modul kuliah mekanika fluida 1
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TEP201 Fluid Mechanics 1
MEKANIKA FLUIDA(TEP201)
• Dr. Ir. Erizal, MAgr.• Dr. Ir. Nora Herdiana Panjaitan, DEA.
• Dr. Ir. Yuli Suharnoto• Dr. Ir. Roh Santoso
Departemen Teknik PertanianFakultas Teknolog Pertanian
Institut Pertanian Bogor
TEP201 Fluid Mechanics 2
MEKANIKA FLUIDA
Mempelajari tentang fluida yang bergerak atau diam dan akibat yang ditimbulkan oleh fluida tersebut pada tempatnya.
TEP201 Fluid Mechanics 3
Tujuan Instruksional Umum
• Setelah menyelesaikan mata kuliah ini, mahasiswa diharapkan mampumenguraikan karakteristik fluida baikdalam keadaan diam maupun bergerakdalam kaitannya dengan kegiatanperencanaan, pengelolaan dan perancangan
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JADWAL KULIAH
No. Pokok Bahasan Pengajar 1 Pendahuluan Erizal
2-3 Fluida Statik Erizal 4-5 Konsep aliran fluida Yuli Suharnoto 6 Aliran fluida ideal Yuli Suharnoto 7 Aliran fluida kompresibel Nora Panjaitan
8-9 UTS 10-11 Aliran fluida nyata di dalam pipa Nora Panjaitan
12 Mesin-mesin fluida Roh Santoso 13 Teori lapisan batas Erizal
14-15 Aliran fluida pada saluran terbuka Roh Santoso 16 Analisis dimensi dan similitude Yuli Suharnoto
Selasa 07.00-08.40 / Rabu 15.00-16.40
Sebagian bahan kuliah dapat diambil di:http://web.ipb.ac.id/~erizal/mekflud/
TEP201 Fluid Mechanics 5
JADWAL PRAKTIKUM
No. Topik 1 Pendahuluan 2 Bilangan Reynold 3 Penentuan koefisien Orifice dan Venturi 4 Head loss karena gesekan 5 Head loss karena perubahan diameter pipa 6 Head loss karena belokan dan katup 7 Pengukuran debit aliran udara di pipa 8 Pengukuran debit aliran di saluran terbuka 9 Aliran kritis 10 Lompatan hidrolik 11 Ujian praktikum
TEP201 Fluid Mechanics 6
PRAKTIKUM
1. Mahasiswa harap hadir paling lambat 5 menit sebelum praktikum dimulai di Laboratorium Hidrolika dan Hidromekanika Departemen Teknik Pertanian (F-G204).
2. Praktikum dilaksanakan 4 kali dalam 1 minggu (Selasa, Rabu, Kamis, dan Jum’at).3. Pelaksanaan praktikum secara kelompok/grup yang terdiri atas 6-7 mahasiswa.4. Pertanyaan sebelum praktikum wajib dijawab dan diserahkan kepada dosen/asisten
dosen.5. Praktikum harus selalu dihadiri. Jika berhalangan harus mendapatkan surat izin dari
departemen.6. Setelah praktikum dilaksanakan, buatlah laporan sementara berisi data hasil
pengukuran yang dilengkapi dengan daftar anggota grup/kelompok.7. Laporan perseorangan dan ditulis dengan tangan pada kertas ukuran A4, kemudian
penyerahannya paling lambat sebelum praktikum dimulai pada minggu berikutnya.8. Laporan berisi :
• Pendahuluan yang berisi teori singkat dan tujuan praktikum• Bahan dan Metode• Hasil dan Pembahasan• Kesimpulan dan Saran• Daftar Pustaka
9. Segala bentuk pelanggaran dapat diberikan sanksi akademik berupa : skorsingpraktikum, tidak diperkenankan mengikuti ujian, dan lain sebagainya.
10.Pada akhir semester akan diadakan ujian praktikum oleh dosen.
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PENILAIAN & PUSTAKA• Praktikum : 30% • UTS : 30%• Ujian Akhir : 40%
Streeter, V.L. dan E.B. Wylie. 1999. Mekanika Fluida. PenerbitErlangga. Jakarta.Giles, Ranald, V. 1994. Fluid Mechanics and Hydraulics. Schaum’s Outline Series. McGraw Hill Book Co. New YorkHughes, W.F dan J.A. Brighton. 1967. Theory and Problem of Fluid Dynamic. Schaum’s Outline Series. McGraw Hill Book Co. New YorkVennard, J.K dan R.L. Street. 1976. Elementary Fluid Mechanics. John Wiley and Sons. New YorkErizal dan Panjaitan, N.H. 2007. Pedoman Praktikum Mekanika Fluida. IPB.
TEP201 Fluid Mechanics 8
Introduction to Fluid Mechanics*
CFD(Computational Fluid Dynamics)
EFD(Experimental Fluid Dynamics)
AFD(Analytical Fluid Dynamics)
2
01
Re i jD p u uDt
∇ • =
= −∇ + ∇ + ∇ •
UU U
Fred Stern, Tao Xing, Jun Shao, Surajeet Ghosh
*Revised version of 4/99 by Fred Stern and Eric Paterson
TEP201 Fluid Mechanics 9
Fluid Mechanics
• Fluids essential to life• Human body 95% water• Earth’s surface is 2/3 water• Atmosphere extends 17km above the earth’s surface
• History shaped by fluid mechanics• Geomorphology• Human migration and civilization• Modern scientific and mathematical theories and methods• Warfare
• Touches every part of our lives
TEP201 Fluid Mechanics 10
HistoryFaces of Fluid Mechanics
Archimedes(C. 287-212 BC)
Newton(1642-1727)
Leibniz(1646-1716)
Euler(1707-1783)
Navier(1785-1836)
Stokes(1819-1903)
Reynolds(1842-1912)
Prandtl(1875-1953)
Bernoulli(1667-1748)
Taylor(1886-1975)
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Significance
• Fluids omnipresent• Weather & climate• Vehicles: automobiles, trains, ships, and
planes, etc.• Environment• Physiology and medicine• Sports & recreation• Many other examples!
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Weather & Climate
Tornadoes
HurricanesGlobal Climate
Thunderstorm
TEP201 Fluid Mechanics 13
Vehicles
Aircraft
SubmarinesHigh-speed rail
Surface ships
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Environment
Air pollution River hydraulics
TEP201 Fluid Mechanics 15
Physiology and Medicine
Blood pump Ventricular assist device
TEP201 Fluid Mechanics 16
Sports & Recreation
Water sports
Auto racing
Offshore racingCycling
Surfing
TEP201 Fluid Mechanics 17
Fluids Engineering
• Engineers have different kinds of tools available for solving fluids engineering systems• Analytical Fluid Dynamics (AFD)• Experimental Fluid Dynamics (EFD)• Computational Fluid Dynamics (CFD)
• This class provides an introduction to all three tools: AFD through lecture and CFD and EFD through labs
TEP201 Fluid Mechanics 18
Analytical Fluid Dynamics
• The theory of mathematical physics problem formulation
• Control volume & differential analysis• Exact solutions only exist for simple
geometry and conditions• Approximate solutions for practical
applications• Linear• Empirical relations using EFD data
TEP201 Fluid Mechanics 19
Analytical Fluid Dynamics
• Lecture Part of Fluid Class• Definition and fluids properties• Fluid statics• Fluids in motion• Continuity, momentum, and energy principles• Dimensional analysis and similitude• Surface resistance• Flow in conduits • Drag and lift
TEP201 Fluid Mechanics 20
Analytical Fluid Dynamics
Schematic
• Example: laminar pipe flow
Exact solution :2 21( ) ( )( )4
pu r R rxμ∂= − −∂
Friction factor:88 64
Re2 2w
dudywf
V V
μτρ ρ
= = =
Assumptions: Fully developed, Low Approach: Simplify momentum equation, integrate, apply boundary conditions (no-slip wall) to determine integration constants and use energy equation to calculate head loss
xgyu
xu
xp
DtDu
+⎥⎦
⎤⎢⎣
⎡∂∂
+∂∂
+∂∂
−= 2
2
2
2
μ
Head loss:1 2
1 2 fp pz z hγ γ
+ = + +2
2
322f
L V LVh fD g D
μγ
= =
UD 2000Re ρ <μ
=
0 0 0
TEP201 Fluid Mechanics 21
Analytical Fluid Dynamics• Example: turbulent flow in smooth pipe( )
0 5y+< <
1 lnu y Bκ
+ += + 520 10y+< <
*0
1U u rfu r
⎛ ⎞−= −⎜ ⎟
⎝ ⎠
510y + >
u y+ +=
( ) ( ) *0
*
1 lnu r r r u
Bu κ ν
−= +
Re 3000>
*y yu ν+ =*u u u+ =*
wu τ ρ=Three layer concept (using dimensional analysis)
1. Laminar sub-layer (viscous shear dominates)
2. Overlap layer (viscous and turbulent shear important)
3. Outer layer (turbulent shear dominates)
Assume log-law is valid across entire pipe:
Integration for average velocity and using EFD data to adjust constants:
( )1 21 2log Re .8ff
= −
( =0.41, B=5.5)
TEP201 Fluid Mechanics 22
Analytical Fluid Dynamics• Example: turbulent flow in rough pipe
( )u u y k+ +=
1 ln yukκ
+ = +
1 2log3.7k D
f= −( )1 ln 8.5 Reyu f
kκ+ = + ≠
Three regimes of flow depending on k+
1. K+<5, hydraulically smooth (no effect of roughness)2. 5 < K+< 70, transitional roughness (Re dependent)3. K+> 70, fully rough (independent Re)
Both laminar sublayer and overlap layerare affected by roughnessInner layer:
Outer layer: unaffected
Overlap layer:
Friction factor:
For 3, using EFD data to adjust constants:
constant
TEP201 Fluid Mechanics 23
Analytical Fluid Dynamics• Example: Moody diagram for turbulent pipe flow
1 1 22
1 2.512log3.7 Rek D
ff
⎡ ⎤= − +⎢ ⎥
⎣ ⎦
Composite Log-Law for smooth and rough pipes is given by the Moody diagram:
TEP201 Fluid Mechanics 24
Experimental Fluid Dynamics (EFD)
Definition:Use of experimental methodology and procedures for solving fluids engineering systems, including full and model scales, large and table top facilities, measurement systems (instrumentation, data acquisition and data reduction), uncertainty analysis, and dimensional analysis and similarity.
EFD philosophy:• Decisions on conducting experiments are governed by the ability of the
expected test outcome, to achieve the test objectives within allowable uncertainties.
• Integration of UA into all test phases should be a key part of entire experimental program • test design • determination of error sources • estimation of uncertainty • documentation of the results
TEP201 Fluid Mechanics 25
Purpose
• Science & Technology: understand and investigate a phenomenon/process, substantiate and validate a theory (hypothesis)
• Research & Development: document a process/system, provide benchmark data (standard procedures, validations), calibrate instruments, equipment, and facilities
• Industry: design optimization and analysis, provide data for direct use, product liability, and acceptance
• Teaching: instruction/demonstration
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Applications of EFD
Application in research & development
Tropic Wind Tunnel has the ability to create temperatures ranging from 0 to 165 degreesFahrenheit and simulate rain
Application in science & technology
Picture of Karman vortex shedding
TEP201 Fluid Mechanics 27
Applications of EFD (cont’d)
Example of industrial application
NASA's cryogenic wind tunnel simulates flight conditions for scale models--a critical tool indesigning airplanes.
Application in teaching
Fluid dynamics laboratory
TEP201 Fluid Mechanics 28
Full and model scale
• Scales: model, and full-scale
• Selection of the model scale: governed by dimensional analysis and similarity
TEP201 Fluid Mechanics 29
Measurement systems• Instrumentation
• Load cell to measure forces and moments• Pressure transducers• Pitot tubes• Hotwire anemometry• PIV, LDV
• Data acquisition• Serial port devices• Desktop PC’s• Plug-in data acquisition boards• DA software - Labview
• Data analysis and data reduction• Data reduction equations• Fast Fourier Transform
TEP201 Fluid Mechanics 30
Instrumentation
Load cell
Pitot tube
Hotwire 3D - PIV
TEP201 Fluid Mechanics 31
Data acquisition system
Hardware
Software - Labview
TEP201 Fluid Mechanics 32
Data reduction methods
f = F( , , z , Q =� � )a
a
wg D�
8LQ
�
�
Q = F( z )�
w
DM
SM
2
2
5
= F(T )�
�
( )
w
= F(T )a
zSM
i
- zSM
j
w
a
Example of data reduction equations
Fast Fourier Transform
FFT: Converts a function from amplitude as function of time to amplitude as function of frequency
Example of FFT application
Aim: To analyze the natural unsteadiness of the separated flow, around a surface piercing
strut, using FFT.f [Hz]
A(f)
0 1 2 3 4 5 6 70
0.05
0.1
0.15
Typical amplitude spectraof the wave elevations
Free-surface wave elevation contours
TEP201 Fluid Mechanics 33
Uncertainty analysis
r = r (X , X ,......, X ) 1 2 J
1 2 J
MEASUREMENTOF INDIVIDUALVARIABLES
INDIVIDUALMEASUREMENTSYSTEMS
ELEMENTALERROR SOURCES
DATA REDUCTIONEQUATION
EXPERIMENTALRESULT
XB , P
1
1 1
XB , P
2
2 2
XB , P
J
J J
rB , P
r r
Rigorous methodology for uncertainty assessment using statistical and engineering concepts
TEP201 Fluid Mechanics 34
Dimensional analysis• Definition : Dimensional analysis is a process of formulating fluid mechanics problems in
in terms of non-dimensional variables and parameters.• Why is it used :
• Reduction in variables ( If F(A1, A2, … , An) = 0, then f(Π1, Π2, … Πr < n) = 0, where, F = functional form, Ai = dimensional variables, Πj = non-dimensionalparameters, m = number of important dimensions, n = number of dimensional variables, r= n – m ). Thereby the number of experiments required to determine f vs. F is reduced.
• Helps in understanding physics• Useful in data analysis and modeling• Enables scaling of different physical dimensions and fluid properties
Example
Vortex shedding behind cylinder
Drag = f(V, L, r, m, c, t, e, T, etc.)
From dimensional analysis,
Examples of dimensionless quantities : Reynolds number, FroudeNumber, Strouhal number, Euler number, etc.
TEP201 Fluid Mechanics 35
Similarity and model testing• Definition : Flow conditions for a model test are completely similar if all relevant dimensionless parameters have the same corresponding values for model and prototype.
• Πi model = Πi prototype i = 1• Enables extrapolation from model to full scale• However, complete similarity usually not possible. Therefore, often it is necessary to
use Re, or Fr, or Ma scaling, i.e., select most important Π and accommodate othersas best possible.
• Types of similarity: • Geometric Similarity : all body dimensions in all three coordinates have the same
linear-scale ratios.• Kinematic Similarity : homologous (same relative position) particles lie at homologous
points at homologous times.• Dynamic Similarity : in addition to the requirements for kinematic similarity the model
and prototype forces must be in a constant ratio.
TEP201 Fluid Mechanics 36
EFD process• “EFD process” is the steps to set up an experiment and
take data
1. Setup facility
2. Install model
3. Setup equipment
4. Setup Data Acquisition using LabView
5. Perform calibrations
6. Data Analysis and Data Reduction
7. Uncertainty Analysis
8. Comparison with CFD results
9. Documentation and Reporting
TEP201 Fluid Mechanics 37
EFD – “hands on” experience
Lab1: Measurement of kinematic viscosity of a fluid Lab2: Measurement of
flow rate, friction factor andvelocity profiles in smooth andrough pipes.
Lab3: Measurement of surface pressure distribution and lift coefficient for an airfoil
TEP201 Fluid Mechanics 38
Computational Fluid Dynamics• CFD is use of computational methods for
solving fluid engineering systems, including modeling (mathematical & Physics) and numerical methods (solvers, finite differences, and grid generations, etc.).
• Rapid growth in CFD technology since advent of computer
ENIAC 1, 1946 IBM WorkStation
TEP201 Fluid Mechanics 39
Purpose• The objective of CFD is to model the continuous fluids
with Partial Differential Equations (PDEs) and discretize PDEs into an algebra problem, solve it, validate it and achieve simulation based designinstead of “build & test”
• Simulation of physical fluid phenomena that are difficult to be measured by experiments: scale simulations (full-scale ships, airplanes), hazards (explosions,radiations,pollution), physics (weather prediction, planetary boundary layer, stellar evolution).
TEP201 Fluid Mechanics 40
Modeling• Mathematical physics problem formulation of fluid
engineering system• Governing equations: Navier-Stokes equations (momentum),
continuity equation, pressure Poisson equation, energy equation, ideal gas law, combustions (chemical reaction equation), multi-phase flows(e.g. Rayleigh equation), and turbulent models (RANS, LES, DES).
• Coordinates: Cartesian, cylindrical and spherical coordinates result in different form of governing equations
• Initial conditions(initial guess of the solution) and Boundary Conditions (no-slip wall, free-surface, zero-gradient, symmetry, velocity/pressure inlet/outlet)
• Flow conditions: Geometry approximation, domain, Reynolds Number, and Mach Number, etc.
TEP201 Fluid Mechanics 41
Modeling (examples)Free surface animation for ship in regular waves
Developing flame surface (Bell et al., 2001)
Evolution of a 2D mixing layer laden with particles of StokesNumber 0.3 with respect to the vortex time scale (C.Narayanan)
TEP201 Fluid Mechanics 42
Modeling (examples, cont’d)
3D vortex shedding behind a circular cylinder (Re=100,DNS,J.Dijkstra)
DES,Re=105, vorticitymagnitude of turbulent flow around NACA12 with angle of attack 60.
LES of a turbulent jet. Back wall shows a slice of the dissipation rate and the bottom wall shows a carpet plot of the mixture fraction in a slice through the jet centerline, Re=21,000 (D. Glaze).
TEP201 Fluid Mechanics 43
Numerical methods
• Finite difference methods: using numerical scheme to approximate the exact derivatives in the PDEs
• Grid generation: conformal mapping, algebraic methods and differential equation methods
• Solvers: direct methods (Cramer’s rule, Gauss elimination, LU decomposition) and iterative methods (Jacobi, Gauss-Seidel, SOR)
Slice of 3D mesh of a fighter aircraft
o x
y
i i+1i-1
j+1j
j-1
imax
jmax xΔ
yΔ2
1 12 2
2i i iP P PPx x
+ −− +∂=
∂ Δ2
1 12 2
2j j jP P PPy y
+ −− +∂=
∂ Δ
TEP201 Fluid Mechanics 44
CFD process• “CFD process” is the steps to set up a problem and
run the code1. Geometry: Create the geometry you want2. Physics: fluid properties, viscous modeling and
boundary conditions3. Mesh: coarse, medium and fine meshes4. Solve: different solvers and numerical
methods5. Report: time history of convergence of
variables6. Post-Processing: visualizations (contours,
vectors), validation and verification
TEP201 Fluid Mechanics 45
Commercial software• CFD software
1. FLUENT: http://www.fluent.com2. CFDRC: http://www.cfdrc.com3. STAR-CD:http://www.cd-adapco.com4. CFX/AEA: http://www.software.aeat.com/cfx
• Grid Generation software1. Gridgen: http://www.pointwise.com2. GridPro: http://www.gridpro.com
• Visualization software1. Tecplot: http://www.amtec.com2. Fieldview: http://www.ilight.com
TEP201 Fluid Mechanics 46
“Hands-on” experience using FlowLab 1.1 (pipe template)
TEP201 Fluid Mechanics 47
“Hands-on” experience using FlowLab 1.1 (airfoil template)
TEP201 Fluid Mechanics 48
57:020 Fluid Mechanics• Lectures cover basic concepts in fluid statics, kinematics,
and dynamics, control-volume, and differential-equation analysis methods. Homework assignments, tests, and complementary EFD/CFD labs
• EFD/CFD lab materials
Pre CFD lab2CFD lab2
Pre CFD lab1CFD lab1
NoneLab report instructionsCFDLecture
Pre EFD lab3EFD 3
Benchmark DataInstructions_UA
Pre EFD Lab2 EFD 2
Lab2_UAInstructions_UA
Pre EFD Lab1EFD 1
Lab 1_UAInstructions_UA
EFD UA ReportLab Report instructions
EFD Lecture
Lab 3: AirfoilLab 2: Pipe Flow
Lab 1: Viscosity
Other DocsLecture