Analysis of Energy Efficiency of Industrial Processes
It is universally recognized that the end of the current and the beginning of the next century will be characterized by a radical change in the existing trends in the economic development of all countries and a transition to new principles of economic management on the basis of a resource and energy...
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Format: | eBook |
Language: | English |
Published: |
Berlin, Heidelberg
Springer Berlin Heidelberg
1993, 1993
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Edition: | 1st ed. 1993 |
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Online Access: | |
Collection: | Springer Book Archives -2004 - Collection details see MPG.ReNa |
Table of Contents:
- 1. The Technological Process as a Subject of Thermodynamic Analysis
- 1.1 Thermodynamic Systems and Processes
- 1.2 The Laws 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
- 2.3 Solving Practical Problems
- 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
- 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
- 8.2 Coke and Coking By-product Production
- 8.3 Rolled Stock
- 8.4 Influence of Other Parameters
- References
- 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
- 5.2 Energy Balances of the Metallurgical Complex and its Main Shops
- 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
- 6.2 Lead and Zinc Production
- 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 ofEnergy Reserves as a Result of Energy Conservation. Ferrous Metallurgy
- 8.1 Steelmaking