rent-now

Rent More, Save More! Use code: ECRENTAL

5% off 1 book, 7% off 2 books, 10% off 3+ books

9780849333651

Modeling of Combustion Systems: A Practical Approach

by ;
  • ISBN13:

    9780849333651

  • ISBN10:

    0849333652

  • Format: Hardcover
  • Copyright: 2006-03-24
  • Publisher: CRC Press

Note: Supplemental materials are not guaranteed with Rental or Used book purchases.

Purchase Benefits

  • Free Shipping Icon Free Shipping On Orders Over $35!
    Your order must be $35 or more to qualify for free economy shipping. Bulk sales, PO's, Marketplace items, eBooks and apparel do not qualify for this offer.
  • eCampus.com Logo Get Rewarded for Ordering Your Textbooks! Enroll Now
  • Write a Review Icon Write a Review
List Price: $240.00 Save up to $69.00
  • Rent Book $171.00
    Add to Cart Free Shipping Icon Free Shipping

    TERM
    PRICE
    DUE
    USUALLY SHIPS IN 3-5 BUSINESS DAYS
    *This item is part of an exclusive publisher rental program and requires an additional convenience fee. This fee will be reflected in the shopping cart.

How To: Textbook Rental

Looking to rent a book? Rent Modeling of Combustion Systems: A Practical Approach [ISBN: 9780849333651] for the semester, quarter, and short term or search our site for other textbooks by Colannino; Joseph. Renting a textbook can save you up to 90% from the cost of buying.

Summary

Increasing competitive pressure for improved quality and efficiency on one hand and tightening emissions and operating requirements on the other leave the modern process engineer squeezed in the middle. While effective modeling can help balance these demands, the current literature offers overly theoretical treatments on modeling that do not translate quickly and easily to the immediate needs of the practicing engineer.Based on more than a quarter-century of experience, Modeling of Combustion Systems: A Practical Approach introduces an approach to semi-empirical combustion modeling for better control, optimization, prediction, and description of industrial combustion processes. First, the author provides an introduction to modeling, the basic model categories, and analytical methods followed by an introduction to combustion that includes equipment and mathematical modeling. Next, he introduces the concepts and procedures of experimental design and provides detailed discussion on how to analyze non-ideal data.The final chapter draws together the previous information to clearly demonstrate the construction of semi-empirical models. Fully worked examples and step-by-step derivations support the discussion along the way, and the book also includes a complete guide to nomenclature and supplies appendices for important physical and chemical properties, conversions, statistical tables, and much more.Modeling of Combustion Systems: A Practical Approach provides concrete answers to real problems and is tailor-made to suit the needs of practicing engineers.

Table of Contents

List of Tables
List of Figures
Concordance of Nomenclature
About the Author
Prologue
Introduction to Modeling
1(100)
Model Categories
1(3)
Model Validation
2(1)
Fundamental Theoretical Models
2(1)
Simulations
2(1)
Semiempirical Models
3(1)
Dimensionless Models
3(1)
Empirical Models
3(1)
Problems with Post Hoc Models
4(1)
Kinds of Testing
4(1)
No Physical Testing
4(1)
Scale Testing
5(1)
Full-Scale Testing
5(1)
Analytical Methods
5(18)
Qualitative Analysis
6(2)
Dimensional Analysis
8(1)
Raleigh's Method
9(2)
Cautions Regarding Dimensional Analysis
11(4)
Function Shape Analysis
15(3)
The Method of Partial Fractions
18(4)
Limitations of Function Shape Analysis
22(1)
Perceiving Higher Dimensionality
23(6)
A View from Flatland
23(1)
Contour Surfaces
24(2)
Orthogonal Directions
26(1)
Visualization with Cubic Regions
26(2)
The Use of Color
28(1)
Basic Data Classifications
29(6)
Level of Scale
29(3)
Data Quality
32(1)
Planned Experiments
32(1)
Unplanned Experiments
33(1)
Source Classifications
33(1)
Functional Classifications
33(2)
A Linear Algebra Primer
35(20)
Matrix Addition
35(1)
The Transpose Operator
36(1)
Multiplication by a Constant
37(1)
Matrix Multiplication
37(1)
Distributive Property of Multiplication over Addition
38(1)
Symmetric Matrices
39(1)
The Identity Matrix
40(1)
The Unity, Zero, and Constant Vectors
41(1)
The Inverse
42(1)
Elementary Row Operations
42(3)
Solving for the Inverse
45(1)
The Determinant
46(1)
Orthogonality
47(5)
Eigenvalues and Eigenvectors
52(3)
Important Concepts and Notation
55(7)
Summation and Matrix Notation
55(1)
Converting between Summation and Matrix Notation
56(1)
Averages: Mean, Mode, and Median
57(1)
Various Means and the Generalized Mean
58(4)
Least Squares
62(31)
The Method of Least Squares
62(3)
The Method of Least Squares: The Calculus
65(4)
Least Squares for Continuous Intervals
69(3)
Least Squares as a Filter
72(3)
A Misconception about Least Squares
75(1)
Transforming Equations for Least Squares Fitting of the Parameters
75(2)
Constrained Polynomials
77(3)
Orthogonal Polynomials
80(3)
General Definition of Orthogonal Polynomials
83(7)
Discrete MOPs and Real Data
90(3)
Addendum
93(8)
Proof That M0 Reduces to the Geometric Mean
93(2)
Proof of the Monotonicity of Mp
95(3)
Proof That Mp Approaches xmax as P → ∞
98(1)
Proof That Mp Approaches xmin as P → ∞
99(1)
Proof xmin ≤ Mp ≤ xmax for x > 0
99(1)
Proof That Mp Increases with Increasing p and the Converse
99(1)
References
100(1)
Introduction to Combustion
101(90)
General Overview
102(21)
The Burner
102(1)
The Fuel System
103(1)
About Fuels
104(1)
Fuel Metering
105(1)
Turndown
105(1)
The Air System
106(2)
The Flame Holder
108(1)
Stabilizing and Shaping the Flame
108(1)
Controlling Emissions
109(1)
Archetypical Burners
109(2)
Round-Flame Gas Diffusion Burners
111(1)
Round-Flame Gas Premix Burners
111(2)
Flat-Flame Gas Diffusion Burners
113(1)
Flat-Flame Premix Burners
114(1)
Flashback
115(1)
Use of Secondary Fuel and Air
115(1)
Round Combination Burners
116(3)
Burner Orientations
119(1)
Upfired
119(1)
Downfired
120(1)
Side-Fired
121(1)
Balcony Fired
121(1)
Combination Side and Floor Firing
121(2)
Archetypical Process Units
123(4)
Boilers
123(1)
Firetube Boilers
123(1)
Watertube Boilers
123(1)
Fired Heaters and Reactors
123(1)
Vertical Cylindrical
124(1)
Cabin Style
124(2)
Fired Reactors
126(1)
Hydrogen Reformers
126(1)
Ammonia Reformers
126(1)
Ethylene Cracking Units (ECUs)
127(1)
Important Factors and Responses
127(8)
The Traditional Test Protocol
127(1)
Instability, Thermoacoustic and Otherwise
128(1)
Quarter-Wave Behavior
129(2)
Half-Wave Behavior
131(1)
Helmholtz Resonator Behavior
131(1)
Mechanism for Thermoacoustic Coupling
132(1)
Comments Regarding Thermoacoustic Resonance
133(1)
Resonance in the Field
134(1)
Mass Balance for Combustion in Air
135(29)
Wet vs. Dry Measurements
137(1)
Flue Gas Relations for Hydrocarbons
137(3)
Accounting for Moisture
140(3)
Addition of Molecular Hydrogen to the Fuel
143(2)
Addition of Flue Gas Components to Fuel
145(3)
Substoichiometric Combustion
148(1)
Lead-Lag Control
148(1)
Substoichiometric Equations
148(6)
Conservation of Mass for Flow in a Furnace
154(1)
Simplifying Assumptions (SAs)
155(3)
Ideal Gas Law
158(1)
Dilution Correction
159(5)
Conservation of Energy
164(9)
Heat and Related Quantities
164(1)
Work
165(1)
Heating Value
166(1)
Adiabatic Flame Temperature
167(2)
Heat Capacity as a Function of Temperature
169(2)
Adiabatic Flame Temperature with Preheated Air
171(2)
Mechanical Energy Balance
173(18)
Work Terms
173(1)
Theoretical Mechanical Models
174(1)
Units of Pressure
174(1)
Natural Draft Model
175(1)
Draft Pressure in a Furnace
175(2)
Air Velocity Due to Natural Draft
177(1)
Airflow through a Diffusion Burner
177(5)
Airflow through Adjustable Dampers
182(1)
Unknown Damper Characteristics
183(1)
Fuel Flow as a Function of Pressure
184(1)
Compressible Flow
185(1)
The Fuel Capacity Curve Revisited
186(2)
Airflow in Premix Burners
188(1)
Gas Jets Entraining Flue Gas
189(1)
References
189(2)
Experimental Design and Analysis
191(102)
Some Statistics
192(11)
Statistics and Distributions
193(1)
The Normal, Chi-Squared (X2), F, and t Distributions
194(1)
The Normal Distribution
195(1)
Probability Distribution for Galton's Board
196(1)
Pascal's Triangle
197(3)
The Chi-Squared Distribution
200(1)
The F Distribution
201(1)
The t Distribution
202(1)
The Analysis of Variance (ANOVA)
203(6)
Use of the F Distribution
206(3)
Two-Level Factorial Designs
209(25)
ANOVA for Several Model Effects
211(1)
General Features of Factorial Designs
212(1)
Construction Details of the Two-Level Factorial
213(3)
Contrast of Factorial and Classical Experimentation
216(3)
Statistical Properties of Classical Experimentation
219(2)
How Factorial Designs Estimate Coefficients
221(1)
The Sneaky Farmer
222(7)
Interpretation of the Coefficients
229(3)
Using Higher-Order Effects to Estimate Experimental Error
232(1)
Normal Probability Plots for Estimating Residual Effects
232(2)
Correspondence of Factor Space and Equation Form
234(6)
Fractional Factorials
240(5)
The Half Fraction
241(1)
Quarter and Higher Fractions
242(3)
ANOVA with Genuine Replicates
245(15)
Bias Error
248(2)
Center-Point Replicates
250(1)
Degrees of Freedom Entries
251(3)
Sum-of-Squares Entries
254(3)
Standard Errors and the t Test
257(1)
The Value of Orthogonal Designs with ANOVA
258(1)
Rotatability
259(1)
Randomization
260(3)
Hysteresis
260(1)
Lurking Factors
261(2)
About Residuals
263(6)
Residuals vs. Run Order
263(1)
Other Residual Plots
263(1)
Full and Block Randomization
264(1)
Blocking
265(1)
Random vs. Fixed Effects
265(4)
Screening Designs
269(6)
Simplex Designs
269(3)
Highly Fractionated Factorials
272(2)
Foldover
274(1)
Second-Order Designs
275(11)
Central Composites
275(2)
Quadratic Bias Only
277(1)
Orthogonal Components
278(2)
Adjusting the Axial Component
280(3)
Box--Behnken Designs
283(1)
Multilevel Factorials
283(3)
Sequential Experimental Design
286(7)
Augmenting to Less Fractionated Factorials
287(1)
Method of Steepest Ascent
287(2)
Augmenting to Second-Order Designs
289(2)
References
291(2)
Analysis of Nonideal Data
293(128)
Plant Data
294(4)
Problem 1: Events Too Close in Time
294(1)
Problem 2: Lurking Factors
295(1)
Problem 3: Moving Average Processes
295(2)
Some Diagnostics and Remedies
297(1)
Historical Data and Serial Correlation
297(1)
Empirical Models
298(7)
Model Bias from an Incorrect Model Specification
301(2)
Design Bias
303(2)
Ways to Make Designs Orthogonal
305(19)
Source and Target Matrices: Morphing Factor Space
306(2)
Eigenvalues and Eigenvectors
308(8)
Using Eigenvectors to Make Matrices Orthogonal
316(2)
Canonical Forms
318(1)
Derivation of A Canonical Form
318(1)
Derivation of B Canonical Form
319(1)
Canonical Form and Function Shape
320(4)
Regression Statistics and Data Integrity
324(24)
The Coefficient of Determination, r2
324(1)
Overfit
325(1)
Parsing Data into Model and Validation Sets
326(1)
The Adjusted Coefficient of Determination, rA2
327(1)
The PRESS Statistic
328(1)
The Hat Matrix
329(1)
The Coefficient of Determination, Predicted, r2p
330(1)
Extrapolation
331(5)
Failure to Detect Hidden Extrapolation
336(1)
Collinearity
337(2)
Reparameterization in Noncorrelated Factors
339(3)
Variance Inflation Factor
342(1)
Beta Coefficients
343(3)
Confidence and Prediction Intervals
346(2)
Residual Analyses
348(1)
Categorical Factors
349(34)
Multilevel Categorical Factors
349(3)
Accounting for Multiple Blocks
352(4)
Accounting for Hard-to-Change Factors
356(1)
The Longest Duration Experimental Series
357(1)
The Shortest Duration Experimental Series
358(3)
Experimental Units
361(1)
The Split-Plot Design
362(5)
Expected Mean Squares (EMS)
367(1)
Methodology for Deriving EMS for Balanced Data
367(6)
EMS for the Factorial Design
373(1)
EMS for a Split-Plot Design
374(4)
Split-Plot Structure with Multiple Whole-Plot Factors
378(5)
Nested Factors
383(1)
Categorical Response Values
383(3)
Conversion from Qualitative to Quantitative Measures
384(1)
Using the Logit and Probit Functions to Categorize Flame Quality
385(1)
Mixture Designs
386(35)
Simplex-Centroid
388(2)
Simplex-Lattice
390(1)
Simplex-Axial
391(1)
Generalizing to Higher Dimensions
392(3)
Fuels of Many Components
395(1)
Fuel Chemistry
395(1)
Hydrogen
396(1)
Hydrocarbon Chemistry
396(1)
Bonding
397(1)
Saturates
397(2)
Olefins
399(1)
Coke Formation
399(1)
Mono-Olefins
400(1)
Di-Olefins
400(1)
Acetylenes
401(1)
Aromatic Hydrocarbons
401(1)
Cyclo Hydrocarbons
402(1)
Representing Gaseous Fuel Blends
402(1)
Chemical Bond Method
403(4)
Equivalent Oxygen Method
407(1)
Component Ranges
408(2)
Pseudo-Components
410(1)
Orthogonal Mixture Designs
410(1)
Ratios of Mixture Fractions
411(2)
Combining Mixture and Factorial Designs
413(1)
Mixtures within Factorial
414(1)
Mixture within Fractional Factorial
414(1)
Fractionated Mixture within Fractional Factorial
415(5)
References
420(1)
Semiempirical Models
421(110)
NOx and Kinetics
422(21)
NOx: Some General Comments
422(1)
The Thermal NOx Mechanism
422(2)
The Fuel-Bound Nitrogen Mechanism
424(2)
The Prompt NOx Mechanism
426(1)
Chemical Kinetic Effects for NOx in Diffusion Flames
427(1)
NOx Response to Air in Diffusion Flames
427(5)
Dimensional Units for NOx
432(2)
The Relation of Referent and Objective Forms
434(1)
NOx Response to Temperature in Diffusion Flames
435(3)
NOx Response to Fuel Composition
438(1)
Chemical NOx When Prompt NOx Is Important
439(1)
Chemical Kinetic Effects for NOx in Premixed Flames
440(1)
NOx Response to Temperature in Premixed Flames
440(1)
NOx Response to Air in Premixed Burners
440(1)
Solving for δ as a Function of αw
441(1)
Solving for T as a Function of αw
441(1)
Log NOx as a Function of αw
442(1)
Overview of NOx Reduction Strategies
443(15)
Low Excess Air (LEA) Operation
443(2)
Air Staging
445(1)
Overfire Air
445(1)
Burners out of Service (BOOS)
446(1)
Fuel Staging
446(1)
Fuel Blending
447(1)
Flue Gas Recirculation
447(1)
Mass-Based Relations
447(3)
Molar and Volumetric Definitions
450(3)
Fuel Dilution, Flue Gas Inducted Recirculation (FIR)
453(3)
Steam or Water Injection
456(1)
Selective Noncatalytic Reduction (SNCR)
456(1)
Selective Catalytic Reduction (SCR)
457(1)
NOx Models
458(19)
Categorization of Emissions Reduction Strategies
460(1)
Temperature Reduction Strategies
460(1)
Fuel Blending or Fuel Dilution
460(1)
Flue Gas Inducted Recirculation
460(1)
Flue Gas Recirculation
461(1)
Steam or Water Injection
462(1)
Air Staging
462(5)
Fuel Staging
467(1)
Overfire Air
467(2)
Burners out of Service
469(1)
Concentration Reduction Strategies
469(1)
Low Excess Air (LEA) Operation
469(1)
Air Staging with Fuel-Bound Nitrogen
470(1)
Fuel Staging with Fuel-Bound Nitrogen
471(1)
Reagent Injection Strategies
471(1)
Selective Noncatalytic Reduction (SNCR)
471(5)
Selective Catalytic Reduction (SCR)
476(1)
Limestone Injection
476(1)
CO Models
477(6)
Cold CO
478(1)
Hot CO
479(1)
General Behavior of Hot CO
479(2)
Equilibrium Considerations
481(2)
Arrested Oxidation of CO (via Ammoniacal Poisoning of OH Catalysis)
483(1)
Response Transformations
483(3)
Empirical Considerations for Transformation of the CO Response
483(3)
Empirical Considerations for Transformation of NOx Response
486(1)
Heat Flux
486(29)
Heat Flux Profile
487(2)
The Normalized Heat Flux Equation
489(2)
Data Normalization
491(1)
Data Smoothing
492(5)
Renormalization
497(3)
The Heat Flux Model
500(1)
Heat Flux as a Function of Furnace Temperatures
500(3)
Qualitative Behavior of zmax
503(3)
The Effect of Air Preheat
506(1)
The Effect of Air/Fuel Ratio
507(1)
The Effect of Fuel Pressure
507(2)
Heat Flux Profile in Terms of Fractional Heat Release
509(2)
The Effect of the Heat Sink (Process)
511(1)
Final Heat Flux and Process Efficiency
512(1)
Run Length and Flux Profile Curvature
512(1)
Factors Affecting the Initial Heat Flux
513(2)
Similarity and Scaling of Heat Flux Curves
515(1)
Flame Shape
515(6)
Flame Measurements
516(1)
Flame Length
517(4)
Visible Plumes
521(10)
Bisulfite Plumes
521(1)
Ammonium Chloride Plumes
522(2)
Sulfur Oxides
524(1)
Equations for Dew Point Elevation
525(3)
References
528(3)
Epilogue
531(1)
References
532(87)
Appendices
A. Fuel and Combustion Properties
533(22)
B. Mechanical Properties
555(18)
C. Units Conversions
573(4)
D. Properties of the Elements
577(24)
E. Statistical Tables
601(8)
F. Numbers in Binary, Octal, and Hexadecimal Representations
609(4)
G. Kinetics Primer
613(4)
H. Equilibrium Primer
617(2)
Index 619

Supplemental Materials

What is included with this book?

The New copy of this book will include any supplemental materials advertised. Please check the title of the book to determine if it should include any access cards, study guides, lab manuals, CDs, etc.

The Used, Rental and eBook copies of this book are not guaranteed to include any supplemental materials. Typically, only the book itself is included. This is true even if the title states it includes any access cards, study guides, lab manuals, CDs, etc.

Rewards Program