Cofiring
Home Up Combustion Properties Physical Properties Cofiring

 

 


 

Experimental Highlight
Burnout Experimental Highlight
Summary of Guidelines
Available Biomass
Inorganic Properties
Ash Management
Ash Deposition
NOx Formation
Ultimate Analyses
Pollutant Issues
Burnout Issues
Kyoto Goals

 


 

Cofiring
Home Up Combustion Properties Physical Properties Cofiring

 

 


 

 Experimental Highlight
Burnout Experimental Highlight
Summary of Guidelines
Available Biomass
Inorganic Properties
Ash Management
Ash Deposition
NOx Formation
Ultimate Analyses
Pollutant Issues
Burnout Issues
Kyoto Goals

 

Cofiring
Home Up Combustion Properties Physical Properties Cofiring

 

 Experimental Highlight
Burnout Experimental Highlight
Summary of Guidelines
Available Biomass
Inorganic Properties
Ash Management
Ash Deposition
NOx Formation
Ultimate Analyses
Pollutant Issues
Burnout Issues
Kyoto Goals

Cofiring biomass with coal represents one of the nearest term and lowest cost options for CO2 reduction in the electrical power sector.  However, there are a number of critical issues associated with cofiring that require careful consideration.   These issues were identified in part by a workshop that included utilities and others involved or potentially involved in cofiring.  The following pages summarize some of the progress we have made to date on these issues.  The major subtopics are indicated in the list to the left, with most subtopics including further links to more details.  These subtopics include the formulation of a series of guidelines for cofiring biomass with coal.

Cofiring

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bulletdownloads/Slag and Refractory/Entrained Flow Gasifier Model Design PSU.doc
bulletDeposition By Reaction
bulletRate-Ratio Asymptotic Analysis of the Structure and Extinction
bullet1-D Heat transfer through the refractory and steel walls
bulletDeposition Conclusions
bulletTemplate for Electronic Submission to ACS Journals

Sponsors: Department of Energy: Biomass Power Program: National Energy Technology Laboratory (NETL)