(216d) Hydrogen Generation in Testing to Support Chemical Processing of High Level Radioactive Waste in the Savannah River Site's Defense Waste Processing Facility | AIChE

(216d) Hydrogen Generation in Testing to Support Chemical Processing of High Level Radioactive Waste in the Savannah River Site's Defense Waste Processing Facility

Authors 

Click, D. R. - Presenter, Savannah River National Laboratory
Hobbs, D. T. - Presenter, Savannah River National Laboratory
Crapse, K. P. - Presenter, Savannah River National Laboratory


The radioactive startup of two new SRS processing facilities at the Savannah River Site (SRS), the Actinide Removal Process (ARP) and the Modular Caustic-Side-Solvent-Extraction Unit (MCU) will add two new waste streams to the Defense Waste Processing Facility (DWPF). The ARP will remove actinides from the 5.6 M salt solution resulting in a sludge-like product that is roughly half monosodium titanate (MST) insoluble solids and half sludge insoluble solids. The ARP product will be added to the Sludge Receipt and Adjustment Tank (SRAT) at boiling and dewatered prior to pulling a SRAT receipt sample. The cesium rich MCU stream will be added to the SRAT at boiling after both formic and nitric acid have been added and the SRAT contents concentrated to the appropriate endpoint.

A concern was raised by an external hydrogen review panel that the actinide loaded MST could act as a catalyst for hydrogen generation (Mar 15, 2007 report, Recommendation 9). Hydrogen generation, and it's potential to form a flammable mixture in the off-gas, under SRAT and Slurry Mix Evaporator (SME) processing conditions has been a concern since the discovery that noble metals catalyze the decomposition of formic acid. Radiolysis of water also generates hydrogen, but the radiolysis rate is orders of magnitude lower than the potential noble metal catalyzed generation. As a result of the concern raised by the external hydrogen review panel, hydrogen generation was a prime consideration in this experiment. Testing was designed to determine whether the presence of the irradiated ARP simulant containing MST caused uncontrolled or unexpected hydrogen production during experiments simulating the DWPF Chemical Process Cell (CPC) due to activation of titanium.

A radioactive demonstration was completed in the SRS Shielded Cells facility using SB4 sludge combined with an ARP product produced from simulants by SRNL researchers. The blend was designed to be prototypic of planned DWPF SRAT and SME cycles. The results from this experiment will be compared to the results from experiment SC-1, a similar experiment with SB4 sludge without added ARP product.