Properties of radioactive wastes and waste containers. Quarterly progress report, January-March 1980

Solidification experiments were performed with organic ion-exchange resins using Portland type II cement to investigate waste to binder ratios which result in monolithic waste forms. Test results are provided in tabular form showing formulations which result in considerable swelling, cracking, or sp...

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Bibliographic Details
Main Authors: Manaktala, H.K., Weiss, A.J.
Language:unknown
Published: 2013
Subjects:
12 MANAGEMENT OF RADIOACTIVE AND NON-RADIOACTIVE WASTES FROM NUCLEAR FACILITIES
LOW-LEVEL RADIOACTIVE WASTES
SOLIDIFICATION
WASTE FORMS
RESEARCH PROGRAMS
BORIC ACID
EXPERIMENTAL DATA
FORMALDEHYDE
ION EXCHANGE MATERIALS
PHASE DIAGRAMS
PORTLAND CEMENT
RESINS
SODIUM HYDROXIDES
UREA
ALDEHYDES
ALKALI METAL COMPOUNDS
AMIDES
BUILDING MATERIALS
CARBONIC ACID DERIVATIVES
CEMENTS
DATA
DIAGRAMS
HYDROGEN COMPOUNDS
HYDROXIDES
INFORMATION
INORGANIC ACIDS
MATERIALS
NUMERICAL DATA
ORGANIC COMPOUNDS
ORGANIC NITROGEN COMPOUNDS
ORGANIC POLYMERS
OXYGEN COMPOUNDS
PETROCHEMICALS
PETROLEUM PRODUCTS
PHASE TRANSFORMATIONS
POLYMERS
RADIOACTIVE MATERIALS
RADIOACTIVE WASTES
SODIUM COMPOUNDS
WASTES
Monolith
Carbonic acid
Online Access:http://www.osti.gov/servlets/purl/5064936
https://www.osti.gov/biblio/5064936
https://doi.org/10.2172/5064936
Description
Summary:Solidification experiments were performed with organic ion-exchange resins using Portland type II cement to investigate waste to binder ratios which result in monolithic waste forms. Test results are provided in tabular form showing formulations which result in considerable swelling, cracking, or splitting of the specimens upon solidification. The range of waste loadings which produce monolithic waste forms is given. Experiments were conducted to establish appropriate waste/binder ratios within which simulated boric acid reactor waste may be incorporated into portland type III cement, to produce acceptable waste forms. Both pH-adjusted and pH-unadjusted boric acid solutions were used. Sodium hydroxide in solid pellet form was used to adjust the boric acid pH. Data are reported for 3, 6, and 12 weight percent boric acid wastes, with pH-adjusted values of 7, 10, and 12. Range of waste/binder ratios investigated is from 0.32 to 1.5. Results are summarized in the form of ternary compositional phase diagrams depicting envelope boundaries within which formulations exhibit no free standing liquids. The cure time is substantially reduced when NaOH pellets are used, rather than 10 M NaOH solution. This is attributed to the higher solid contents in the waste solution when NaOH in solid form is used. A ''two-part'' urea-formaldehyde process was used to solidify four simulated LWR waste streams, viz. ion-exchange bead resins, diatomaceous earth, sodium sulfate, and boric acid wastes. The waste forms were evaluated on the basis of solid monolith, free standing liquid, corrosivity of the free liquids, and specimen shrinkage criteria. The results show that the two-part urea-formaldehyde process (a) is capable of solidifying LWR low-level wastes into solid free-standing monoliths, (b) produces free-standing water with pH approximately 2, and (c) produces specimen shrinkage of approximately 5 volume percent after four weeks in an enclosed environment.

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