Analysis of metallurgical slags
Applications | 2019 | Thermo Fisher ScientificInstrumentation
Accurate characterization of metallurgical slags is vital for optimizing steelmaking processes. Slag composition affects impurity removal, energy consumption and the integrity of refractory linings, directly impacting product quality and operational costs.
The application note aims to evaluate the repeatability, reproducibility and detection capabilities of the Thermo Scientific ARL OPTIM’X 200 W WDXRF spectrometer configured in a sequential-simultaneous mode for analyzing key oxide and element concentrations in steelmaking slags.
Sample Preparation
Calibration was established using eight certified slag standards covering typical concentration ranges for CaO, SiO₂, Fe₂O₃, MgO, Al₂O₃, MnO, K₂O, P₂O₅, Na₂O, TiO₂, S and F. Detection limits for fluorine were comparable between the SmartGonio (537 ppm at 60 s) and fixed channel (509 ppm at 60 s), with improved precision on the fixed channel at extended counting times.
Short-term repeatability (10 consecutive runs, total counting time 270 s) yielded relative standard deviations below 0.05 % for major oxides and below 0.02 ppm for fluorine. Long-term reproducibility over 12 hours (runs every 30 min) demonstrated consistent average values with RSDs comparable to the short-term test.
The ARL OPTIM’X 200 W WDXRF enables rapid multi-element slag screening with high precision and low maintenance. Total analysis time for 12 elements can be reduced to approximately 3 minutes by optimizing counting times per element. Reliable fluorine quantification is achieved without compromising throughput.
Advances in detector technology and beam optics may further enhance sensitivity for trace elements. Integration with process analytics and real-time feedback loops could enable proactive slag chemistry control in industrial furnaces. The methodology may be extended to other complex silicate materials in metallurgical and environmental applications.
The Thermo Scientific ARL OPTIM’X 200 W sequential-simultaneous WDXRF spectrometer delivers excellent accuracy, repeatability and throughput for comprehensive slag analysis. The combination of SmartGonio and fixed-channel fluorine detection provides flexible analytical performance to meet diverse industrial quality and research requirements.
No external references were cited in the source document.
X-ray
IndustriesMaterials Testing
ManufacturerThermo Fisher Scientific
Summary
Significance of the Topic
Accurate characterization of metallurgical slags is vital for optimizing steelmaking processes. Slag composition affects impurity removal, energy consumption and the integrity of refractory linings, directly impacting product quality and operational costs.
Objectives and Study Overview
The application note aims to evaluate the repeatability, reproducibility and detection capabilities of the Thermo Scientific ARL OPTIM’X 200 W WDXRF spectrometer configured in a sequential-simultaneous mode for analyzing key oxide and element concentrations in steelmaking slags.
Methodology and Instrumentation
Sample Preparation
- Slag samples were crushed and milled to <50 μm to minimize particle size effects.
- Magnetic separation removed metallic residues prior to analysis.
- Pressed powder pellets were prepared for routine XRF measurements.
- ARL OPTIM’X WDXRF spectrometer, 200 W Rh-anode X-ray tube, no external water cooling.
- SmartGonio covering elements from F (Z=9) to U (Z=92).
- Fixed channel for parallel fluorine analysis.
- OXSAS software for multivariate regression calibration and data processing.
Main Results and Discussion
Calibration was established using eight certified slag standards covering typical concentration ranges for CaO, SiO₂, Fe₂O₃, MgO, Al₂O₃, MnO, K₂O, P₂O₅, Na₂O, TiO₂, S and F. Detection limits for fluorine were comparable between the SmartGonio (537 ppm at 60 s) and fixed channel (509 ppm at 60 s), with improved precision on the fixed channel at extended counting times.
Short-term repeatability (10 consecutive runs, total counting time 270 s) yielded relative standard deviations below 0.05 % for major oxides and below 0.02 ppm for fluorine. Long-term reproducibility over 12 hours (runs every 30 min) demonstrated consistent average values with RSDs comparable to the short-term test.
Benefits and Practical Applications
The ARL OPTIM’X 200 W WDXRF enables rapid multi-element slag screening with high precision and low maintenance. Total analysis time for 12 elements can be reduced to approximately 3 minutes by optimizing counting times per element. Reliable fluorine quantification is achieved without compromising throughput.
Future Trends and Potential Uses
Advances in detector technology and beam optics may further enhance sensitivity for trace elements. Integration with process analytics and real-time feedback loops could enable proactive slag chemistry control in industrial furnaces. The methodology may be extended to other complex silicate materials in metallurgical and environmental applications.
Conclusion
The Thermo Scientific ARL OPTIM’X 200 W sequential-simultaneous WDXRF spectrometer delivers excellent accuracy, repeatability and throughput for comprehensive slag analysis. The combination of SmartGonio and fixed-channel fluorine detection provides flexible analytical performance to meet diverse industrial quality and research requirements.
References
No external references were cited in the source document.
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