Publications

The overall goal of this work was to improve the modeling of laboratory shock and vibration testing. Laboratory shock and vibration testing is used to qualify Nuclear Weapon components for the environment they will experience in the field. Standard practice is to use rigid test fixtures so that no spurious modes are introduced during laboratory testing. Rigid test fixtures may however in some cases change the dynamics of the component being tested, resulting in laboratory testing being more severe than what would occur in the field.

The overall goal of this work was to improve the modeling of laboratory shock and vibration testing. Laboratory shock and vibration testing is used to qualify Nuclear Weapon components for the environment they will experience in the field. Standard practice is to use rigid test fixtures so that no spurious modes are introduced during laboratory testing. Rigid test fixtures may however in some cases change the dynamics of the component being tested, resulting in laboratory testing being more severe than what would occur in the field. This milestone investigated the use of topology optimization to create laboratory test fixtures that would better replicate the dynamics that components experience in field environments.

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The Yucca Mountain Project, managed by the U.S. Department of Energy, is examining the feasibility of siting a repository for high-level nuclear waste at Yucca Mountain on and adjacent to the Nevada Test Site. As part of the site characterization, a series of in situ thermomechanical experiments are planned, which are to be conducted in the Exploratory Studies Facility (ESF). In this report, the results of preliminary analyses of three of the in situ thermomechanical experiments are presented. The major objective of these analyses was to determine the boundaries of the thermally perturbed zones surrounding each of the experiments. The boundaries of the thermal zones needs to be known in order to avoid test interference between the experiments planned for the ESF. A second objective of these analyses was to calculate the displacements and stresses associated with the experiments, in order to advance the planning of the experiments.

In situ design verification activities are being conducted in the North Ramp Starter Tunnel of the Yucca Mountain Project Exploratory Studies Facility. These activities include: monitoring the construction blasting, evaluating the damage to the rock mass associated with construction, assessing the rock mass quality surrounding the tunnel, monitoring the performance of the installed ground support, and monitoring the stability of the tunnel. In this paper, examples of the data that have been collected and preliminary conclusions from the data are presented.

In situ thermomechanical experiments are planned as part of the Yucca Mountain Site Characterization Project that require instruments to measure stress and displacement at temperatures that exceed the typical specifications of existing geotechnical instruments. A high degree of instrument reliability will also be required to satisfy the objectives of the experiments, therefore a study was undertaken to identify areas where improvement in instrument performance was required. A preliminary list of instruments required for the experiments was developed, based on existing test planning and analysis. Projected temperature requirements were compared to specifications of existing instruments to identify instrumentation development needs. Different instrument technologies, not currently employed in geotechnical instrumentation, were reviewed to identify potential improvements of existing designs for the high temperature environment. Technologies with strong potentials to improve instrument performance with relatively high reliability include graphite fiber composite materials, fiber optics, and video imagery.