Roberts et al., 2018 - Google Patents
Investigating the impact of an Al-Si additive on the resistivity of biomass ashesRoberts et al., 2018
View HTML- Document ID
- 16828928416183438413
- Author
- Roberts L
- Mason P
- Jones J
- Gale W
- Williams A
- Ellul C
- Publication year
- Publication venue
- Fuel Processing Technology
External Links
Snippet
Ash resistivity is an important factor in the collection efficiency of electrostatic precipitators (ESPs). There is good experience in the industry regarding resistivity of coal fly ash and well- established models for its prediction based on coal ash composition. The same is not true for …
- 239000002956 ash 0 title abstract description 131
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Heinzel et al. | Investigation of slagging in pulverized fuel co-combustion of biomass and coal at a pilot-scale test facility | |
| Ninomiya et al. | Influence of coal particle size on particulate matter emission and its chemical species produced during coal combustion | |
| Li et al. | Study on ash fusion temperature using original and simulated biomass ashes | |
| Roberts et al. | Investigating the impact of an Al-Si additive on the resistivity of biomass ashes | |
| Zhou et al. | Effect of ash composition on the partitioning of arsenic during fluidized bed combustion | |
| Diaz-Somoano et al. | Prediction of trace element volatility during co-combustion processes | |
| Miller et al. | Trace element emissions from co-combustion of secondary fuels with coal: a comparison of bench-scale experimental data with predictions of a thermodynamic equilibrium model | |
| Pedersen et al. | A full-scale study on the partitioning of trace elements in municipal solid waste incineration Effects of firing different waste types | |
| Zhao et al. | Enrichment characteristics, thermal stability and volatility of hazardous trace elements in fly ash from a coal-fired power plant | |
| Meij et al. | Trace elements in world steam coal and their behaviour in Dutch coal-fired power stations: a review | |
| Chen et al. | Partitioning of trace elements in coal combustion products: A comparative study of different applications in China | |
| Jaworek et al. | Properties of biomass vs. coal fly ashes deposited in electrostatic precipitator | |
| Mu et al. | Influence of ignition process on mineral phase transformation in municipal solid waste incineration (MSWI) fly ash: Implications for estimating loss-on-ignition (LOI) | |
| Quick et al. | Trace element partitioning during the firing of washed and untreated power station coals | |
| Han et al. | Distribution and emissions of trace elements in coal-fired power plants after ultra-low emission retrofitting | |
| Zheng et al. | Measurement and prediction of fly ash resistivity over a wide range of temperature | |
| Ahn et al. | Physical, chemical, and electrical analysis of aerosol particles generated from industrial plants | |
| Liu et al. | Particle size distributions of fly ash arising from vaporized components of coal combustion: A comparison of theory and experiment | |
| Ouyang et al. | Effect of the coal preparation process on mercury flows and emissions in coal combustion systems | |
| Zhang et al. | Temperature effect on central-mode particulate matter formation in combustion of coals with different mineral compositions | |
| James et al. | Modeling trace element partitioning during coal combustion | |
| Zhang et al. | Concentration, enrichment, and partitioning behavior of heavy metals in ash from a down-fired furnace burning anthracite coal | |
| Singh et al. | An experimental study of ash behaviour and the potential fate of ZnO/Zn in the Co-combustion of pulverised South African coal and waste tyre rubber | |
| Agarwal et al. | Comparing and interpreting laboratory results of Hg oxidation by a chlorine species | |
| Wils et al. | Reduction of fuel side costs due to biomass co-combustion |