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9783540334705

Solving Direct And Inverse Heat Conduction Problems

by ;
  • ISBN13:

    9783540334705

  • ISBN10:

    354033470X

  • Format: Hardcover
  • Copyright: 2006-11-10
  • Publisher: Springer Verlag
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Summary

The book presents a solution for direct and inverse heat conduction problems. In the first part, the authors discuss the theoretical basis for the heat transfer process. In the second part, they present selected theoretical and numerical problems in the form of exercises with their subsequent solutions. Such layout of the book will allow the reader to become more familiar with step-by-step calculation methods and with the practical application of the equations to the solution of design and utilization problems of thermal machinery. It will also help to master complex mathematics behind the heat transfer theory. The book covers one-, two- and three dimensional problems which are solved by using exact and approximate analytical methods and numerical methods such as: the finite difference method, the finite volume method, the finite element method and the boundary method. Unlike other books on the subject, the superposition method is thoroughly presented. Particular attention is paid to the solution of inverse heat conduction problems. The authors took special care that the solved inverse problems can be implemented in indirect measurements of boundary heat flux and heat transfer coefficient.

Author Biography

Professor Jan Taler is a director of the Department of Process and Power Engineering at the Faculty of Mechanical Engineering, Krakow University of Technology. He has lectures on heat transfer processes and thermal power plants at the Faculty of Mechanical Engineering and the Faculty of Computer and Electrical Engineering. His research interests mainly lie in heat transfer, inverse heat conduction problems and monitoring of thermal stresses, which arise during the operations of energy installations and machinery. The results of his research on heat transfer, thermal stresses, optimum heating and cooling of solids and measuring of heat flux were published in well-known international journals, such as Transactions of the ASME, International Journal of Heat and Mass Transfer, Heat and Mass Transfer, Forschung im Ingenieurwessen, Brennstoff-Warme-Kraft, VGB Kraftwerkstechnik and VGB Power Tech.Professor Taler was a research fellow of DAAD in Germany and of Alexander von Humboldt Foundation at the University of Stuttgart. He is also a member of the Committee of Combustion and Thermodynamics at the Polish Academy of Sciences. He is also the author of over 200 publications and 5 monographies, including three in German language. He has received Siemens Award for his achievements in scientific research, the Award of the Minister of Education and the Award of the Rector of the Krakow University of Technology.Dr. Piotr Duda is an associate professor at the Department of Process and Power Engineering of the Faculty of Mechanical Engineering, Krakow University of Technology. Between 1997-1998, he was a research fellow at the Swiss Federal Institute of Technology in Lausanne (EPFL). Between 2002-2003, he was a research fellow of the Alexander von Humboldt Foundation at the University of Stuttgart, Germany. He has published over 50 articles on heat transfer problems, thermal stresses and numerical methods both at home and abroad.

Table of Contents

Part I Heat Conduction Fundamentals 1(50)
1 Fourier Law
3(4)
Literature
6(1)
2 Mass and Energy Balance Equations
7(22)
2.1 Mass Balance Equation for a Solid that Moves at an Assigned Velocity
7(2)
2.2 Inner Energy Balance Equation
9(7)
2.2.1 Energy Balance Equations in Three Basic Coordinate Systems
12(4)
2.3 Hyperbolic Heat Conduction Equation
16(1)
2.4 Initial and Boundary Conditions
17(9)
2.4.1 First Kind Boundary Conditions (Dirichlet Conditions)
18(1)
2.4.2 Second Kind Boundary Conditions (von Neumann Conditions)
18(1)
2.4.3 Third Kind Boundary Conditions
19(2)
2.4.4 Fourth Kind Boundary Conditions
21(1)
2.4.5 Non-Linear Boundary Conditions
22(2)
2.4.6 Boundary Conditions on the Phase Boundaries
24(2)
Literature
26(3)
3 The Reduction of Transient Heat Conduction Equations and Boundary Conditions
29(12)
3.1 Linearization of a Heat Conduction Equation
29(2)
3.2 Spatial Averaging of Temperature
31(8)
3.2.1 A Body Model with a Lumped Thermal Capacity
31(2)
3.2.2 Heat Conduction Equation for a Simple Fin with 'inform 'thickness
33(2)
3.2.3 Heat Conduction Equation for a Round Fin with Uniform Thickness
35(2)
3.2.4 Heat Conduction Equation for a Circular Rod or a Pipe that Moves at Constant Velocity
37(2)
Literature
39(2)
4 Substituting Heat Conduction Equation by Two-Equations System
41(6)
4.1 Steady-State Heat Conduction in a Circular Fin with Variable Thermal Conductivity and Transfer Coefficient
41(2)
4.2 One-Dimensional Inverse Transient Heat Conduction Problem
43(3)
Literature
46(1)
5 Variable Change
47(4)
Literature
50(1)
Part II Exercises. Solving Heat Conduction Problems 51(780)
6 Heat Transfer Fundamentals
53(88)
Exercise 6.1 Fourier Law in a Cylindrical Coordinate System
53(2)
Exercise 6.2 The Equivalent Heat Transfer Coefficient Accounting for Heat Exchange by Convection and Radiation
55(2)
Exercise 6.3 Heat Transfer Through a Flat Single-Layered and Double-Layered Wall
57(3)
Exercise 6.4 Overall Heat Transfer Coefficient and Heat Loss Through a Pipeline Wall
60(2)
Exercise 6.5 Critical Thickness of an Insulation on an Outer Surface of a Pipe
62(3)
Exercise 6.6 Radiant Tube Temperature
65(3)
Exercise 6.7 Quasi-Steady-State of Temperature Distribution and Stresses in a Pipeline Wall
68(2)
Exercise 6.8 Temperature Distribution in a Flat Wall with Constant and Temperature Dependent Thermal Conductivity
70(4)
Exercise 6.9 Determining Heat Flux on the Basis of Measured Temperature at Two Points Using a Flat and Cylindrical Sensor
74(3)
Exercise 6.10 Determining Heat Flux By Means of Gardon Sensor with a Temperature Dependent Thermal Conductivity
77(3)
Exercise 6.11 One-Dimensional Steady-State Plate Temperature Distribution Produced by Uniformly Distributed Volumetric Heat Sources
80(2)
Exercise 6.12 One-Dimensional Steady-State Pipe Temperature Distribution Produced by Uniformly Distributed Volumetric Heat Sources
82(3)
Exercise 6.13 Inverse Steady-State Heat Conduction Problem in a Pipe
85(2)
Exercise 6.14 General Equation of Heat Conduction in Fins
87(2)
Exercise 6.15 Temperature Distribution and Efficiency of a Straight Fin with Constant Thickness
89(3)
Exercise 6.16 Temperature Measurement Error Caused by Thermal Conduction Through Steel Casing that Contains a Thermoelement as a Measuring Device
92(3)
Exercise 6.17 Temperature Distribution and Efficiency of a Circular Fin of Constant Thickness
95(3)
Exercise 6.18 Approximated Calculation of a Circular Fin Efficiency
98(1)
Exercise 6.19 Calculating Efficiency of Square and Hexagonal Fins
99(3)
Exercise 6.20 Calculating Efficiency of Hexagonal Fins by Means of an Equivalent Circular Fin Method and Sector Method
102(6)
Exercise 6.21 Calculating Rectangular Fin Efficiency
108(1)
Exercise 6.22 Heat Transfer Coefficient in Exchangers with Extended Surfaces
109(5)
Exercise 6.23 Calculating Overall Heat Transfer Coefficient in a Fin Plate Exchanger
114(1)
Exercise 6.24 Overall Heat Transfer Coefficient for a Longitudinally Finned Pipe with a Scale Layer on an Inner Surface
115(4)
Exercise 6.25 Overall Heat Transfer Coefficient for a Longitudinally Finned Pipe
119(3)
Exercise 6.26 Determining One-Dimensional Temperature Distribution in a Flat Wall by Means of Finite Volume Method
122(5)
Exercise 6.27 Determining One-Dimensional Temperature Distribution in a Cylindrical Wall by Means of Finite Volume Method
127(4)
Exercise 6.28 Inverse Steady-State Heat Conduction Problem for a Pipe Solved by Space-Marching Method
131(3)
Exercise 6.29 Temperature Distribution and Efficiency of a Circular Fin with Temperature-Dependent Thermal Conductivity
134(4)
Literature
138(3)
7 Two-Dimensional Steady-State Heat Conduction. Analytical Solutions
141(20)
Exercise 7.1 Temperature Distribution in an Infinitely Long Fin with Constant Thickness
141(4)
Exercise 7.2 Temperature Distribution in a Straight Fin with Constant Thickness and Insulated Tip
145(3)
Exercise 7.3 Calculating Temperature Distribution and Heat Flux in a Straight Fin with Constant Thickness and Insulated Tip
148(8)
Exercise 7.4 Temperature Distribution in a Radiant Tube of a Boiler
156(4)
Literature
160(1)
8 Analytical Approximation Methods. Integral Heat Balance Method
161(10)
Exercise 8.1 Temperature Distribution within a Rectangular Cross-Section of a Bar
161(2)
Exercise 8.2 Temperature Distribution in an Infinitely Long Fin of Constant Thickness
163(2)
Exercise 8.3 Determining Temperature Distribution in a Boiler's Water-Wall Tube by Means of Functional Correction Method
165(4)
Literature
169(2)
9 Two-Dimensional Steady-State Heat Conduction. Graphical Method
171(12)
Exercise 9.1 Temperature Gradient and Surface-Transmitted Heat Flow
171(2)
Exercise 9.2 Orthogonality of Constant Temperature Line and Constant Heat Flux
173(3)
Exercise 9.3 Determining Heat Flow between Isothermal Surfaces
176(3)
Exercise 9.4 Determining Heat Loss Through a Chimney Wall; Combustion Channel (Chimney) with Square Cross-Section
179(2)
Exercise 9.5 Determining Heat Loss Through Chimney Wall with a Circular Cross-Section
181(1)
Literature
182(1)
10 Two-Dimensional Steady-State Problems. The Shape Coefficient
183(6)
Exercise 10.1 Buried Pipe-to-Ground Surface Heat Flow
183(2)
Exercise 10.2 Floor Heating
185(1)
Exercise 10.3 Temperature of a Radioactive Waste Container Buried Underground
186(1)
Literature
187(2)
11 Solving Steady-State Heat Conduction Problems by Means of Numerical Methods
189(120)
Exercise 11.1 Description of the Control Volume Method
189(5)
Exercise 11.2 Determining Temperature Distribution in a Square Cross-Section of a Long Rod by Means of the Finite Volume Method
194(5)
Exercise 11.3 A Two-Dimensional Inverse Steady-State Heat Conduction Problem
199(5)
Exercise 11.4 Gauss-Seidel Method and Over-Relaxation Method
204(4)
Exercise 11.5 Determining Two-Dimensional Temperature Distribution in a Straight Fin with Uniform Thickness by Means of the Finite Volume Method
208(7)
Exercise 11.6 Determining Two-Dimensional Temperature Distribution in a Square Cross-Section of a Chimney
215(6)
Exercise 11.7 Pseudo-Transient Determination of Steady-State Temperature Distribution in a Square Cross-Section of a Chimney; Heat Transfer by Convection and Radiation on an Outer Surface of a Chimney
221(9)
Exercise 11.8 Finite Element Method
230(4)
Exercise 11.9 Linear Functions That Interpolate Temperature Distribution (Shape Functions) Inside Triangular and Rectangular Elements
234(4)
Exercise 11.10 Description of FEM Based on Galerkin Method
238(7)
Exercise 11.11 Determining Conductivity Matrix for a Rectangular and Triangular Element
245(4)
Exercise 11.12 Determining Matrix [K&aLPHA;E in Terms of Convective Boundary Conditions for a Rectangular and Triangular Element
249(4)
Exercise 11.13 Determining Vector {fQe} with Respect to Volumetric and Point Heat Sources in a Rectangular and Triangular Element
253(3)
Exercise 11.14 Determining Vectors {fqe} and {fαe} with Respect to Boundary Conditions of 2nd and 3rd Kind on the Boundary of a Rectangular or Triangular Element
256(3)
Exercise 11.15 Methods for Building Global Equation System in FEM
259(5)
Exercise 11.16 Determining Temperature Distribution in a Square Cross-Section of an Infinitely Long Rod by Means of FEM, in which the Global Equation System is Constructed using Method I (from Ex. 11.15)
264(7)
Exercise 11.17 Determining Temperature Distribution in an Infinitely Long Rod with Square Cross-Section by Means of FEM, in which the Global Equation System is Constructed using Method II (from Ex. 11.15)
271(4)
Exercise 11.18 Determining Temperature Distribution by Means of FEM in an Infinitely Long Rod with Square Cross-Section, in which Volumetric Heat Sources Operate
275(10)
Exercise 11.19 Determining Two-Dimensional Temperature Distribution in a Straight Fin with Constant Thickness by Means of FEM
285(12)
Exercise 11.20 Determining Two-Dimensional Temperature Distribution by Means of I-EM in a Straight Fin with Constant Thickness (ANSYS Program)
297(3)
Exercise 11.21 Determining Two-Dimensional Temperature Distribution by Means of FEM in a Hexagonal Fin with Constant Thickness (ANSYS Program)
300(3)
Exercise 11.22 Determining Axisymmetrical Temperature Distribution in a Cylindrical and Conical Pin by Means of FEM (ANSYS program)
303(4)
Literature
307(2)
12 Finite Element Balance Method and Boundary Element Method
309(24)
Exercise 12.1 Finite Element Balance Method
309(5)
Exercise 12.2 Boundary Element Method.
314(9)
Exercise 12.3 Determining Temperature Distribution in Square Region by Means of FEM Balance Method
323(4)
Exercise 12.4 Determining Temperature Distribution in a Square Region Using Boundary Element Method
327(4)
Literature
331(2)
13 Transient Heat Exchange Between a Body with Lumped Thermal Capacity and Its Surroundings
333(20)
Exercise 13.1 Heat Exchange between a Body with Lumped Thermal Capacity and Its Surroundings
333(3)
Exercise 13.2 Heat Exchange between a Body with Lumped Thermal Capacity and Surroundings with Time-Dependent Temperature
336(3)
Exercise 13.3 Determining Temperature Distribution of a Body with Lumped Thermal Capacity, when the Temperature of a Medium Changes Periodically
339(1)
Exercise 13.4 Inverse Problem: Determining Temperature of a Medium on the Basis of Temporal Thermometer-Indicated Temperature History
340(2)
Exercise 13.5 Calculating Dynamic Temperature Measurement Error by Means of a Thermocouple
342(2)
Exercise 13.6 Determining the Time It Takes to Cool Body Down to a Given Temperature
344(1)
Exercise 13.7 Temperature Measurement Error of a Medium whose Temperature Changes at Constant Rate
345(1)
Exercise 13.8 Temperature Measurement Error of a Medium whose Temperature Changes Periodically
346(1)
Exercise 13.9 Inverse Problem: Calculating Temperature of a Medium whose Temperature Changes Periodically, on the Basis of Temporal Temperature History Indicated by a Thermometer
347(2)
Exercise 13.10 Measuring Heat Flux
349(2)
Literature
351(2)
14 Transient Heat Conduction in Half-Space
353(32)
Exercise 14.1 Laplace Transform
353(2)
Exercise 14.2 Formula Derivation for Temperature Distribution in a Half-Space with a Step Increase in Surface Temperature
355(3)
Exercise 14.3 Formula Derivation for Temperature Distribution in a Half-Space with a Step Increase in Heat Flux
358(2)
Exercise 14.4 Formula Derivation for Temperature Distribution in a Half-Space with a Step Increase in Temperature of a Medium
360(4)
Exercise 14.5 Formula Derivation for Temperature Distribution in a Half-Space when Surface Temperature is Time-Dependent
364(2)
Exercise 14.6 Formula Derivation for a Quasi-Steady State Temperature Field in a Half-Space when Surface Temperature Changes Periodically
366(8)
Exercise 14.7 Formula Derivation for Temperature of Two Contacting Semi-Infinite Bodies
374(1)
Exercise 14.8 Depth of Heat Penetration
375(2)
Exercise 14.9 Calculating Plate Surface Temperature under the Assumption that the Plate is a Semi-Infinite Body
377(1)
Exercise 14.10 Calculating Ground Temperature at a Specific Depth
378(1)
Exercise 14.11 Calculating the Depth of Heat Penetration in the Wall of a Combustion Engine
379(1)
Exercise 14.12 Calculating Quasi-Steady-State Ground Temperature at a Specific Depth when Surface Temperature Changes Periodically
380(2)
Exercise 14.13 Calculating Surface Temperature at the Contact Point of Two Objects
382(1)
Literature
383(2)
15 Transient Heat Conduction in Simple-Shape Elements
385(84)
Exercise 15.1 Formula Derivation for Temperature Distribution in a Plate with Boundary Conditions of 3rd Kind
385(9)
Exercise 15.2 A Program for Calculating Temperature Distribution and Its Change Rate in a Plate with Boundary Conditions of 3rd Kind
394(4)
Exercise 15.3 Calculating Plate Surface Temperature and Average Temperature Across the Plate Thickness by Means of the Provided Graphs
398(4)
Exercise 15.4 Formula Derivation for Temperature Distribution in an Infinitely Long Cylinder with Boundary Conditions of 3rd Kind
402(10)
Exercise 15.5 A Program for Calculating Temperature Distribution and Its Change Rate in an Infinitely Long Cylinder with Boundary Conditions of 3rd Kind
412(4)
Exercise 15.6 Calculating Temperature in an Infinitely Long Cylinder using the Annexed Diagrams
416(4)
Exercise 15.7 Formula Derivation for a Temperature Distribution in a Sphere with Boundary Conditions of 3rd Kind
420(8)
Exercise 15.8 A Program for Calculating Temperature Distribution and Its Change Rate in a Sphere with Boundary Conditions of 3rd Kind
428(4)
Exercise 15.9 Calculating Temperature of a Sphere using the Diagrams Provided
432(4)
Exercise 15.10 Formula Derivation for Temperature Distribution in a Plate with Boundary Conditions of 2nd Kind
436(5)
Exercise 15.11 A Program and Calculation Results for Temperature Distribution in a Plate with Boundary Conditions of 2nd Kind
441(3)
Exercise 15.12 Formula Derivation for Temperature Distribution in an Infinitely Long Cylinder with Boundary Conditions of 2nd Kind
444(4)
Exercise 15.13 Program and Calculation Results for Temperature Distribution in an Infinitely Long Cylinder with Boundary Conditions of 2nd Kind
448(4)
Exercise 15.14 Formula Derivation for Temperature Distribution in a Sphere with Boundary Conditions of 2nd Kind
452(4)
Exercise 15.15 Program and Calculation Results for Temperature Distribution in a Sphere with Boundary Conditions of 2nd kind
456(4)
Exercise 15.16 Heating Rate Calculations for a Thick-Walled Plate
460(1)
Exercise 15.17 Calculating the Heating Rate of a Steel Shaft
461(2)
Exercise 15.18 Determining Transients of Thermal Stresses in a Cylinder and a Sphere
463(1)
Exercise 15.19 Calculating Temperature and Temperature Change Rate in a Sphere
464(1)
Exercise 15.20 Calculating Sensor Thickness for Heat Flux Measuring
465(2)
Literature
467(2)
16 Superposition Method in One-Dimensional Transient Heat Conduction Problems
469(46)
Exercise 16.1 Derivation of Duhamel Integral
469(3)
Exercise 16.2 Derivation of an Analytical Formula for a Half-Space Surface Temperature when Medium's Temperature Undergoes a Linear Change in the Function of Time
472(4)
Exercise 16.3 Derivation of an Approximate Formula for a Half-Space Surface Temperature with an Arbitrary Change in Medium's Temperature in the Function of Time
476(3)
Exercise 16.4 Derivation of an Approximate Formula for a Half-Space Surface Temperature when Temperature of a Medium Undergoes a Linear Change in the Function of Time
479(2)
Exercise 16.5 Application of the Superposition Method when Initial Body Temperature is Non-Uniform
481(3)
Exercise 16.6 Description of the Superposition Method Applied to Heat Transfer Problems with Time-Dependent Boundary Conditions
484(4)
Exercise 16.7 Formula Derivation for a Half-Space Surface Temperature with a Change in Surface Heat Flux in the Form of a Triangular Pulse
488(3)
Exercise 16.8 Formula Derivation for a Half-Space Surface Temperature with a Mixed Step-Variable Boundary Condition in Time
491(4)
Exercise 16.9 Formula Derivation for a Plate Surface Temperature with a Surface Heat Flux Change in the Form of a Triangular Pulse and the Calculation of this Temperature
495(5)
Exercise 16.10 Formula Derivation for a Plate Surface Temperature with a Surface Heat Flux Change in the Form of a Rectangular Pulse; Temperature Calculation
500(3)
Exercise 16.11 A Program and Calculation Results for a Half-Space Surface Temperature with a Change in Surface Heat Flux in the Form of a Triangular Pulse
503(3)
Exercise 16.12 Calculation of a Half-Space Temperature with a Mixed Step-Variable Boundary Condition in Time
506(1)
Exercise 16.13 Calculating Plate Temperature by Means of the Superposition Method with Diagrams Provided
507(2)
Exercise 16.14 Calculating the Temperature of a Paper in an Electrostatic Photocopier
509(4)
Literature
513(2)
17 Transient Heat Conduction in a Semi-Infinite body. The Inverse Problem
515(26)
Exercise 17.1 Measuring Heat Transfer Coefficient. The Transient Method
515(3)
Exercise 17.2 Deriving a Formula for Heat Flux on the Basis of Measured Half-Space Surface Temperature Transient Interpolated by a Piecewise Linear Function
518(3)
Exercise 17.3 Deriving Heat Flux Formula on the Basis of a Measured and Polynomial-Approximated Half-Space Surface Temperature Transient
521(2)
Exercise 17.4 Formula Derivation for a Heat Flux Periodically Changing in Time on the Basis of a Measured Temperature Transient at a Point Located under the Semi-Space Surface
523(4)
Exercise 17.5 Deriving a Heat Flux Formula on the Basis of Measured Half-Space Surface Temperature Transient, Approximated by a Linear and Square Function
527(1)
Exercise 17.6 Determining Heat Transfer Coefficient on the Plexiglass Plate Surface using the Transient Method
528(4)
Graphical Method
529(1)
Numerical Method
529(3)
Exercise 17.7 Determining Heat Flux on the Basis of a Measured Time Transient of the Half-Space Temperature, Approximated by a Piecewise Linear Function
532(3)
Exercise 17.8 Determining Heat Flux on the Basis of Measured Time Transient of a Polynomial-Approximated Half-Space Temperature
535(4)
Literature
539(2)
18 Inverse Transient Heat Conduction Problems
541(32)
Exercise 18.1 Derivation of Formulas for Temperature Distribution and Heat Flux in a Simple-Shape Bodies on the Basis of a Measured Temperature Transient in a Single Point
541(4)
Plate
543(1)
Cylinder
543(1)
Sphere
544(1)
Exercise 18.2 Formula Derivation for a Temperature of a Medium when Linear Time Change in Plate Surface Temperature is Assigned
545(2)
Exercise 18.3 Determining Temperature Transient of a Medium for which Plate Temperature at a Point with a Given Coordinate Changes According to the Prescribed Function
547(2)
Exercise 18.4 Formula Derivation for a Temperature of a Medium, which is Warming an Infinite Plate; Plate Temperature at a Point with a Given Coordinate Changes at Constant Rate
549(6)
Exercise 18.5 Determining Temperature and Heat Flux on the Plate Front Face on the Basis of a Measured Temperature Transient on an Insulated Back Surface; Heat Flow on the Plate Surface is in the Form of a Triangular Pulse
555(7)
Exercise 18.6 Determining Temperature and Heat Flux on the Surface of a Plate Front Face on the Basis of a Measured Temperature Transient on an Insulated Back Surface; Heat Flow on the Plate Surface is in the Form of a Rectangular Pulse
562(3)
Exercise 18.7 Determining Time-Temperature Transient of a Medium, for which the Plate Temperature at a Point with a Given Coordinate Changes in a Linear Way
565(4)
Exercise 18.8 Determining Time-Temperature Transient of a Medium, for which the Plate Temperature at a Point with a Given Coordinate Changes According to the Square Function Assigned
569(2)
Literature
571(2)
19 Multidimensional Problems. The Superposition Method
573(14)
Exercise 19.1 The Application of the Superposition Method to Multidimensional Problems
573(4)
Exercise 19.2 Formula Derivation for Temperature Distribution in a Rectangular Region with a Boundary Condition of 3rd Kind
577(3)
Exercise 19.3 Formula Derivation for Temperature Distribution in a Rectangular Region with Boundary Conditions of 2nd Kind
580(2)
Exercise 19.4 Calculating Temperature in a Steel Cylinder of a Finite Height
582(2)
Exercise 19.5 Calculating Steel Block Temperature
584(3)
20 Approximate Analytical Methods for Solving Transient Heat Conduction Problems
587(18)
Exercise 20.1 Description of an Integral Heat Balance Method by Means of a One-Dimensional Transient Heat Conduction Example
587(3)
Exercise 20.2 Determining Transient Temperature Distribution in a Flat Wall with Assigned Conditions of 1st, 2nd and 3rd Kind
590(10)
Exercise 20.3 Determining Thermal Stresses in a Flat Wall
600(1)
Literature
600(5)
21 Finite Difference Method
605(54)
Exercise 21.1 Methods of Heat Flux Approximation on the Plate surface
606(4)
Exercise 21.2 Explicit Finite Difference Method with Boundary Conditions of 1st, 2nd and 3rd Kind
610(6)
Exercise 21.3 Solving Two-Dimensional Problems by Means of the Explicit Difference Method
616(6)
Exercise 21.4 Solving Two-Dimensional Problems by Means of the Implicit Difference Method
622(4)
Exercise 21.5 Algorithm and a Program for Solving a Tridiagonal Equation System by Thomas Method
626(4)
Exercise 21.6 Stability Analysis of the Explicit Finite Difference Method by Means of the von Neumann Method
630(4)
Exercise 21.7 Calculating One-Dimensional Transient Temperature Field by Means of the Explicit Method and a Computational Program
634(5)
Exercise 21.8 Calculating One-Dimensional Transient Temperature Field by Means of the Implicit Method and a Computational Program
639(5)
Exercise 21.9 Calculating Two-Dimensional Transient Temperature Field by Means of the Implicit Method and a Computational Program; Algebraic Equation System is Solved by Gaussian Elimination Method
644(8)
Exercise 21.10 Calculating Two-Dimensional Transient Temperature Field by Means of the Implicit Method and a Computational Program; Algebraic Equation System Solved by Over-Relaxation Method
652(4)
Literature
656(3)
22 Solving Transient Heat Conduction Problems by Means of Finite Element Method (FEM)
659(34)
Exercise 22.1 Description of FEM Based on Galerkin Method Used for Solving Two-Dimensional Transient Heat Conduction Problems
659(3)
Exercise 22.2 Concentrating (Lumped) Thermal Finite Element Capacity in FEM
662(6)
Exercise 22.3 Methods for Integrating Ordinary Differential Equations with Respect to Time Used in FEM
668(3)
Exercise 22.4 Comparison of FEM Based on Galerkin Method and Heat Balance Method with Finite Volume Method
671(3)
Exercise 22.5 Natural Coordinate System for One-Dimensional, Two-Dimensional Triangular and Two-Dimensional Rectangular Elements
674(4)
Exercise 22.6 Coordinate System Transformations and Integral Calculations by Means of the Gauss-Legendre Quadratures
678(9)
Exercise 22.7 Calculating Temperature in a Complex-Shape Fin by Means of the ANSYS Program
687(3)
Literature
690(3)
23 Numerical-Analytical Methods
693(40)
Explicit Method
694(1)
Implicit Method
694(1)
Crank-Nicolson Method
694(1)
Exercise 23.1 Integration of the Ordinary Differential Equation System by Means of the Runge-Kutta Method
695(3)
Exercise 23.2 Numerical-Analytical Method for Integrating a Linear Ordinary Differential Equation System
698(5)
Exercise 23.3 Determining Steel Plate Temperature by Means of the Method of Lines, while the Plate is Cooled by air and Boiling Water
703(6)
Exercise 23.4 Using the Exact Analytical Method and the Method of lines to Determine Temperature of a Cylindrical Chamber
709(5)
Exercise 23.5 Determining Thermal Stresses in a Cylindrical Chamber using the Exact Analytical Method and the Method of Lines
714(4)
Exercise 23.6 Determining Temperature Distribution in a cylindrical Chamber with Constant and Temperature Dependent Thermo-Physical Properties by Means of the Method of Lines
718(6)
Exercise 23.7 Determining Transient Temperature Distribution in an Infinitely Long Rod with a Rectangular Cross-Section by Means of the Method of Lines
724(5)
Literature
729(4)
24 Solving Inverse Heat Conduction Problems by Means of Numerical Methods
733(32)
Exercise 24.1 Numerical-Analytical Method for Solving Inverse Problems
733(6)
Exercise 24.2 Step-Marching Method in Time Used for Solving Non-Linear Transient Inverse Heat Conduction Problems
739(7)
Exercise 24.3 Weber Method Step-Marching Methods in Space
746(5)
Exercise 24.4 Determining Temperature and Heat Flux Distribution in a Plate on the Basis of a Measured Temperature on a Thermally Insulated Back Plate Surface; Heat Flux is in the Shape of a Rectangular Pulse
751(8)
Exercise 24.5 Determining Temperature and Heat Flux Distribution in a Plate on the Basis of a Temperature Measurement on an Insulated Back Plate Surface; Heat Flux is in the Shape of a Triangular Pulse
759(4)
Literature
763(2)
25 Heat Sources
765(34)
Exercise 25.1 Determining Formula for Transient Temperature Distribution Around an Instantaneous (Impulse) Point Heat Source Active in an Infinite Space
767(3)
Exercise 25.2 Determining Formula for Transient Temperature Distribution in an Infinite Body Produced by an Impulse Surface Heat Source
770(2)
Exercise 25.3 Determining Formula for Transient Temperature Distribution Around Instantaneous Linear Impulse Heat Source Active in an Infinite Space
772(2)
Exercise 25.4 Determining Formula for Transient Temperature Distribution Around a Point Heat Source, which lies in an Infinite Space and is Continuously Active
774(3)
Exercise 25.5 Determining Formula for a Transient Temperature Distribution Triggered by a Surface Heat Source Continuously Active in an Infinite Space
777(2)
Exercise 25.6 Determining Formula for a Transient Temperature Distribution Around a Continuously Active Linear Heat Source with Assigned Power ·q per Unit of Length
779(2)
Exercise 25.7 Determining Formula for Quasi-Steady-State Temperature Distribution Caused by a Point Heat Source with a Power Q0 that Moves at Constant Velocity v in Infinite Space or on the Half Space Surface
781(4)
Exercise 25.8 Determining Formula for Transient Temperature Distribution Produced by a Point Heat Source with Power Q0 that Moves At Constant Velocity v in Infinite Space or on the Half Space Surface
785(4)
Exercise 25.9 Calculating Temperature Distribution along a Straight Line Traversed by a Laser Beam
789(3)
Exercise 25.10 Quasi-Steady State Temperature Distribution in a Plate During the Welding Process; a Comparison between the Analytical Solution and FEM
792(4)
Literature
796(3)
26 Melting and Solidification (Freezing)
799(32)
Exercise 26.1 Determination of a Formula which Describes the Solidification (Freezing) and Melting of a Semi-Infinite Body (the Stefan Problem)
803(5)
Exercise 26.2 Derivation of a Formula that Describes the Solidification (Freezing) of a Semi-Infinite Body Under the Assumption that the Temperature of a Liquid Is Non-Uniform
808(3)
Exercise 26.3 Derivation of a Formula that Describes Quasi-Steady-State Solidification (Freezing) of a Flat Liquid Layer
811(5)
Exercise 26.4 Derivation of Formulas that Describe Solidification (Freezing) of Simple-Shape Bodies: Plate, Cylinder and Sphere
816(4)
Exercise 26.5 Ablation of a Semi-Infinite Body
820(3)
Exercise 26.6 Solidification of a Falling Droplet of Lead
823(2)
Exercise 26.7 Calculating the Thickness of an Ice Layer After the Assigned Time
825(1)
Exercise 26.8 Calculating Accumulated Energy in a Melted Wax
826(2)
Exercise 26.9 Calculating Fish Freezing Time
828(1)
Literature
829(2)
Appendix A Basic Mathematical Functions 831(6)
A.1. Gauss Error Function
831(2)
A.2. Hyperbolic Functions
833(1)
A.3. Bessel Functions
834(1)
Literature
835(2)
Appendix B Thermo-Physical Properties of Solids 837(26)
B.1. Tables of Thermo-Physical Properties of Solids
837(19)
B.2. Diagrams
856(2)
B.3. Approximated Dependencies for Calculating Thermo-Physical Properties of a Steel [8]
858(3)
Literature
861(2)
Appendix C Fin Efficiency Diagrams (for Chap. 6, Part II) 863(4)
Literature
865(2)
Appendix D Shape Coefficients for Isothermal Surfaces with Different Geometry (for Chap. 10, part II) 867(12)
Appendix E Subprogram for Solving Linear Algebraic Equations System using Gauss Elimination Method (for Chap. 6, Part II) 879(2)
Appendix F Subprogram for Solving a Linear Algebraic Equations System by Means of Over-Relaxation Method 881(2)
Appendix G Subprogram for Solving an Ordinary Differential Equations System of 1st order using Runge-Kutta Method of 4th Order (for Chap. 11, Part II) 883(2)
Appendix H Determining Inverse Laplace Transform for Chap. 15, Part II) 885
Literature
889

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