论文信息 - Independent technical support for the frozen soil barrier installation and operation at the Fukushima Daiichi Nuclear Power Station (F1 Site)

Independent technical support for the frozen soil barrier installation and operation at the Fukushima Daiichi Nuclear Power Station (F1 Site)

TEPCO is implementing a number of water countermeasures to limit the releases and impacts of contaminated water to the surrounding environment. The diverse countermeasures work together in an integrated manner to provide different types, and several levels, of protection. In general, the strategy represents a comprehensive example of a “defense in depth” concept that is used for nuclear facilities around the world. One of the key countermeasures is a frozen soil barrier encircling the damaged reactor facilities. The frozen barrier is intended to limit the flow of water into the area and provide TEPCO the ability to reduce the amount of contaminated water that requires treatment and storage. The National Laboratory team supports the selection of artificial ground freezing and the incorporation of the frozen soil barrier in the contaminated water countermeasures -- the technical characteristics of a frozen barrier are relatively well suited to the Fukushima-specific conditions and the need for inflow reduction. Further, our independent review generally supports the TEPCO/Kajima design, installation strategy and operation plan.

Michael J. Truex | Brian B. Looney | Christian D. Johnson | Dennis G. Jackson

[1] F. H. Sayles,et al. Thermal and rheological computations for artificially frozen ground construction , 1979 .

[2] E. L. Long,et al. Cryogenic Barrier Demonstration Project. Final report , 2000 .

[3] A.P.S. Selvadurai,et al. Computational modelling of frost heave induced soil–pipeline interaction: II. Modelling of experiments at the Caen test facility , 1999 .

[4] Jean-François Thimus,et al. Investigation of Water to Ice Phase Change in Porous Media by Ultrasonic and Dielectric Measurements , 2009 .

[5] A. R. Jumikis. Cryogenic Texture and Strength Aspects of Artificially Frozen Soils , 1979 .

[6] Anthony J. Gow,et al. Effect of Freezing and Thawing on the Permeability and Structure of Soils , 1979 .

[7] Å. Melinder. Thermophysical Properties of Aqueous Solutions Used as Secondary Working Fluids , 2007 .

[8] V. Loon. Heat and mass transfer in frozen porous media , 1991 .

[9] Anna M. Wagner,et al. Demonstration of an artificial frozen barrier , 2012 .

[10] A. G. Razaqpur,et al. Frost-induced deformations and stresses in pipelines , 1996 .

[11] J. Dash,et al. Ice technology for hazardous waste management , 1991 .

[12] Aleksey Y. Sheshukov,et al. Frozen barrier evolution in saturated porous media , 2002 .

[13] Megan Rose Roworth,et al. Understanding the effect of freezing on rock mass behaviour as applied to the Cigar Lake mining method , 2013 .