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Heat Transfer
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EM52013 Heat Transfer
Department of Engineering Management
UNIVERSITAS INTERNASIONAL SEMEN INDONESIA
OKKY PUTRI PRASTUTI, S.T, M.T
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Course Details
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Course title : Heat Transfer Time slot : Monday, 12.35-15.20 Credit : 3 sks Instructor : Okky Putri Prastuti, S.T, M.T Telephone : +6281332546469 E-mail : [email protected] Course books : 1. Incropera, Frank P. Dewitt, David P, 1996. Intorduction to Heat Transfer. 3rd Edition,
John Willey & Sons. 2. Geankoplis,C.J., Transport Processes and Separation Process Principles, Prentice Hall
International Inc., 4th Ed, 2003
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TOPICS
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1. The concept of heat transfer (conduction, convection, radiation) 2. Analysis conduction 3. Forced Convection and Natural Convection 4. Heat exchangers 5. The concept of radiation and mass transfer
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Outline of Learning
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Week Subjects
1 Thermodynamic and Heat Transfer
2-3 Conduction Heat Transfer
4-5 Conduction and convection system
6 Steady state conduction for multi dimensional
7 Convenction Heat Transfer
8 UTS
9 External forced convection
10 Internal forced convection
11 Natural convection heat tansfer
12 Boiling and condensation
13-14 Heat exchanger
15 Radiation Heat Transfer
16 UAS
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Assessment
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Tugas : 15 % Kuis 1 : 15 % UTS : 20 % Kuis 2 : 15 % UAS : 30 % Keaktifan : 5 %
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Introduction of Thermodynamics
Heat Transfer t
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Definition
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Thermodynamics : The science of energy
The name thermodynamics stems from the Greek words therme
(heat) and dynamics (motion)
Thermodynamics is the study of energy conversion between heat and mechanical work, and subsequently the macroscopic variables such as temperature, volume, and pressure.
THERMO : HEAT and TEMPERATURE DYNAMICS : MOTION
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Example
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The production of chemicals, polymers, pharmaceuticals and other biological materials, and oil and gas processing, all involve chemical or biochemical reaction that produce a mixture of reaction product. (e.g : production of tert-butanol) 1. These must be separated from the mixture and purified to result in product of
societal, commercial, or medicinal value. 2. These is the area where thermodynamics plays a central role in process eng. 3. Separation processes, e.g. distillation are designed based on information from
thermodynamics such as vapor-liquid equilibrium data.
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Example (cont.)
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Vapor-Liquid
Equilibrium
(VLE) data
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Dimensions and Units
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- Dimension is recognize through our sensory perceptions and not
definable without the definition of arbitrary scales of measure,
divided into specific units of size.
The units have been set by international
agreement, and are
codified as the International System of Units (SI).
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Dimensions and Units (cont) t
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Dimensions and Units in HYSYS v3.2
American Engineering Units (Field)
SI units
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Measurements of Amount and Size
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Three measures of amount or size are in common use: Mass, m ; Number of moles, n ; Total volume, Vt
Mass, m divided by the molar mass M (molecular weight) to yield number of moles;
,M
mn Mnm
Total volume, divided by the mass or number of moles of the system to yield specific or molar volume.
Specific volume:
Molar Volume:
mVV t m
VV
t
or
nVV t n
VV
t
or
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Measurements of Amount and Size (cont)
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Properties in HYSYS
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Force
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21
c
2
c
s f kg m kg .80665 9 g
ms 9.80665 x kg 1 x g
1 kgf 1
* Note : The kilogram force is equivalent to 9.80665 N
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Temperature
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All temperature scales are based on some easily reproducible states such as the freezing and boiling points of water: the ice point and the steam point.
Ice point: A mixture of ice and water that is in equilibrium with air saturated with vapor at 1 atm pressure (0C or 32F).
Steam point: A mixture of liquid water and water vapor (with no air) in equilibrium at 1 atm pressure (100C or 212F).
Celsius scale: in SI unit system Fahrenheit scale: in English unit system Thermodynamic temperature scale: A temperature scale that is independent of the properties of any substance. Kelvin scale (SI) Rankine scale (E) A temperature scale nearly identical to the Kelvin scale is the ideal-gas temperature scale. The temperatures on
this scale are measured using a constant-volume gas thermometer.
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Temperature (cont.)
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Pressure
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Pressure: A normal force exerted by a fluid per unit area
ghA
gAh
A
mg
A
FP
A
mg
A
FP
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Pressure (cont.)
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Absolute pressure: The actual pressure at a given position. It is measured relative to absolute vacuum (i.e., absolute zero pressure).
Gage pressure: The difference between the absolute pressure and the local atmospheric pressure. Most pressure-measuring devices are calibrated to read zero in the atmosphere, and so they indicate gage pressure.
Vacuum pressures: Pressures below atmospheric pressure
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Energy
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Work (W)
Heat (Q)
Kinetic Energy (Ek)
Potential Energy (Ep)
Internal Energy (U)
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Work (W)
FdldW
Kerja diikuti oleh perubahan volume dari fluida (ex. Compression of a gas
by a piston)
2
1
2
1
V
V
V
V
t
t
PdVW
PdVW
A
VPAddW
t
t Total volume gives total work
Work per unit mass or mole
W+ Tanda negatif menunjukkan bahwa kompresi fluida
didifinisikan sebagai kerja positif
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Heat (Q)
heatQ
-Heat moves from object with higher T to object with lower T
-Temperature difference is driving force of heat flow
W & Q are path variables
Path variables only have meaning when exchange between a
system/substance and surroundings
A substance does not contain a certain amount of work or heat
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2
2
1muEK
We will focus on 5 forms of energy
Potential Energy(Ep)
mgzEp
Internal Energy(U)
forcesular intermolec karenaenergy internal U
Question:
what is the relationship between the various forms of energy?
Kinetic Energy(Ek)
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Hukum Pertama Termodinamika
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Panas yang diberikan pada suatu sistem (Q) sama dengan perubahan energi dalam (U) dan kerja yang dilakukan (W).
Hukum termodinamika I secara matematis dirumuskan:
di mana: Q = + panas masuk ke sistem
- panas keluar dari sistem
U = energi internal sistem
W = + usaha dilakukan oleh sistem
- usaha dilakukan pada sistem
WQU
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Hukum I
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Jumlah energi total konstan
Ek, Ep,
U
Q W
-E(lingkungan)
E(sistem)
E(sistem) + E(lingkungan) = 0
0 WQEpEkUsistem
WQEEkU P
+
Formulasi matematis HK I
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Eksoterm Proses pelepasan energi atau transfer kalor dari sistem ke lingkungan.
Endoterm Proses penyerapan
energi atau transfer kalor dari lingkungan ke
sistem.
Ditandai dengan kenaikan temperatur sistem saat
reaksi berlangsung. Contoh: reaksi pembakaran
Ditandai dengan penurunan temperatur sistem.
Contoh: proses fotosintesis
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proses-proses termodinamika
Proses Isobarik (1)
o Tekanan konstan
Proses Isotermis (2)
o Temperatur kontan
Proses Adiabatik (3)
o Tidak ada kalor yang hilang
Proses Isokorik (4)
o Volume konstan
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proses adiabatik Tidak terjadi transfer panas selama proses, sehingga Q = 0 Proses adiabatik dapat terjadi pada sistem yang terisolasi atau
sistem yang mempunyai proses sangat cepat.
U = Q W = 0
o Untuk sistem yang mengalami kompresi secara adiabatik, maka W negatif (kerja dilakukan pada sistem) sehingga U positif.
o Untuk sistem yang mengalami ekspansi secara adiabatik, maka
W positif (kerja dilakukan oleh sistem) sehingga U negatif.
U = - W
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proses isotermal Temperatur sistem konstan selama proses berlangsung.
Untuk gas ideal, jika T = 0 (temperatur gas konstan), maka U = 0.
Sehingga:
A
B
0TRnU2
3 WQ
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proses isobarik
Tidak terjadi perubahan tekanan pada sistem selama proses.
Umumnya terjadi pada sistem yang mempunyai kontak langsung dengan tekanan atmosfer bumi.
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proses isokhorik Tidak terjadi perubahan volume selama proses.
Proses ini juga disebut volume konstan, isometrik, isovolumik.
Proses ini terjadi pada sistem yang tertutup rapat dan kuat.
Ketika volume sistem tidak berubah, maka tidak ada kerja yang dilakukan, sehingga: W = 0 U = Q
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kapasitas kalor (heat capacity)
Kapasitas kalor (Q) adalah jumlah kalor yang diperlukan untuk menaikkan temperatur suatu zat 1oC.
Q = mcT di mana c adalah kalor spesifik (J/kg.K).
Untuk gas ideal:
Kapasitas kalor pada volume konstan
CV = 3/2 R
Kapasitas kalor pada tekanan konstan
CP = 5/2 R
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soal
Sebuah pemanas air menggunakan listrik sebagai sumbernya digunakan untuk memanaskan 3 kg air pada 80oC. Usaha yang diberikan filamen pemanas 25 kJ sementara panas yang terbuang karena konduksi sebesar 15 kkal. Berapa perubahan energi internal sistem dan temperatur akhir ?
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jawaban
Panas terbuang 15 kkal = 62,7 kJ
Q = U + W
-62,7 kJ = U -25 kJ U = -37,7 kJ
T = 76,9oC
CkgCxkgkJ
kJT o
o01,3
3/18,4
7,37
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MESIN KALOR
H
C
H
CH
H
CHQ
Q1
Q
QQ
Q
WQQW
di mana = efisiensi mesin kalor
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MESIN PENDINGIN
1W
Q
W
WQ
W
QCOPQQW CCCCH
di mana COP = Coefficient of Performance mesin pendingin
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SIKLUS KARNOT
Kurva A (12): ekspansi isotermal pada TH (kerja dilakukan oleh gas)
Kurva B (23): ekspansi adiabatik (kerja dilakukan oleh gas)
Kurva C (34): kompresi isotermal pada TC (kerja dilakukan pada gas)
Kurva D (41): kompresi adiabatik (kerja dilakukan pada gas)
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Heat Transfer
Heat Transfer t
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Proses Perpindahan
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Membahas dasar-dasar proses perpindahan momentum, panas dan massa yang terdapat dalam industri dan kehidupan sehari-hari. Konsep-konsep dasar akan dijelaskan melalui aplikasinya dalam penyelesaian soal-soal.
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MEKANISME PROSES PERPINDAHAN
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RESISTANCE
FORCEDRIVINGRATE
kA
dxRESISTANCE
TdFORCEDRIVING
)/( ADdx
dCJ
A
AA
dx
dCD
A
J AA
x
A
)/(kAdx
dTq
dx
dV
A
F yxy
dx
dTk
A
q
x
RATE LAW GENERAL RATE LAW
HEAT TRANSFER :
MASS TRANSFER
MOMENTUM TRANSFER
V
Diam
FOURIER LAW
FICKS LAW
NEWTON
LAW OF
VISCOSITY
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MEKANISME PROSES PERPINDAHAN (cont)
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BENTUK ANALOG PERSAMAAN FLUKS SATU DIMENSI
xx
x
xA
q
x
A
A
J
xy
Cp
k
x
x
CpT
x
CA
x
Vy
DA
Fluks Diffusivity Gradien konsentrasi
Properti
Umum
Panas
Massa
Momentum
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Heat Transport
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Perpindahan panas terjadi di berbagai proses (Operasi) misalnya :
Distilasi
Pembakaran bahan bakar
Penguapan & Pengeringan
Pemanasan & Pendinginan
Perpindahan panas terjadi karena adanya beda suhu (dari suhu tinggi ke suhu rendah)
Mekanisme Perpindahan Panas
Panas bisa berpindah dengan mekanisme : Konduksi
Konveksi dan Turbulensi
Radiasi
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Heat Transport (cont)
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Konduksi
Panas berpindah dengan transfer energy gerak molekul-molekul yang berdekatan.
Perpindahan panas secara konduksi bisa terjadi dalam solid, liquid, gas.
Dalam gas, molekul-molekul yang panas yang mempunyai energy gerak, menularkan energynya ke molekul-molekul yang
berdampingan.
Konduksi panas dapat juga ditransfer oleh elektron bebas (misalnya dalam logam).
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Heat Transport (cont)
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Konveksi
Perpindahan panas oleh bulk transport dan percampuran elemen-elemen makroskopis bagian-bagian yang lebih panas dengan bagian yang lebih dingin,
atau bisa juga pertukaran panas antara permukaan solid dan fluida.
Perlu dibedakan : Konveksi paksa Konveksi natural
Contoh : Kehilangan panas dari radiator mobil dimana udara disirkulasikan dengan
kipas.
Mendinginkan kopi dengan meniup.
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Heat Transport (cont)
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Radiasi
Perpindahan panas oleh gelombang elektron maknit. Radiasi tak perlu
medium.
Contoh: -Transfer Panas dari matahari ke bumi.
-Memanaskan (memasak) makanan di dalam oven.
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HUKUM KEKEKALAN
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Laju panas masuk + Laju generasi panas = Laju panas keluar + Laju akumulasi panas
dx
dTk
A
q
x
FOURIER LAW
In = qx|x Out = qx|x + x
x X + x x
| + . = |+ +
(.
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FOURIER LAW
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dx
dTk
A
q
x
Dimana : qx : laju transfer panas pada arah x (W)/(Btu/h)
A : luas penampang (m2)/(ft2)
T : suhu (K)/(0F)
x : jarak (m)/(ft)
k : konduktifitas panas (W/m.K)/(Btu/h)
1 btu/h.ft.0F = 4.1365 x 10-3 cal/s.cm.0C 1 btu/h.ft.0F = 1.73073 W/m.K 1 btu/h.ft2 = 3.1546 W/m2
1 btu/h = 0.29307 W
=
2
1
2
1
=
2 1 (1 2)
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PROBLEMS
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1. Calculate the heat loss per m2 of surface area for an insulating wall composed of 25.4 mm thick fiber insulating board, where the inside temperature is 352.7 K and the outside temperature is 297.1 K.
2. Calculate the heat loss per m2 of surface area for a temporary insulating wall of a food cold storage room where the outside temperature is 299 K and the inside temperature is 276.5 K. The wall composed of 25.4 mm of corkboard having a k of 0.0433 W/m.k
3. In determining thermal conductivity of insulating material, the temperatures were measured on both sides of a flat slab of 25 mm of the material and were 318.4 and 303.2 K. The heat flux was measured as 35.1 W/m2. Calculate the thermal conductivity in btu/h.ft.F and W/m.K.
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THANK YOU
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