A. James Clark School of Engineering

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The collections in this community comprise faculty research works, as well as graduate theses and dissertations.

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    A Potential Flow Model of a Fire Sprinkler Head
    (2014) Myers, Taylor Macks; Marshall, Andre W; Fire Protection Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Understanding fire sprinkler sprays fills a critical gap in the modeling of fire suppression systems. Previous research has shown that a modeling framework consisting of an instability model coupled with a stochastic transport model can paint most of the sprinkler spray picture, but requires input in the form of the thickness and velocity of unstable fluid sheets. The model outlined forgoes traditional CFD to solve for water jet-deflector interactions, and instead describes the sheet formation as a potential flow boundary value problem, utilizing a free surface formulation and the superposition of the Green's function. The resulting model allows for the determination of the complete flow field over a fire sprinkler head of arbitrary geometry and input conditions. A hypothetical axisymmetric sprinkler is explored to provide insight into the impact of sprinkler head geometry on local fluid as well as complete spray behavior. The resulting flow splits, sheet thicknesses, and sheet velocities are presented for various sprinkler head geometries.
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    ADVANCES IN CHARACTERIZING FIRE SPRINKLER SPRAYS
    (2010) Ren, Ning; Marshall, André W; Mechanical Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Knowledge of the initial spray characteristics of sprinklers is critical for fire suppression performance analysis. Although numerous tests and studies have been conducted on fire sprinkler sprays, measurements were mostly conducted in the far-field due to spray diagnostics limitations. Although these far-field measurements are useful for evaluating the ultimate sprinkler performance, they are convoluted by the dispersion process and yield little useful information regarding the initial sprinkler discharge characteristics. With the development of advanced non-intrusive spray diagnostics, high fidelity initial spray measurements are possible, providing sprinkler discharge characteristics which are useful alone for nozzle development or together with analytical tools for prediction of suppression performance. In this study, a laser diagnostic technique based on Shadowgraphy was used to characterize the initial spray for actual fire sprinklers and nozzles having more basic configurations. The shadowgraphs revealed important information on the effect of nozzle geometry on sheet formation (from the injected jet) and sheet fragmentation into drops. Three breakup modes were observed depending on the injection conditions quantified through the We and the geometric details of the nozzle. Based on these breakup modes, scaling laws were developed to quantify the effect of nozzle geometry and injection condition on sheet breakup distance and drop size. The sheet breakup location followed a We -1/3 power law for all observed breakup modes. However, drop sizes followed a We -1/3 power law only for the ligament breakup mode which was observed to occur at very high We (We > 104). The shadowgraphs also provided spatially resolved measurements of drop size and velocity on a hemisphere 0.3 m away from the nozzle. Based on these detailed measurements, a comprehensive spray initiation model was developed for the purpose of providing a high fidelity analytical description of the initial spray useful for spray modeling. A simple dispersion analysis, accounting only for drag forces on the droplet in a quiescent environment, was performed to compare with volume density measurements taken 1 m below the sprinkler. Predicted and measured volume densities compared favorably providing some validation of the initial spray measurements and simple dispersion analysis.
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    Analysis of the initial spray from canonical fire suppression nozzles
    (2007-08-10) Ren, Ning; Marshall, André W; Fire Protection Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The performance of a fire suppression spray is governed by injector discharge characteristics. An atomization model based on the theoretical evolution of a radially expanding sheet generated by an impinging jet has been established in this study. The atomization model predicts characteristic initial drop location, size, and velocity based on injector operating conditions and geometry. These model predictions have been compared with measured discharge characteristics from three nozzle configurations of increasing geometrical complexity over a range of operating conditions. Differences between the predicted and measured initial spray are critically evaluated based on the experimentally observed atomization behavior.
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    Discharge Characteristics of Canonical Sprinkler Sprays
    (2007-04-05) Blum, Andrew; Marshall, Andre; Fire Protection Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Detailed characterization of spray behavior and its relationship to nozzle geometry, fluid properties, and injection characteristics is needed to advance water-based suppression technology and fire related computational fluid dynamics (CFD) tools. In this study, a series of experiments have been conducted to measure discharge characteristics of sprays produced by basic injector configurations modeled after conventional pendant sprinklers. Liquid jets of various sizes were injected downwards onto flat deflectors, tined deflectors, and boss-modified tined deflectors to establish the three canonical configurations explored in this study. Spray measurements including the initial angle of the sheet at the deflector exit, the sheet breakup radius, the drop size distribution 1 m below the deflector surface, and the volume density distribution were performed for these configurations. These systematic experiments provide discharge characteristics of practical interest while providing valuable data for CFD based atomization model development.