Suchergebnisse

A fact sheet overview of the activities of the Office of Energy Efficiency.

Intro -- EMISSIONS CONTROL IN ELECTRICITY GENERATION -- EMISSIONS CONTROL IN ELECTRICITY GENERATION -- CONTENTS -- PREFACE -- Chapter 1 CARBON CONTROL IN THE U.S. ELECTRICITY SECTOR: KEY IMPLEMENTATION UNCERTAINTIES* -- SUMMARY -- INTRODUCTION -- ENERGY EFFICIENCY AND CONSERVATION -- Electricity-Efficiency Potential -- Impacts from Electricity-Efficiency Initiatives -- Uncertainty about the Efficiency Opportunity -- RENEWABLE ENERGY -- Wind Power -- Transmission Requirements -- Transmission Grid Uncertainty -- Biomass Power Generation -- Biomass Fuel Supply -- Biomass Fuel Uncertainty -- NUCLEAR POWER GENERATION -- Nuclear Power Construction Uncertainty -- ADVANCED COAL-FIRED POWER GENERATION -- Uncertainty in Coal Plant Financing and Approval -- CARBON CAPTURE AND SEQUESTRATION -- CCS Technology Uncertainty -- PLUG-IN ELECTRIC HYBRID VEHICLES -- DISTRIBUTED ENERGY RESOURCES -- POLICY ISSUES FOR CONGRESS -- Possible Outcomes for Carbon Control -- Underperformance of Individual CO Measures -- Failure of the CO Mitigation Portfolio -- CONCLUSION -- End Notes -- Chapter 2 AVAILABLE AND EMERGING TECHNOLOGIES FOR REDUCING GREENHOUSE GAS EMISSIONS FROM COAL-FIRED ELECTRIC GENERATING UNITS* -- ACRONYMS AND ABBREVIATIONS -- 1. INTRODUCTION -- 1.1. Electric Power Generation Using Coal -- 2. COAL-FIRED ELECTRIC GENERATING UNITS -- 2.1. Coals Burned in U.S. EGUs -- 2.2. Coal Utilization in U.S. EGUs -- 2.2.1. Stoker-Fired Coal Combustion -- 2.2.2. Pulverized-Coal Combustion -- 2.2.3. Cyclone Coal Combustion -- 2.2.4. Fluidized-Bed Combustion -- 2.2.5. Coal Gasification -- 2.3. GHG Emissions from Coal-Fired EGUs -- 2.4. Factors Impacting Coal-Fired EGU CO2 Emissions -- 2.4.1. Impact of Coal Rank on CO2 Emissions from EGUs -- 2.4.2 Impact of Coal-Fired EGU Efficiency on CO2 Emissions -- 2.4.3. Impact of SO2 Controls on Coal-Fired EGU CO2 Emissions

The Main objective of writing these paper is to reduce the pollution in India for the human wellbeing, Now a days ,pollution, population electricity ,transportation are the main problems facing our country. No one can stop this kind of thing to take place in our live. In the rural areas ,the solid waste is more bio-degradable in nature and the components like plastics & packing are non-biodegradable by Government various initiatives are taken by NGO and private companies are increased in past few decoder, but the land is still filling by the solid waste and the other types of garbage all around the world. To overcome these problems of MSW (Municipal solid waste), in our project we are going to produce or generate the electricity from waste, we can make the garbage useful. First the municipal waste is collected and it can be separated and all of the solid waste is remove and collected then all of these solid waste is pass to the inside the boiler. The boiler which is filled with water inside it and the water inside it and the water is heated at the high pressure steam that can be generated and pass to the turbine from the nozzle of the boiler .Then due to high pressure use the turbine is coupled to the shaft of the generator due to rotation of the turbine t generator as well rotate due to which electricity will be generated. Key Words: India, MSW (municipal solid waste), waste management, pollution minimization, electricity generation

The levelized cost of electricity is estimated for more than 70 electricity production technologies and for two facility ownership sectors. The analysis uses a Lotus 1–2‐3 spreadsheet for a consistent approach. The cost effectiveness of several alternative technologies is compared with that of conventional technologies. A variety of owners could build and operate facilities made from these conventional and alternative technologies.