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" Analysis of energy efficiency of industrial processes. "
Vladimir S Stepanov
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BL
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| Record Number
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753654
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b573615
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| Main Entry
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Vladimir S Stepanov
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| Title & Author
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Analysis of energy efficiency of industrial processes.\ Vladimir S Stepanov
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| Publication Statement
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[Place of publication not identified] : Springer, 2012
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| ISBN
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3642771483
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: 9783642771484
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| Contents
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1. The Technological Process as a Subject of Thermodynamic Analysis.- 1.1 Thermodynamic Systems and Processes.- 1.2 The Laws of Thermodynamics.- 1.2.1 Internal Energy, Work and Heat. The First Law of Thermodynamics.- 1.2.2 The Second Law of Thermodynamics.- 1.2.3 The Third Law of Thermodynamics.- 1.3 State Functions.- 1.4 Thermodynamic Properties of Substances and Their Changes in Chemical Processes.- 1.5 Thermochemistry.- 1.6 Maximum and Minimum Work. The Gouy-Stodola Law.- 1.7 The Concept of Exergy. The Exergy Method of Analysis.- 2. Efficiency of Technological Processes Based on Energy Balance.- 2.1 Heat Balance of a Process.- 2.2 Complete Energy Balance.- 2.2.1 Derivation.- 2.2.2 Components of the Complete Energy Balance.- 2.3 Solving Practical Problems.- 2.3.1 Determination of Energy Use Efficiency in a Process. Idealized and Ideal Analogs of Processes.- 2.3.2 Energy Losses and Secondary Energy Resources.- 2.4 Theoretical Potential and Energy Reserves.- 3. Calculation of Chemical Energy and Exergy of Elements and Elementary Substances.- 3.1 Choice of Environment Model.- 3.2 Short Overview of Methods.- 3.2.1 The Simplified Ozoling-Stepanov Technique.- 3.2.2 Comparison of the Different Methods.- 4. Optimizing the Use of Thermal Secondary Energy Resources.- 4.1 Thermal Secondary Energy Resources.- 4.2 Minimizing Costs. Optimal Composition of Heat Recovery Installations.- 4.2.1 Costs of Production of Secondary Energy Resources.- 4.2.2 Costs of Reliability Improvement.- 4.2.3 Calculation of the Minimized Total Costs.- 4.3 Determination of the Optimal Extent of Secondary Energy Resource Utilization at an Industrial Plant.- 5. Energy Balances in Ferrous Metallurgy.- 5.1 The Production Scheme.- 5.1.1 Metallurgical Cycle.- 5.1.2 Coke and Coking By-product Cycle.- 5.2 Energy Balances of the Metallurgical Complex and its Main Shops.- 5.2.1 Energy Use Efficiency.- 5.3 Energy Losses and Possible Secondary Energy Resources.- 5.4 Determination of the Economically Feasible Value of Using Thermal Secondary Energy Resources.- 6. Energy Use for Energy Efficiency Increase in Non-ferrous Metallurgy.- 6.1 Copper Production.- 6.1.1 Production Scheme and Energy Balances in Reverberatory Smelting.- 6.1.2 Autogenous Processes.- 6.2 Lead and Zinc Production.- 6.2.1 Production Scheme and Energy Balances in Lead Production Using Blast Smelting.- 6.2.2 Zinc Production in Hydrometallurgy.- 6.3 Production of Titanium and Magnesium.- 7. Predicting Energy Conservation in an Industry by Modeling Individual Sectors.- 7.1 The Scope of the Problem.- 7.2 Forecasting Energy Consumption in an Industrial Sector.- 7.3 Forecasting Exergy Expenditures.- 7.4 Financial and Energy Expenditures for Environmental Protection.- 8. Evaluation of Energy Reserves as a Result of Energy Conservation. Ferrous Metallurgy.- 8.1 Steelmaking.- 8.1.1 Energy Conservation Due to Technological Restructuring.- 8.1.2 Impact of Improvements in Current Production Processes.- 8.2 Coke and Coking By-product Production.- 8.3 Rolled Stock.- 8.4 Influence of Other Parameters.- References.
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| LC Classification
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TJ163.3V533 2012
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| Added Entry
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Vladimir S Stepanov
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