Description |
1 online resource (xiii, 539 pages) : illustrations (some color) |
Series |
Mechanical engineering theory and applications series |
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Mechanical engineering theory and applications series
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Contents |
THERMAL ENGINEERING RESEARCH DEVELOPMENTS ; THERMAL ENGINEERING RESEARCH DEVELOPMENTS ; CONTENTS ; PREFACE ; OPTIMIZING PRELIMINARY DESIGN OF INDUSTRIALEQUIPMENT INVOLVING DIFFERENT THERMALENGINEERING CALCULATION PROCEDURESOVER A POWER PLANT; Abstract; Nomenclature; Greek Symbols; Subscripts; Superscripts; 1. Introduction; 2. Part A: Design and Optimisation of a Burnerthrough CFD Based on Experimental Data; 2.1. Introduction; 2.2. Aims and Methodology; 2.3. Experimental Procedure; Description of the Experimental Procedure; Experimental Results; 2.4. Numerical Simulations |
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Building a CFD Model for the Experimental BurnerDefining the Basic Conservation Equations; Defining Boundary Conditions; Defining the Turbulence Model; Defining the Wall Functions; Defining the Radiation Model; Defining the Combustion Model; Defining the Nox Model; A) Thermal Route; B) Prompt Route; C) Fuel Route; D) Intermediate N2O Route; Validating the CFD Model; Further Improvements Introduced to the CFD Model; Building a CFD Model for the Prototype Burner; 2.5. Results and Discussion; Analysis of the Alternatives Studied for the Prototype Burner |
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Comparative Results for Both Experimental (Corrected) and Prototype BurnersAnalysis of the Sensibility and Response of the Prototype Burner; Behaviour under a Combustion Based on Swirling Injections; 2.6. Conclusion; 3. Part B: Analytical Study of the Effects of the Clogging of a Mechanical Precipitator Unit; 3.1. Introduction; 2.2. Aims and Methodology; 3.3. Theoretical Time Dependent Study of the Heat Transfer Process; 3.4. Analysis of the Ash Accumulation Inside; 3.5. Results and Discussion; 3.6. Conclusion |
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4. Part C: Performance Efficiency of a Cogeneration Power Plantwith Natural Gas Engines4.1. Introduction; 4.2. Heat and Electricity Loads; Steam Loads; Hot Water Load; 4.3. Methodology; Plant Capacity Criteria; Economy and Working Criteria; Technological Criteria; 4.4. Alternatives; Alternative 1: Internal Combustion Engines; Alternative 2: Gas Turbines; 4.5. Definition of the Auxiliary Equipment; 4.6. Energy Analysis; Energy Balance; Summary of the Energy Assessment; 4.7. Economical Analysis; Initial Hypothesis; Assessment of the Yearly Expected Saving |
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Consumptions and Productions EstimationThermal and Electricity Bill; Working and Maintenance Costs; Investment; 4.8. Results and Discussion; 4.9. Conclusion; 5. Part D: Optimising the Process for Emptying the CO2 Bottles inHigh-Power Generators; 5.1. Introduction; 5.2. Aims and Methodology; 5.3. Description of the Generator Loading and Unloading Process; 5.4. Cooling the Inside of the Bottles during the Unloading Process; 5.5. Assessing the Number of CO2 Bottles Required; Bottles for Unit 1; Bottles for Unit 2; 5.6. Study of the Arrangement for Introducing CO2 into the Generator |
Bibliography |
Includes bibliographical references and index |
Notes |
Print version record |
Subject |
Heat engineering.
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Heat -- Transmission.
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Thermodynamics.
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heat transmission.
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thermodynamics.
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TECHNOLOGY & ENGINEERING -- Mechanical.
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Heat engineering
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Heat -- Transmission
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Thermodynamics
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Form |
Electronic book
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Author |
Evgova, Jovan.
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Kostadinov, Ognjan.
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ISBN |
9781611224399 |
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161122439X |
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