05166-NTME239006-A-20AB-20242

About the course

Tahun Akademik:
Genap 2024/2025
Kelas-Offr:
A-20AB
Deskripsi:
Matakuliah Dinamika Transport (NTMEUM9088) mempelajari fenomena perpindahan, dinamika perpindahan, dan aplikasi transport momentum, energi dan massa pada aliran laminar dan turbulen serta kasus-kasus yang berkaitan dengan rekayasa keteknikan. Dalam matakuliah ini akan dibahas tentang materi Fenomena perpindahan, vector dan tensor; Konsep dasar viskositas pada cairan dan gas, serta hukum Newton tentang viskositas; Viskositas pada cairan murni, suspense dan emulsi; Perpindahan momentum konvektif, kesetimbangan momentum dan kondisi batas; Aliran pada dua cairan tak tercampurkan (immisible liquid); Persamaan pada kondisi Isotermal: Persamaan kontinuitas; Persamaan perubahan momentum (equation of change); Distribusi kecepatan pada aliran turbulen; Distribusi kecepatan pada fluida non-Newtonian; Difusivitas dan mekanisme transport massa; Distribusi konsentrasi padatan dalam aliran laminar; Persamaan perubahan untuk sistem multi-komponen; Transport momentum, energi dan massa dalam aliran laminar; Transport momentum, energi dan massa dalam aliran turbulen.
Capaian Pembelajaran

mengaplikasikan fenomena perpindahan dan teori viskositas.
mengidentifikasi perpindahan momentum, persamaan kontinuitas dan perubahan momentum.
mengaplikasikan distribusi kecepatan pada aliran turbulen dan fluida non-Newtonian.
mengidentifikasi teori difusivitas, distribusi konsentrasi dan persamaan perubahan sistem multi komponen.
mengaplikasikan transport momentum, energi dan massa pada aliran laminar dan turbulen.

Daftar Pustaka:

Barr, D.I.H., “Solutions of the Colebrook-White functions for resistance to uniform turbulent flows.”, Proc. Inst. Civil. Engrs. Part 2. 71,1981.
Churchill, S.W., “Friction factor equations spans all fluid-flow ranges.”, Chem.Eng., 91,1977.
Colebrook, C.F. and White, C.M., “Experiments with Fluid friction roughened pipes.”, Proc. R.Soc.(A), 161,1937.
Haaland, S.E., “Simple and Explicit formulas for friction factor in turbulent pipe flow.”, Trans. ASME, JFE, 105, 1983.
Liou, C.P., “Limiations and proper use of the Hazen-Williams equations.”, J.Hydr., Eng., 124(9), 951-954, 1998. Manadilli, G., “Replace implicit equations with sigmoidal functions.”,Chem.Eng. Journal, 104(8), 1997.McKeon, B.J., Swanson, C.J., Zagarola, M.V., Donnelly, R.J. and Smits, A.J.,
Incropere F. P., De Witt D.,Fundamentals of Heat and Mass Transfer, Third EfitionWilley publication 1990
Churchill, S.W. and H.H.S. Chu, Correlating Equations for Laminar and Turbulent Free Convection from a vertical plate, Int. J. Heat Mass Transfer, 18, 1323, 1975
Morgan, V. T. The Overall Convective Heat Transfer from Smooth Circular Cylinders, in T.F.
Irvine and J.P. Harnett, Eds., Advances in Heat Transfer Vol 11, Academic Press, New York, 1975, pp. 199-264
Mikhailov, M.D., Özisik, M. N., Unified analysis and solutions of heat and mass diffusion, Dover publications,1984, ISBN 0-486-67876-8
Özisik, Necati, Heat Conduction, Second edition, John Wiley and Sons, Inc. ISBN 0-471-53256
Özisik, Necati, Heat transfer, a basic approach, Mc Graw Hill Book Company, ISBN 0-07-0479828

Course content

Sections: 17

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Activities: 17

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Resources: 2

Announcements

RPS Dinamika Transport
Introduction
Attendance 1

Attendance 2

Attendance 3

Attendance 4

Attendance 5

Attendance 6

Attendance 7

Attendance 8

Attendance 9

Attendance 10

Attendance 11

Attendance 12

Attendance 13

Attendance 14

Attendance 15

Attendance 16

Enrolment options

Dinamika Transport 05166-NTME239006-A-20AB-20242

mengaplikasikan fenomena perpindahan dan teori viskositas.
mengidentifikasi perpindahan momentum, persamaan kontinuitas dan perubahan momentum.
mengaplikasikan distribusi kecepatan pada aliran turbulen dan fluida non-Newtonian.
mengidentifikasi teori difusivitas, distribusi konsentrasi dan persamaan perubahan sistem multi komponen.
mengaplikasikan transport momentum, energi dan massa pada aliran laminar dan turbulen.

Daftar Pustaka:

Barr, D.I.H., “Solutions of the Colebrook-White functions for resistance to uniform turbulent flows.”, Proc. Inst. Civil. Engrs. Part 2. 71,1981.
Churchill, S.W., “Friction factor equations spans all fluid-flow ranges.”, Chem.Eng., 91,1977.
Colebrook, C.F. and White, C.M., “Experiments with Fluid friction roughened pipes.”, Proc. R.Soc.(A), 161,1937.
Haaland, S.E., “Simple and Explicit formulas for friction factor in turbulent pipe flow.”, Trans. ASME, JFE, 105, 1983.
Liou, C.P., “Limiations and proper use of the Hazen-Williams equations.”, J.Hydr., Eng., 124(9), 951-954, 1998. Manadilli, G., “Replace implicit equations with sigmoidal functions.”,Chem.Eng. Journal, 104(8), 1997.McKeon, B.J., Swanson, C.J., Zagarola, M.V., Donnelly, R.J. and Smits, A.J.,
Incropere F. P., De Witt D.,Fundamentals of Heat and Mass Transfer, Third EfitionWilley publication 1990
Churchill, S.W. and H.H.S. Chu, Correlating Equations for Laminar and Turbulent Free Convection from a vertical plate, Int. J. Heat Mass Transfer, 18, 1323, 1975
Morgan, V. T. The Overall Convective Heat Transfer from Smooth Circular Cylinders, in T.F.
Irvine and J.P. Harnett, Eds., Advances in Heat Transfer Vol 11, Academic Press, New York, 1975, pp. 199-264
Mikhailov, M.D., Özisik, M. N., Unified analysis and solutions of heat and mass diffusion, Dover publications,1984, ISBN 0-486-67876-8
Özisik, Necati, Heat Conduction, Second edition, John Wiley and Sons, Inc. ISBN 0-471-53256
Özisik, Necati, Heat transfer, a basic approach, Mc Graw Hill Book Company, ISBN 0-07-0479828

Teacher: Retno Wulandari Dr., S.T., M.T.
Enrolled students: 4

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Dinamika Transport

About the course

Course content

Instructors

Retno Wulandari Dr., S.T., M.T.

Enrolment options

Dinamika Transport 05166-NTME239006-A-20AB-20242

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