Temperature measurements behind reflected shock waves in air

A radiometric method for the measurement of gas temperature in self-absorbing gases has been applied in the study of shock tube generated flows. This method involves making two absolute intensity measurements at identical wavelengths, but for two different pathlengths in the same gas sample. Experimental results are presented for reflected shock waves in air at conditions corresponding to incident shock velocities from 7 to 10 km/s and an initial driven tube pressure of 1 torr. These results indicate that, with this technique, temperature measurements with an accuracy of + or - 5 percent can be carried out. The results also suggest certain facility related problems

Description and Comparison of the Results of the Proposed House: Habitat for Humanity at Frazier Court, Dallas, Texas, with the 2004 IECC Standard Reference House

The Energy Systems Laboratory was requested to calculate the emissions reductions associated with the Habitat for Humanity Housing Project at Frazier Court, Dallas Texas. This report presents the results of the required analysis, a set of houses was compared to a corresponding standard reference house as described in the 2004 International Energy Conservation Code (2004 IECC). The energy consumption calculations were carried out using DOE-2.1e input file RES3ST.inp (Version 4.01.07) and DDP (Version: 1.7.03). Based on this comparison, the % above/below code for the proposed house was determined. The resultant emissions calculations were carried out using eCALC software (ESL, 2006). This report also contains detailed information about the description of the proposed house in terms of its building parameters, resultant energy consumption and emission reductions. Calculations are carried out using TMY2 weather file for Tarrant County, TX which is in climate zone 3 of the IECC 2004 climate zone categories. For the 1285 sq. ft. houses, the energy consumption of the Habitat for Humanity houses is in the range of 10.3% - 11.7% above code and for the 843 sq. ft. houses, the energy consumption is in the range of 20.9% - 21.4% below code. The HERS ratings calculated by IC3 is in the range of 71.7– 74.2 for the 1285 sq. ft. houses and in the range of 79.4 – 80.6 for the 843 sq. ft. houses

Introduction: resilience and the Anthropocene: the stakes of ‘renaturalising’ politics

The Anthropocene marks a new geological epoch in which human activity (and specifically Western production and consumption practices) has become a geological force. It also profoundly destabilizes the grounds of Western political philosophy. Visions of a dynamic earth system wholly indifferent to human survival liquefy modernity’s division between nature and politics. Critical thought has only begun to scratch the surface of the Anthropocene’s re-naturalization of politics. This special issue of Resilience: International Policies, Practices and Discourses explores the politics of resilience within the wider cultural and political moment of the Anthropocene. It is within the field of resilience thinking that the implications of the Anthropocene for forms of governance are beginning to be sketched out and experimental practices are undertaken. Foregrounding the Anthropocene imaginary’s re-naturalization of politics enables us to consider the political possibilities of resilience from a different angle, one that is irreducible to neoliberal post-political rule

Engineering Evaluation/Cost Analysis for Power Burst Facility (PER-620) Final End State and PBF Vessel Disposal

Preparation of this engineering evaluation/cost analysis is consistent with the joint U.S. Department of Energy and U.S. Environmental Protection Agency Policy on Decommissioning of Department of Energy Facilities Under the Comprehensive Environmental Response, Compensation, and Liability Act, (DOE and EPA 1995) which establishes the Comprehensive Environmental, Response, Compensation, and Liability Act non-time critical removal action process as an approach for decommissioning. The scope of this engineering evaluation/cost analysis is to evaluate alternatives and recommend a preferred alternative for the final end state of the PBF and the final disposal location for the PBF vessel

Numerical Coupling of Fracture and Fluid Pressure Using a Phase-Field Model with Applications in Geomechanics

The application of fracture mechanics is an increasingly important topic in fields including geophysics, geomechanics, materials engineering, structural mechanics and engineering design. The initiation and evolution of fractures in porous media often gives rise to discontinuous fields within computational problems. We compute the crack's aperture, or crack opening, by making use of the gradient of the phase-field in the damaged area. This is useful for determining the material's fluid-mechanical properties, such as the estimation of Poiseuille-type flow that occurs within a sufficiently damaged medium. Using this approach, it can be shown that the evolution of such fractures in a porous medium can contribute to the material's fluid flow characteristics, giving rise to a coupled model of fluid flow and damage within a porous solid. Using the Sierra Mechanics code suite at Sandia National Laboratories, a phase-field model of fracture is developed which will allow a loose, two-way coupling of these physics for future implementations. We find the model's ability to predict fractures initiated and propagated by introducing fluid mass to be consistent with analytical solutions. We also find that the crack openings calculated with this model will be helpful for implementing Poiseuille flow along fractures which is a valuable feature in geomechanics modeling

Engineering Evaluation/Cost Analysis for Decommissioning of the Engineering Test Reactor Complex

Preparation of this Engineering Evaluation/Cost Analysis is consistent with the joint U.S. Department of Energy and U.S. Environmental Protection Agency Policy on Decommissioning of Department of Energy Facilities Under the Comprehensive Environmental Response, Compensation, and Liability Act, which establishes the Comprehensive Environmental Response, Compensation, and Liability Act non-time-critical removal action (NTCRA) process as an approach for decommissioning