NEW YORK, Jan. 6, 2014 /PRNewswire/ -- Reportlinker.com announces that a new market research report is available in its catalogue:
Strategic Analysis of the Australian Waste-to-Energy Market
Opportunities Abound Due to Rising Landfill Cost and Proven Energy Conversion Technologies
Research Objectives
-To understand the status and potential of waste-to-energy (including municipal solid waste, biomass, and biogas) in Australia
-To understand the challenges facing waste-to-energy project developments
-To outline the relevant regulatory framework at national and state level
-To forecast an indicative timeframe for large scale MSW investment
-To identify critical success factors for MSW waste-to-energy projects in Australia
-To provide benchmarking scenarios with Europe and North America
Research Methodology
This research service is based on interviews with MSW project developers, state Environment Protection Agencies, waste management experts, and literature review from local and global resources.
The responses, findings, and analysis are woven through the study.
Introduction
-Waste-to-energy (WTE) includes methods by which the valuable energy entrapped in waste is extracted, for the production of electricity and heat.
-Waste from cities contains a large amount of biological and renewable materials — a source of renewable energy. As a result, energy-from-waste contributes to energy security and diversification, and helps address the growing demand for renewable energy in a carbon constrained world.
-Extracting energy from waste has broad applications – ranging from direct combustion of dry wastes such as sawdust, rice husks, and palm oil kernels on-site in boilers to provide cheap process heat for factories; using sugarcane processing residue (bagasse) as feedstock for heat and power generation; using animal waste to generate biogas; incinerate municipal waste directly to generate heat and power, using landfill gas as feedstock to generate power.
-Where biomass residues (corn cobs, tree bark, forest residues, wood chips, or animal fat) have already been delivered to a processing site along with the primary product (corn kernels, pulp logs or meat), the biomass value, dollar per GigaJoule ($/GJ) is usually very competitive, particularly where there may even be an avoided disposal cost.
According to the only existing policy on energy conversion from waste (issued by New South Wales Environment Protection Agency (EPA), the following wastes are considered eligible to be used as waste-to-energy feedstock:
-Biomass from agriculture
-Residues from plantation forestry and sawmilling operations
-Uncontaminated wood waste
-Recovered waste oil and tallow
-Waste from virgin paper pulp activities
-Coal washery rejects
-Landfill and biogas In addition, the Renewable Energy (Electricity) Act 2000 - under section xx - sets out what is an eligible renewable energy source. Several biogenic wastes are eligible for obtaining large scale generation certificates for accredited power stations. These eligible renewable energy sources include:
-Energy crops
-Wood waste
-Agricultural waste
-Waste from processing of agricultural products
-Food waste
-Food processing waste
-Bagasse
-Biomass-based components of municipal solid waste
-Biomass-based components of sewage
There are unavoidable overlaps between energy conversion technologies from municipal solid waste and other types of waste, especially when technology developers endeavour to expand application areas. For example, improved pyrolysis technology has the potential to treat part of municipal solid waste for biochar.
-Rising energy prices, carbon tax, rising landfill cost in major capital cities, and growing environmental concerns have led to an increased interest in renewable sources of electricity generation.
-Cost- and technology-competitive MSW power generation has yet to reach maturity due to regulatory, technological, and public opposition issues. The concerns for the environmental condition adjacent to their homes prevail, irrespective of the actual emissions impact of a proposed plant, thus making it difficult for new plant projects to pass the community consultation stage. The Productivity Commission Inquiry into Waste Management and Resource Efficiency (2006) also concluded that waste policy should maximise net community benefits (as opposed to resource efficiency).
-The first specific policy for energy generation from waste in the country is expected to be finalised in January 2014 by the New South Wales Environment Protection Agency. In this version, the technical criteria are expected to be lowered based on feedback from industry and community to the draft policy.
-The first large scale MSW power generation plant is in the process of obtaining licenses and contract signing with local councils for waste supply. It has yet to demonstrate its minimum environmental impact.
-The large scale MSW power generation segment is expected to witness rapid growth after 2018 with the successful commissioning of first plants, the finalisation of supportive regulation, and more importantly, the exhaustion of landfill space in populated east coast capital cities.
-In addition, the relatively low energy recovery potential from anaerobic digestion (100–150 kWh/tonne of MSW) and the expensive requirement to landfill the bulk of the solid product from such processes (due to contamination from glass, sharps), is another reason why thermal WTE is the predominant technological solution for maximising the diversion of food, organics, plastic, and paper away from landfill.
-'Other' wastes (biomass and biogas) power generation has been broadly adopted because of abundant availability of appropriate wastes and mature power generation technologies. Nevertheless, stronger incentives from government are required for the sector to pick up more rapidly.
-The NSW and WA experience with anaerobic and aerobic digestion processes for processing organic waste shows that biological processes are typically costly and achieve only 'partial volume reduction' processes, which do not significantly increase waste diversion rates or energy recovery.
Executive Summary
-Research Objectives and Methodology
-Introduction
-Market Snapshot by State
-Waste-to-Energy Market—PESTIE Analysis
-Key Findings
Regulatory Framework
-Regulatory Framework —National
-Regulatory Framework—by State
Feedstock Availability
-Australian Waste Availability
External Challenges— Market Drivers and Restraints
-Drivers—Impact and Duration
-Restraints—Impact and Duration
MSW Waste-to-Energy Market
-Overview
-Technology Overview
-MSW Waste-to-Energy Market Analysis
-MSW Power Generation Installed Capacity Forecast
-MSW Power Generation Plants Revenue Forecast
-Market Participants – MSW WTE Technology Suppliers
-Project Overview
-Case Study
-Success Factors
'Other' Types of Waste (Biomass and Biogas) Power Generation
-Introduction
-Biomass Power Generation Installed Capacity Forecast
-Biomass Power Generation Plants Revenue Forecast
-Biomass Power Generation
-Biogas Power Generation Installed Capacity Forecast
-Biogas Power Generation Plants Revenue Forecast
-Biogas Power Generation
-Biomass and Biogas—Power Generation Plant Cost Analysis
-Biomass and Biogas—Power Generation Plant Market Analysis
-Market Competition – Biomass Equipment Suppliers
-Market Competition – Biogas Equipment Suppliers
-Plant Operators – Biomass and Biogas
MSW Power Generation Global Scenarios—North America and European Union
-Global Market Dynamics—Drivers
-Global Market Dynamics—Restraints
-Global Market Forecast
-North America
-European Union
Mega Trends and Industry Convergence Implications
Conclusion
-Conclusion—Municipal Solid Waste WTE Sector
-Conclusion—Other Types of Waste WTE Sector
Appendix
The Frost & Sullivan Story
Exhibit
Waste-to-Energy Market: Segmentation Based on Feedstock Type, Australia, 2013
Waste-to-Energy Market: Segmentation Based on Conversion Technology, Australia, 2013
Waste-to-Energy Market: Market Participants, Australia, 2013
Waste-to-Energy Market: State Regulatory Framework Development, Australia, 2013
Waste-to-Energy Market: Relevant Regulations and Policies, New South Wales, 2013
Waste-to-Energy Market: NSW Energy from Waste Draft Policy, Australia, 2013
Waste-to-Energy Market: NSW Energy from Waste Draft Policy–Resource Recovery Rates, Australia, 2013
Waste-to-Energy Market: Relevant Regulations and Policies, Victoria, 2013
Waste-to-Energy Market: Relevant Regulations and Policies, Queensland, 2013
Waste-to-Energy Market: Relevant Regulations and Policies, South Australia, 2013
Waste-to-Energy Market: Relevant Regulations and Policies, Western Australia, 2013
Waste-to-Energy Market: Total National Waste Generation, Australia, 2009
Waste-to-Energy Market: Generated Waste by Source, Australia, FY2007
Waste-to-Energy Market: Waste to Landfill by Source, Australia, FY2007
Waste-to-Energy Market: Generated Municipal Solid Waste Forecast, Australia, FY2007–FY2020
Waste-to-Energy Market: Waste Hierarchy, Australia, 2013
Waste-to-Energy Market: Waste to Landfill Share by Source and States, Australia, FY2007
Waste-to-Energy Market: Impact of Key Market Drivers, Australia 2014–2020
Waste-to-Energy Market: Expected Depletion Date Range for Approved Landfill Airspace at Major Population Centres, Australia, 2013–2020
Waste-to-Energy Market: Impact of Key Market Restraints, Australia 2014–2020
Waste-to-Energy Market: Waste Recycling Per Capita by State & Territory, Australia, 2008–2009
Waste-to-Energy Market: Municipal Waste Flow, Australia, 2013
Waste-to-Energy Market: MSW Preparation – Feedstock Pre-treatment, Global, 2013
Waste-to-Energy Market: MSW Waste-to-Energy Segmentation by Technology, Australia, 2013
Waste-to-Energy Market: Incineration Technology Overview, Global, 2013
Waste-to-Energy Market: Types and Specifications of Incineration Technology, Global, 2013
Waste-to-Energy Market: MSW Waste-to-Energy Life Cycle, Australia, 2013
Waste-to-Energy Market: Municipal Solid Waste Power Generation Installed Capacity Forecast, Australia, 2015–2020
Waste-to-Energy Market: Municipal Solid Waste Power Generation Plants Revenue Forecast, Australia, 2015–2020
Waste-to-Energy Market: Process Sketch of EDL Wollongong Site, Australia, 2013
Waste-to-Energy Market: Biomass Power Generation Installed Capacity Forecast, Australia, 2011–2020
Waste-to-Energy Market: Biomass Power Generation Plants Revenue Forecast, Australia, 2011–2020
Waste-to-Energy Market: Available Woody Biomass Feedstock Volume, Australia, 2012
Waste-to-Energy Market: Biomass Power Generation Life Cycle, Australia, 2013
Waste-to-Energy Market: Biogas Power Generation Installed Capacity Forecast, Australia, 2011–2020
Waste-to-Energy Market: Biogas Power Generation Plants Revenue Forecast, Australia, 2011–2020
Waste-to-Energy Market: Biomass Power Generation Life Cycle, Australia, 2013
Waste-to-Energy Market: Key Performance Parameters and Associated Cost Estimates for Other Waste to Energy Technologies, Australia, 2012
Waste-to-Energy Market: Number of Coal and Biomass Co-Fired Power Plants, Global, 2009 and 2011
Waste-to-Energy Market: Co-firing Biomass Plant and Dedicated Biomass Plant Cost Comparison, Global, 2009
Waste-to-Energy Market: Biomass Equipment Supplier Competitive Structure, Australia, 2013
Waste-to-Energy Market: Biogas Equipment Supplier Competitive Structure, Australia, 2013
Waste-to-Energy Market: Major Biomass Energy Generation Companies, Australia, 2013
Waste-to-Energy Market: Major Biogas Energy Generation Companies, Australia, 2013
Waste-to-Energy Market: Key Market Drivers, Global, 2012–2016
Waste-to-Energy Market: Key Market Restraints, Global, 2012–2016
Waste-to-Energy Market: Number of MSW WTE Plants Forecast by Region, Global, 2011–2025
Waste-to-Energy Market: Market Share of MSW WTE Plants by Region, Global, 2011–2025
Waste-to-Energy Market: Cumulative Installed Capacity Forecast for the Biomass Segment, North America, 2010–2016
Waste-to-Energy Market: Revenue Forecast for the Biomass Segment, North America, 2010–2016
Waste-to-Energy Market: Market Share of Key Participants by Cumulative Installed Capacity, North America, 2010–2016
Waste-to-Energy Market: Biomass Power Generation, North America, 2009
Waste-to-Energy Market: MSW WTE Power Generation, North America, 2009
Waste-to-Energy Market: Revenue Forecast, Europe, 2009–2016
Waste-to-Energy Market: Number of Plants by Region, MSW Material Use and Average Size of Plant, Energy Generated and Average Calorific Value of MSW Input Material, Europe, 2012
Waste-to-Energy Market: Per cent of Plants by Incineration Technology, Europe, 2012
Waste-to-Energy Market: Per cent of Incineration Plants by Year of Installation, Europe, 2012
Waste-to-Energy Market: Mega Trend Impact, Australia, 2014–2020
Waste-to-Energy Market: Capex Split of Mass Combustion Technology, Europe, 2013
Waste-to-Energy Market: Capex Trend in Corresponding to Plant Size of Mass Combustion Technology, Europe, 2013
Waste-to-Energy Market: Opex Split of Mass Combustion Technology, Europe, 2013
Waste-to-Energy Market: Opex Trend Corresponding to Plant Size of Mass Combustion Technology, Europe, 2013
Waste-to-Energy Market: Biomass and Waste Electricity Net Generation, Australia, 2005–2012
Waste-to-Energy Market: Biomass and Biogas Power Generation Forecast, Australia, FY2013, FY2035 and FY2050
Waste-to-Energy Market: Energy Consumption by Energy Type, Australia, FY2006–FY2020F
Waste-to-Energy Market: Biogas Power Generation, Australia, FY2006–FY2020F
To order this report: Strategic Analysis of the Australian Waste-to-Energy Market
http://www.reportlinker.com/p01936432/Strategic-Analysis-of-the-Australian-Waste-to-Energy-Market.html#utm_source=prnewswire&utm_medium=pr&utm_campaign=Renewable_energy
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