Heat Conduction in semi-infinite Slab

Similar documents
Unsteady State Heat Conduction in a Bounded Solid How Does a Solid Sphere Cool?

Chapter 3: Transient Heat Conduction

Chapter 5 Time-Dependent Conduction

Heat Transfer in a Slab

MECH 375, Heat Transfer Handout #5: Unsteady Conduction

3.3 Unsteady State Heat Conduction

Solution of Partial Differential Equations

Heat and Mass Transfer Effects on Flow past an Oscillating Infinite Vertical Plate with Variable Temperature through Porous Media

Chapter 4: Transient Heat Conduction. Dr Ali Jawarneh Department of Mechanical Engineering Hashemite University

Partial differentiation. Background mathematics review

Consider a volume Ω enclosing a mass M and bounded by a surface δω. d dt. q n ds. The Work done by the body on the surroundings is.

Theories for Mass Transfer Coefficients

Correspondence should be addressed to S. M. Abo-Dahab,

Introduction to Heat and Mass Transfer. Week 8

Introduction to Heat and Mass Transfer. Week 8

PROBLEM SET 6. E [w] = 1 2 D. is the smallest for w = u, where u is the solution of the Neumann problem. u = 0 in D u = h (x) on D,

QUESTION ANSWER. . e. Fourier number:

Method of Images

Math 1B Calculus Test 3 Spring 10 Name Write all responses on separate paper. Show your work for credit.

ANALYTICAL SOLUTIONS OF HEAT CONDUCTION PROBLEMS A THESIS SUBMITTED IN PARTIAL FULFILMENT OF THE REQUIREMENTS FOR THE DEGREE OF

One dimensional steady state diffusion, with and without source. Effective transfer coefficients

UNSTEADY LOW REYNOLDS NUMBER FLOW PAST TWO ROTATING CIRCULAR CYLINDERS BY A VORTEX METHOD

Introduction to Differential Equations

Module 1 : The equation of continuity. Lecture 4: Fourier s Law of Heat Conduction

Introduction to Partial Differential Equations

MHD Flow Past an Impulsively Started Vertical Plate with Variable Temperature and Mass Diffusion

Research Article Approximate Solution of the Nonlinear Heat Conduction Equation in a Semi-Infinite Domain

International Journal of Scientific Research and Reviews

1 Constant Pressure Inner Boundary Condition

CHAPTER 3 Introduction to Fluids in Motion

Phys 122 Lecture 3 G. Rybka

1 R-value = 1 h ft2 F. = m2 K btu. W 1 kw = tons of refrigeration. solar = 1370 W/m2 solar temperature

4. Analysis of heat conduction

[Yadav*, 4.(5): May, 2015] ISSN: (I2OR), Publication Impact Factor: (ISRA), Journal Impact Factor: 2.114

5.6. Differential equations

Elementary Non-Steady Phenomena

Parallel Plate Heat Exchanger

UNSTEADY FREE CONVECTION BOUNDARY-LAYER FLOW PAST AN IMPULSIVELY STARTED VERTICAL SURFACE WITH NEWTONIAN HEATING

2: Distributions of Several Variables, Error Propagation

Introduction to Heat and Mass Transfer. Week 7

Steady and unsteady diffusion

2 Law of conservation of energy

First Order Equations

Lecture notes for , Theoretical Environmental Analysis. D. H. Rothman, MIT February 4, 2015

MHD FLOW PAST AN IMPULSIVELY STARTED INFINITE VERTICAL PLATE IN PRESENCE OF THERMAL RADIATION

Exam in Fluid Mechanics SG2214

Entropy ISSN

lim = F F = F x x + F y y + F z

MATURITY EFFECTS IN CONCRETE DAMS

Introduction to Partial Differential Equation - I. Quick overview

Unsteady free MHD convection flow past a vertical porous plate in slip-flow regime under fluctuating thermal and mass diffusion *

SET-I SECTION A SECTION B. General Instructions. Time : 3 hours Max. Marks : 100

Chemical diffusion in a cuboidal cell

Accelerator Physics Statistical and Beam-Beam Effects. G. A. Krafft Old Dominion University Jefferson Lab Lecture 14

Data Analysis and Heat Transfer in Nanoliquid Thin Film Flow over an Unsteady Stretching Sheet

Jim Lambers ENERGY 281 Spring Quarter Lecture 3 Notes

ECE 695 Numerical Simulations Lecture 12: Thermomechanical FEM. Prof. Peter Bermel February 6, 2017

The purpose of this lecture is to present a few applications of conformal mappings in problems which arise in physics and engineering.

Simulation of Acoustic and Vibro-Acoustic Problems in LS-DYNA using Boundary Element Method

HEAT AND MASS TRANSFER OF UNSTEADY MHD FLOW OF KUVSHINSKI FLUID WITH HEAT SOURCE/SINK AND SORET EFFECTS

Multivariable Calculus Lecture #13 Notes. in each piece. Then the mass mk. 0 σ = σ = σ

Chapter 22. Dr. Armen Kocharian. Gauss s Law Lecture 4

SOE3213/4: CFD Lecture 3

AE/ME 339. K. M. Isaac Professor of Aerospace Engineering. December 21, 2001 topic13_grid_generation 1

Boundary value problems

Linear Algebra and Dirac Notation, Pt. 1

Magnetic Field and Chemical Reaction Effects on Convective Flow of

4. DIFFUSION AND MASS TRANSFER

Thermal Conduction in Permafrost

INTEGRATION WORKSHOP 2004 COMPLEX ANALYSIS EXERCISES

Math 4381 / 6378 Symmetry Analysis

Harmonic functions, Poisson kernels

CHAPTER 4 BOUNDARY LAYER FLOW APPLICATION TO EXTERNAL FLOW

CONSERVATION OF ENERGY FOR ACONTINUUM

the first derivative with respect to time is obtained by carefully applying the chain rule ( surf init ) T Tinit

Oscillatory heating in a microchannel at arbitrary oscillation frequency in the whole range of the Knudsen number

IV. Transport Phenomena Lecture 18: Forced Convection in Fuel Cells II

Outline Lecture 2 2(32)

I&C 6N. Computational Linear Algebra

Lesson 9: Multiplying Media (Reactors)

On the Effect of the Boundary Conditions and the Collision Model on Rarefied Gas Flows

Thermal Analysis Contents - 1

15. Polarization. Linear, circular, and elliptical polarization. Mathematics of polarization. Uniaxial crystals. Birefringence.

- 1 - θ 1. n 1. θ 2. mirror. object. image

Apply mass and momentum conservation to a differential control volume. Simple classical solutions of NS equations

CHAPTER 2: Partial Derivatives. 2.2 Increments and Differential

5.3.3 The general solution for plane waves incident on a layered halfspace. The general solution to the Helmholz equation in rectangular coordinates

f(x)e ikx dx. (1) f(k)e ikx dk. (2) e ikx dx = 2sinak. k f g(x) = g f(x) = f(s)e iks ds

Horizontal buoyancy-driven flow along a differentially cooled underlying surface

Lecture 16 : Fully Developed Pipe flow with Constant Wall temperature and Heat Flux

FACULTY OF MATHEMATICAL STUDIES MATHEMATICS FOR PART I ENGINEERING. Lectures AB = BA = I,

2.6 Oseen s improvement for slow flow past a cylinder

3.6 Applications of Poisson s equation

. Then Φ is a diffeomorphism from (0, ) onto (0, 1)

PhysicsAndMathsTutor.com

Numerical Solution of Mass Transfer Effects on Unsteady Flow Past an Accelerated Vertical Porous Plate with Suction

FRW cosmology: an application of Einstein s equations to universe. 1. The metric of a FRW cosmology is given by (without proof)

Chapter 16 Mechanical Waves

Review of Probability

THE VORTEX PANEL METHOD

Transcription:

1 Module : Diffusive heat and mass transfer Lecture 11: Heat Conduction in semi-infinite Slab with Constant wall Temperature

Semi-infinite Solid Semi-infinite solids can be visualized as ver thick walls with one side exposed to some fluid. The other side, since the wall is ver thick remains unaffected b the fluid temperature. The condition applicable can be expressed as T, t T, where T 0 is the initial wall temperature At ( ) 0 Fig. 11.1 Heat transfer in Semi-infinite solids The condition at the exposed side of the wall is called the boundar condition Unstead-state Heat Transfer Consider a heat conduction in -direction in a semi-infinite slab (bounded onl b one face) initiall at a temperature T 0, whose face suddenl at time equal to zero is raised to and maintained at T 1. Assuming constant thermal diffusivit and with no heat generation, a differential equation in one space dimension and time is given b θ θ α, where α is the thermal diffusivit (11.1) t with the following I.C and B.Cs

3 At t 0 At 0 At θ 0 θ 1 θ 0 for all for all t for all t > 0 > 0 (11.) An example is heating of a semi-infinite slab, initiall at temperature T 0. The slab surface temperature is raised suddenl to T 1 and maintained at that level for all t>0. For this situation, ( ) T TO k we have considered dimensionless parameter, θ in equation (11.1), and α is ( T1 TO ) ρc p the thermal diffusivit. Solution: One wa to solve this problem is b Combination of Variables Assume θ a t b (11.3) where a and b are constants Differentiating equation (11.3) w.r.t t we get θ t a b t ( b 1) (11.4) Also on differentiating w.r.t we get θ t b a (a -1) ( a-) (11.5) Substituting equation (11.4) and (11.5) into (11.1) we get ( b 1) a b t α ( a-) b t a (a -1) (11.6)

4 After some algebraic manipulations, we get α t a ( a 1) b constant Hence the new variable can be an of the form t C α d where C and d are constants Define η (11.7) 4α t 1 1 (Here we choosec and d ) 4 Then θ θ (, t) θ ( η) Differentiating θ (eqn. (11.7)) w.r.t. t we get θ t t 4α t dθ dη (11.8) Also differentiating θ w.r.t. we get θ 1 α t d θ dη (11.10) Substituting eqn. (11.8) and (11.10) into eqn. (11.1) then leads to a second-order ordinar differential equation of the form

5 θ dθ + η 0 (11.11) η dη On solving equation (11.11) we get η 0 θ B + A η dη (11.1) e Note For the method of combination of variables to work, the boundar conditions must be expressible in terms of η onl. This method is usuall applied for media of infinite or semiinfinite extend. Boundar Conditions At η 0 θ 1 and At η θ 0 Appling above B.Cs. to equation (11.1) we get η η θ 1 e dη (11.13) π 0 Note

6 In mathematics, the error function also called as Gauss error function is a special function (non-elementar) of sigmoid shape which generall occurs in problems related to probabilit, statistics, materials science and partial differential equations. It can be defined as ( ) x t erf x e dt π 0 The complimentar error function denoted b erfc, is defined in terms of the error function: ( ) 1 ( ) erfc x erf x π x e t dt Some useful results of error functions are given below. ( 0) 0, ( ) 1, ( ) ( ) erf erf erf x erf x So utilizing the results given for error function, we can write θ 1 erf 4α t or θ 1 erf( η) (11.14) Fig.(11.3) shows the variation of the surface temperature along the length of the slab with time. Diffusion length

7 Diffusion length can be defined as a measure of how far the temperature (or concentration) has propagated in the -direction b diffusion in time t. It can be given as δ 4 α t at this value, the value of η is η 4α t Therefore from equation (11.13) we can write ( ) 1 0.9953 0. 004678 θ 1 erf This implies that, at a distancel > δ, the field variables has changed b < 0.5%. Solution (11.14) is a good approximation even for finite length slabs if the diffusion length δ << L. The heat flux can be obtained as T ( q) k ( T ) 0 1 To 0 k παt (11.15)

8 Fig.11. Error function From the above solution to the problem on semi-infinite slab we can conclude that the diffusion length (or penetration depth) varies as square root of time (t 1/ ) and the wall flux varies as inverse of as square root of time (t -1/ ). Solution b the method of Laplace Transform Definition Let f(z) be an function, then the Laplace transform of f(z) can be given b 0 pt { ( z) } f ( p) e f ( t) f dt (11.16) Some of the standard Laplace results are shown below:

9 () f ( ) if f t 1, then after taking Laplace transform, p 1 p In this wa f at () t e f ( p) 1 ( p - a) f () t sin( wt) f ( p) w ( p + w ) Problem Consider a diffusion of component A in the -direction in a semi-infinite (bounded onl b one face) slab initiall at a uniform concentration, C 0, whose face suddenl at time equal to zero is raised to and maintained at C. The governing differential equation is given b C t C D, D is the binar diffusivit (11.17) with following I.C. and B.Cs. C C C 0 O C 0 at at at 0, > 0,, t > 0 t 0 t 0 (11.18) The Laplace transform of equation (11.17) ields

10 C D pc C (,0) (11.19) Using I.C. given in equation (11.18), equation (11.19) becomes C D pc (11.0) Appling B.Cs, so C C p C 0 O at as 0 and; Therefore the solution for equation (11.0) is C p O D C e (11.1) p Taking the inverse Laplace transform of equation (11.1) and from the table of Laplace transform C Co 1 erf (11.) 4D t

11 Fig.11.3 Temperature variation along the length at different time period

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback