hanya satu
daripada penyelesaian
tersebut yang stabil apabila masa berlalu.
Kata kunci: Analisis
kestabilan; aliran genangan;
bendalir mikrokutub;
penyelesaian dual; sedutan/semburan
ABSTRACT
The purpose
of this study was to investigate the stability of fluid flow for the
problem of stagnation flow in a micropolar
fluid towards a vertical permeable surface with prescribed heat
flux. The governing nonlinear partial differential equations
are transformed into a system of nonlinear ordinary differential
equations using a similarity transformation
which are then solved numerically using the boundary value
problem solver, bvp4c built in MATLAB software. The numerical results are
obtained for the skin friction coefficient, local Nusselt
number as well as the velocity and temperature profiles for some
values of the governing parameters involved. Dual solutions are found to exist
for a certain range of the bouyancy parameter or the mixed convection
parameter in both assisting
and opposing flows. A stability analysis is performed
to determine which solution is stable in a long run. It is
found that only one of the solutions is stable as time passes.
Keywords: Dual solutions; micropolar fluid; stability analysis; stagnation flow; suction/injection
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*Corresponding author: email: anuar_mi@ukm.edu.my |
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