Development of an Alternative Glass Formulation for Vitrification of Excess Plutonium

Vitrification of HLW Produced by Uranium/Molybdenum Fuel Reprocessing in COGEMA’s Cold Crucible Melter

9th ASME International Conference on Radioactive Waste Management and Environmental Remediation: Volumes 1, 2, and 3 ◽

10.1115/icem2003-4594 ◽

2003 ◽

Cited By ~ 7

Author(s):

R. Do Quang ◽

V. Petitjean ◽

F. Hollebecque ◽

O. Pinet ◽

T. Flament ◽

...

Keyword(s):

Atomic Energy Commission ◽

Liquid Waste ◽

Glass Layer ◽

Cold Crucible ◽

High Level Liquid Waste ◽

Process Waste ◽

Glass Formulation ◽

High Level ◽

Fuel Reprocessing ◽

High Frequency Induction

The performance of the vitrification process currently used in the La Hague commercial reprocessing plants has been continuously improved during more than ten years of operation. In parallel COGEMA (industrial Operator), the French Atomic Energy Commission (CEA) and SGN (respectively COGEMA’s R&D provider and Engineering) have developed the cold crucible melter vitrification technology to obtain greater operating flexibility, increased plant availability and further reduction of secondary waste generated during operations. The cold crucible is a compact water-cooled melter in which the radioactive waste and the glass additives are melted by direct high frequency induction. The cooling of the melter produces a soldified glass layer that protects the melter’s inner wall from corrosion. Because the heat is transferred directly to the melt, high operating temperatures can be achieved with no impact on the melter itself. COGEMA plans to implement the cold crucible technology to vitrify high level liquid waste from reprocessed spent U-Mo-Sn-Al fuel (used in gas cooled reactor). The cold crucible was selected for the vitrification of this particularly hard-to-process waste stream because it could not be reasonably processed in the standard hot induction melters currently used at the La Hague vitrification facilities: the waste has a high molybdenum content which makes it very corrosive and also requires a special high temperature glass formulation to obtain sufficiently high waste loading factors (12% in molybednum). A special glass formulation has been developed by the CEA and has been qualified through lab and pilot testing to meet standard waste acceptance criteria for final disposal of the U-Mo waste. The process and the associated technologies have been also being qualified on a full-scale prototype at the CEA pilot facility in Marcoule. Engineering study has been integrated in parallel in order to take into account that the Cold Crucible should be installed remotely in one of the R7 vitrification cell. This paper will present the results obtained in the framework of these qualification programs.

Download Full-text

Technical Status Report: Preliminary Glass Formulation Report for INEEL HAW

10.2172/653917 ◽

1998 ◽

Author(s):

D. Peeler ◽

I. Reamer ◽

J. Vienna ◽

J.A. Crum

Keyword(s):

Status Report ◽

Technical Status ◽

Glass Formulation

Download Full-text

A Study on the Vitrification Tests of the Low Level Radioactive Wastes Using Plasma Arc Melter System

12th International Conference on Nuclear Engineering, Volume 2 ◽

10.1115/icone12-49060 ◽

2004 ◽

Author(s):

Boo Ho Yoon ◽

Jae Hak Cho ◽

Sang Chul Lee ◽

Dong Woo Kang ◽

Yong Joon Choi ◽

...

Keyword(s):

Compressive Strength ◽

Nuclear Power ◽

Power Plants ◽

Radioactive Wastes ◽

Plasma Arc ◽

Micro Hardness ◽

Radioactive Materials ◽

Low Level ◽

Glass Density ◽

Glass Formulation

For the research on the vitrification of the low-level radioactive wastes (LLRW) produced in nuclear power plants, one pilot plant with plasma arc melter system was built and several tests were done on it. Some surrogate wastes, which were spiked with several materials and were made very similar to the real LLRW, were used for these tests. For the vitrification of the surrogate wastes, the surrogate wastes were classified into the combustible, the non-combustible and the resin. Then each waste was spiked with special materials and was melted in separate. Off-gases produced in each test were picked up and analyzed. Real radioactive materials cesium (Cs) and cobalt (Co) were spiked in each wastes. Data gained from the final glass formulation were follows. Glass density is 2.42 ∼ 2.95(g/cm3), the compressive strength is 30 ∼ 175 Mpa, micro hardness is 5.5 ∼ 5.8 Gpa. The leaching ratio for Co is 1.27×10−4 ∼ 1.08×10−3 (10mL/g) and that for Cs is 2.46×10−3 ∼ 3.23×10−2 (10mL/g). The leaching speed for Co is 4.14×10−7 ∼ 5.53×10−6 (g/m2) and that for Cs is 4.58×10−5 ∼ 3.87×10−4 (g/m2). In off-gas, dioxin & furan is 0.016 mano gram on the average, CO is about 20 ppm, NO2 is about 15 ppm and SO2 is about 15 ppm.

Download Full-text

High Waste Loading Glass Formulations for Hanford High-Aluminum High-Level Waste Streams

ASME 2011 14th International Conference on Environmental Remediation and Radioactive Waste Management, Parts A and B ◽

10.1115/icem2011-59388 ◽

2011 ◽

Author(s):

Albert A. Kruger

Keyword(s):

Previous Experience ◽

High Level Waste ◽

Waste Streams ◽

Testing Program ◽

Glass Formulation ◽

Waste Loading ◽

Production Requirement ◽

High Level ◽

Glass Compositions ◽

High Aluminum

The current estimates and glass formulation efforts have been conservative in terms of achievable waste loadings. These formulations have been specified to ensure that the glasses are homogenous, contain essentially no crystalline phases, are processable in joule-heated, ceramic-lined melters and meet WTP Contract terms. The WTP’s overall mission will require the immobilization of tank waste compositions that are dominated by mixtures of aluminum (Al), chromium (Cr), bismuth (Bi), iron (Fe), phosphorous (P), zirconium (Zr), and sulfur (S) compounds as waste-limiting components. Glass compositions for these waste mixtures have been developed based upon previous experience and current glass property models. Recently, DOE has initiated a testing program to develop and characterize HLW glasses with higher waste loadings. Results of this work have demonstrated the feasibility of increases in waste loading from about 25 wt% to 33–50 wt% (based on oxide loading) in the glass depending on the waste stream. It is expected that these higher waste loading glasses will reduce the HLW canister production requirement by about 25% or more.

Download Full-text

Vitrification of borate waste from nuclear power plant using coal fly ash. (I) Glass formulation development

Fuel and Energy Abstracts ◽

10.1016/s0140-6701(02)85737-x ◽

2002 ◽

Vol 43 (3) ◽

pp. 188

Keyword(s):

Fly Ash ◽

Power Plant ◽

Nuclear Power Plant ◽

Nuclear Power ◽

Coal Fly Ash ◽

Formulation Development ◽

Glass Formulation

Download Full-text

Glass Formulation Development in Support of Melter Testing to Demonstrate Enhanced High Level Waste Throughput

MRS Proceedings ◽

10.1557/proc-1107-231 ◽

2008 ◽

Vol 1107 ◽

Cited By ~ 6

Author(s):

James C. Marra ◽

Kevin M. Fox ◽

David K. Peeler ◽

Thomas B. Edwards ◽

Amanda L. Youchak ◽

...

Keyword(s):

Product Quality ◽

Department Of Energy ◽

High Alumina ◽

High Level Waste ◽

Alumina Concentration ◽

Formulation Development ◽

Technology Innovations ◽

Glass Formulation ◽

Waste Loading ◽

High Level

AbstractThe U.S. Department of Energy (DOE) is currently processing high-level waste (HLW) through a Joule-heated melter (JHM) at the Savannah River Site (SRS) and plans to vitrify HLW and Low activity waste (LAW) at the Hanford Site. Over the past few years at the Defense Waste Processing Facility (DWPF), work has concentrated on increasing waste throughput. These efforts are continuing with an emphasis on high alumina concentration feeds. High alumina feeds have presented specific challenges for the JHM technology regarding the ability to increase waste loading yet still maintain product quality and adequate throughput. Alternatively, vitrification technology innovations are also being investigated as a means to increase waste throughput. The Cold Crucible Induction Melter (CCIM) technology affords the opportunity for higher vitrification process temperatures as compared to the current reference JHM technology. Higher process temperatures may allow for higher waste loading and higher melt rate.Glass formulation testing to support melter demonstration testing was recently completed. This testing was specifically aimed at high alumina concentration wastes. Glass composition/property models developed for DWPF were utilized as a guide for formulation development. Both CCIM and JHM testing will be conducted so glass formulation testing was targeted at both technologies with a goal to significantly increase waste loading and maintain melt rate without compromising product quality.

Download Full-text

Initial Investigation Into the Vitrification of High Molybdenum Solids in Borosilicate Glass

MRS Proceedings ◽

10.1557/proc-1193-291 ◽

2009 ◽

Vol 1193 ◽

Cited By ~ 2

Author(s):

Barbara F. Dunnett ◽

Nick R. Gribble ◽

Andrew D. Riley ◽

Carl J. Steele

Keyword(s):

Phase Separation ◽

Borosilicate Glass ◽

Spent Nuclear Fuel ◽

Storage Tanks ◽

Waste Storage ◽

Waste Vitrification ◽

Durability Testing ◽

Glass Formulation ◽

Selection Of ◽

Scanning Electron

AbstractSellafield Ltd operates a Waste Vitrification Plant (WVP) to immobilise the arisings from the reprocessing of spent nuclear fuel. Washout of solids from the base of waste storage tanks in preparation for decommissioning is likely to produce feeds enriched in molybdenum to the WVP. Vitrification of such feeds in the borosilicate glass formulation currently used by the WVP for vitrification of reprocessing waste has been investigated to determine the maximum achievable loading of MoO3.The vitrification of molybdenum in the absence and presence of reprocessing waste was studied. A number of glasses were manufactured in the laboratory containing various waste loadings. The resultant glasses were examined both visually and under the scanning electron microscope for the presence of any phase separation. Additional aluminium was added to the glasses manufactured in the absence of reprocessing waste to improve the durability of the glass. In borosilicate glass containing 3.5 wt% Al2O3 the onset of a molybdenum phase separation was observed in glasses containing 2.6 wt% MoO3. In the presence of Magnox reprocessing waste, phase separation was observed when the product contained >3.8 wt% MoO3. Soxhlet durability testing of a selection of the glasses manufactured was carried out. The Soxhlet durability of glasses in the absence of phase separation was good.

Download Full-text