The fire growth rate of interior linings, furnishings, and construction materials is measured in full-scale fire tests such as the ASTM E84 Steiner Tunnel, the ISO 9705 room fire, and a passenger aircraft cabin as the flame spread rate, time-to-flashover, or time to incapacitation, respectively. The results are used to indicate the level of passive fire protection afforded by the combustible material or product in the test. These large-scale tests require many square meters of product, are very expensive to conduct, and can exhibit poor repeatability- making them unsuitable for product development, quality control, or product surveillance. For this reason, smaller ( 0.01 m2) samples are tested in bench-scale fire calorimeters under controlled conditions, and these one-dimensional burning histories are correlated with the results of the two- and three-dimensional burning histories in full-scale fire tests by a variety of empirical and semi-empirical fire propagation indices, as well as analytic and computer models that are particular to the full-scale fire test.
A more general approach described here equates the coupled fire growth processes of surface flame spread and in-depth burning to the generation of combustion heat in response to the radiant energy from a fire calorimeter that is above the critical value for ignition and burning. This measurement in a cone calorimeter under standard conditions (ASTM E1354) is used to compute the fire growth potential of the combustible solid, (m2/MJ), which is realized as a hazard when the heat of combustion, Hc (MJ/m2), is sufficient to grow the fire. Consequently, the dimensionless fire hazard of a material or product is obtained directly from a single cone calorimeter measurement as =Hc. The physical basis for and as well as their method of evaluation in a cone calorimeter are described. Experimental data show that the development of full-scalecompartment fires and free standing product fires correlates with as the sole explanatory variable.
Electrical odors and smoke incidents in aviation have become a pressing concern, with over half of the detector activations resulting in false alarms, leading to uncertainties for flight crews. The escalating costs of diversions and growing awareness of associated health risks underscore the need for more reliable detection and discrimination from false alarms. This study harnesses advanced multi-sensor array technologies, intelligent algorithms, and Metal Oxide Sensors (MOS) sensors equipped with AI capabilities to detect and analyze signatures from candidate internal contaminant sources located in the cockpit. Printed circuit boards from avionics, aviation cables of different insulation, and external contaminant sources were put to failure testing to analyze the early fire signatures. These signatures were subsequently assessed using clustering algorithms and multivariate analysis to pinpoint distinct markers. Comprehensive gas analysis and light obscuration measurements further characterized the environment. Experiments were executed at both the University of Maryland and the Federal Aviation Administration (FAA) Technical Center, replicating diverse conditions, including an altitude simulation of 8000 ft. The focus was on the capability to distinguish between samples during the smoldering phase, leveraging a multivariate approach and gas analysis. The study also incorporated Aspirating Smoke Detection (ASD) to characterize the responses during large-scale testing. The findings pave the way for identifying and integrating innovative technologies, achieving accurate detection of early-stage signatures from internal contaminants during potential aircraft smoke events.
With a rising interest in hydrogen-fueled aircraft comes many design and safety concerns. There are many problems to be solved and safety standards and precautions established if aircrafts are going to be equipped with hydrogen. To that end, the objective of this project is to understand the fundamental characteristics of hydrogen flames. More specifically, small hydrogen flames resulting from leaks in diameter of less than 2mm will be studied and their flame characteristics recorded. To simulate leak conditions, a small-scale, horizontal custom hydrogen burner was made with five interchangeable nozzles, each representing a different leak. The nozzles varied in shape between circular and slot orifices, varied in size under 2mm, and the standard leakage flow rate varied was between 1SLPM (Standard Liters Per Minute) and 5SLPM. Nozzle exit-sensor spacing was an additional parameter which was varied between 1in (25mm), 2in (50mm), and 4in (100mm). A water-cooled gardon gauge was utilized to record impinging flame heat flux and K-type thermocouples were used to record cross-sectional flame temperature. Additionally, a flame tracking software was used to estimate the horizontal flame length from the nozzle exit up to the furthest horizontal reach of the flame. Results show that the most influential parameters for leakage flames are the leak size and the flow rate of hydrogen, while the leak shape (whether a crack or a pore) has little influence on the flame characteristics. Generally, increasing standard flow rate (SFR) of hydrogen while keeping leak size constant resulted in an increase in flame heat flux and flame temperature, while increasing the leak size for a given flow resulted in a decrease in flame heat flux and flame temperature. Additionally, reducing the nozzle exit-sensor spacing generally resulted in an increase in flame heat flux while a decrease in flame temperature.