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Instrumentation for Studying Binder Burnout in an Immobilized Plutonium Ceramic Wasteform.

DE200415006857

Publication Date	2000
Personal Author	Mitchell, M.; Herman, C.; Pugh, D.
Page Count	14
Abstract	The Plutonium Immobilization Program produces a ceramic wasteform that utilizes organic binders. Several techniques and instruments were developed to study binder burnout on full size ceramic samples in a production environment. This approach provides a method for developing process parameters on production scale to optimize throughput, product quality, offgas behavior, and plant emissions. These instruments allow for offgas analysis, large-scale TGA, product quality observation, and thermal modeling. Using these tools, results from lab-scale techniques such as laser dilametry studies and traditional TGA/DTA analysis can be integrated. Often, the sintering step of a ceramification process is the limiting process step that controls the production throughput. Therefore, optimization of sintering behavior is important for overall process success. Furthermore, the capabilities of this instrumentation allows better understanding of plant emissions of key gases: volatile organic compounds (VOCs), volatile inorganics including some halide compounds, NO(sub x), SO(sub x), carbon dioxide, and carbon monoxide.
Keywords	Ceramics Radioactive waste management Binders Burnout Carbon dioxide Carbon monoxide Gases Halides Lasers Plutonium Production Simulation Sintering Waste forms Optimization Organic compounds Ceramic wasteforms Binder burnout
Source Agency	Technical Information Center Oak Ridge Tennessee
Corporate Authors	Lawrence Livermore National Lab., CA.; Department of Energy, Washington, DC.
Supplemental Notes	Sponsored by Department of Energy, Washington, DC.
Document Type	Technical Report
NTIS Issue Number	200416

Instrumentation for Studying Binder Burnout in an Immobilized Plutonium Ceramic Wasteform.

Instrumentation for Studying Binder Burnout in an Immobilized Plutonium Ceramic Wasteform.
DE200415006857

Publication Date	2000
Personal Author	Mitchell, M.; Herman, C.; Pugh, D.
Page Count	14
Abstract	The Plutonium Immobilization Program produces a ceramic wasteform that utilizes organic binders. Several techniques and instruments were developed to study binder burnout on full size ceramic samples in a production environment. This approach provides a method for developing process parameters on production scale to optimize throughput, product quality, offgas behavior, and plant emissions. These instruments allow for offgas analysis, large-scale TGA, product quality observation, and thermal modeling. Using these tools, results from lab-scale techniques such as laser dilametry studies and traditional TGA/DTA analysis can be integrated. Often, the sintering step of a ceramification process is the limiting process step that controls the production throughput. Therefore, optimization of sintering behavior is important for overall process success. Furthermore, the capabilities of this instrumentation allows better understanding of plant emissions of key gases: volatile organic compounds (VOCs), volatile inorganics including some halide compounds, NO(sub x), SO(sub x), carbon dioxide, and carbon monoxide.
Keywords	Ceramics Radioactive waste management Binders Burnout Carbon dioxide Carbon monoxide Gases Halides Lasers Plutonium Production Simulation Sintering Waste forms Optimization Organic compounds Ceramic wasteforms Binder burnout
Source Agency	Technical Information Center Oak Ridge Tennessee
Corporate Authors	Lawrence Livermore National Lab., CA.; Department of Energy, Washington, DC.
Supplemental Notes	Sponsored by Department of Energy, Washington, DC.
Document Type	Technical Report
NTIS Issue Number	200416