Publications

Luxat, David L.; Dodd, Amanda B.; Urbina, Angel U.; Strack, Otto E.

Abstract not provided.

Dodd, Amanda B.; Domino, Stefan P.

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Scott, Sarah N.; Kury, Matthew W.; Keedy, Ryan M.; Brunini, Victor B.; Dodd, Amanda B.; Urban, James L.; Fernandez-Pello, Carlos F.

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Scott, Sarah N.; Keedy, Ryan M.; Brunini, Victor B.; Dodd, Amanda B.; Urban, James L.; Fernandez-Pello, A.C.

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Scott, Sarah N.; Keedy, Ryan M.; Brunini, Victor B.; Kury, Matthew W.; Dodd, Amanda B.; Urban, James L.; Fernandez-Pello, A C.

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Hewson, John C.; Lopez Mestre, Carlos L.; Dodd, Amanda B.

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Scott, Sarah N.; Dodd, Amanda B.; Brunini, Victor B.; Keedy, Ryan M.

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Scott, Sarah N.; Dodd, Amanda B.; Brunini, Victor B.; Keedy, Ryan M.

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10th U.S. National Combustion Meeting

Scott, Sarah N.; Keedy, Ryan M.; Brunini, Victor B.; Dodd, Amanda B.

Polymer foam encapsulants provide mechanical, electrical, and thermal isolation in engineered systems. In fire environments, gas pressure from thermal decomposition of polymers can cause mechanical failure of sealed systems. A 3-D finite element conduction-radiation model with porous media flow and a chemistry model was created to investigate the heat transfer and pressurization in such scenarios. Experiments show that the rate of pressurization and the temperature of select thermocouples are dependent on orientation with respect to gravity, indicating buoyancy-driven flow. In this work, the gas velocity is solved by applying the Darcy approximation, and the heat transfer and pressurization are determined by solving the continuity, species, and enthalpy equations in the condensed and gas phases. This work will describe the porous media model, explore material parameters (e.g. phase, permeability, conductivity) for use with PMDI polyurethane, compare predictions to experimental data, and recommend values for material properties. It will use multiple heating rates to validate the data, and show that incorporating gas motion into the model captures the divergent nature of the results in different orientations.

Dodd, Amanda B.; Lamb, Joshua H.; Hewson, John C.; Ferreira, Summer R.

Abstract not provided.

Kopacz, Adrian M.; Bozinoski, Radoslav B.; Hewson, John C.; Dodd, Amanda B.; Brown, Alexander B.; Voskuilen, Tyler V.

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Dodd, Amanda B.

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Kopacz, Adrian M.; Bozinoski, Radoslav B.; Hewson, John C.; Dodd, Amanda B.; Brown, Alexander B.

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Fire Technology

Scott, Sarah N.; Dodd, Amanda B.; Larsen, Marvin E.; Suo-Anttila, Jill M.; Erickson, Ken L.

Polymer foam encapsulants provide mechanical, electrical, and thermal isolation in engineered systems. It can be advantageous to surround objects of interest, such as electronics, with foams in a hermetically sealed container in order to protect them from hostile environments or from accidents such as fire. In fire environments, gas pressure from thermal decomposition of foams can cause mechanical failure of sealed systems. In this work, a detailed uncertainty quantification study of polymeric methylene diisocyanate (PMDI)-polyether-polyol based polyurethane foam is presented and compared to experimental results to assess the validity of a 3-D finite element model of the heat transfer and degradation processes. In this series of experiments, 320 kg/m3 PMDI foam in a 0.2 L sealed steel container is heated to 1,073 K at a rate of 150 K/min. The experiment ends when the can breaches due to the buildup of pressure. The temperature at key location is monitored as well as the internal pressure of the can. Both experimental uncertainty and computational uncertainty are examined and compared. The mean value method (MV) and Latin hypercube sampling (LHS) approach are used to propagate the uncertainty through the model. The results of the both the MV method and the LHS approach show that while the model generally can predict the temperature at given locations in the system, it is less successful at predicting the pressure response. Also, these two approaches for propagating uncertainty agree with each other, the importance of each input parameter on the simulation results is also investigated, showing that for the temperature response the conductivity of the steel container and the effective conductivity of the foam, are the most important parameters. For the pressure response, the activation energy, effective conductivity, and specific heat are most important. The comparison to experiments and the identification of the drivers of uncertainty allow for targeted development of the computational model and for definition of the experiments necessary to improve accuracy.

Brunini, Victor B.; Keedy, Ryan M.; Scott, Sarah N.; Noble, David R.; Dodd, Amanda B.

Abstract not provided.

Keedy, Ryan M.; Dodd, Amanda B.; Brunini, Victor B.; Scott, Sarah N.

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Scott, Sarah N.; Dodd, Amanda B.

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Black, Amalia R.; Romero, Vicente J.; Breivik, Nicole L.; Orient, George E.; Suo-Anttila, Jill M.; Antoun, Bonnie R.; Dodd, Amanda B.

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Romero, Vicente J.; Black, Amalia R.; Breivik, Nicole L.; Orient, George E.; Suo-Anttila, Jill M.; Antoun, Bonnie R.; Antoun, Bonnie R.; Dodd, Amanda B.

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Dodd, Amanda B.; Bohlin, Alexis; Kliewer, Christopher J.

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Fire and Materials 2015 - 14th International Conference and Exhibition, Proceedings

Kearney, S.P.; Dodd, Amanda B.; Bohlin, Alexis; Kliewer, Christopher J.

We report measurements of temperature and O2/N2 mole-fraction ratio in the vicinity of a burning and decomposing carbon-epoxy composite aircraft material samples exposed to uniform heat fluxes of 48 and 69 kW/m2. Controlled laboratory experiments were conducted with the samples suspended above a cone-type heater and enclosed in an optically accessible chimney. Noninvasive coherent anti-Stokes Raman scattering (CARS) measurements we performed on a single-laser-shot basis. The CARS data were performed with both a traditional point measurement system and with a one-dimensional line imaging scheme that provides single-shot temperature and O2/N2 profiles to reveal the quantitative structure of the temperature and oxygen concentration profiles over the duration of the 30-40 minute duration events. The measured near-surface temperature and oxygen transport are an important factor for exothermic chemistry and oxidation of char materials and the carbon fibers themselves in a fire scenario. These unique laser-diagnostic experiments provide new information on physical/chemical processes in a well-controlled environment which may be useful for the development of heat-and mass-transfer models for the composite fire scenario.

Scott, Sarah N.; Dodd, Amanda B.; Keedy, Ryan M.; Brunini, Victor B.

Abstract not provided.

Tencer, John T.; Akau, Ronald L.; Dobranich, Dean D.; Brown, Alexander B.; Dodd, Amanda B.; Hogan, Roy E.; Okusanya, Tolulope O.; Phinney, Leslie M.; Pierce, Flint P.

Thermal analysts address a wide variety of applications requiring the simulation of radiation heat transfer phenomena. The re are gaps in the currently available modeling capabilities. Addressing these gaps w ould allow for the consideration of additional physics and increase confidence in simulation predictions. This document outlines a five year plan to address the current and future needs of the analyst community with regards to modeling radiation heat tran sfer processes. This plan represents a significant multi - year effort that must be supported on an ongoing basis.

Scott, Sarah N.; Dodd, Amanda B.; Larsen, Marvin E.; Suo-Anttila, Jill M.; Erickson, Ken E.

Abstract not provided.

Dodd, Amanda B.

Abstract not provided.