The branch of science called thermodynamics deals with systems that are able to transfer thermal energy into at least one other form of energy (mechanical, electrical, etc.) or into work. The laws of thermodynamics were developed over the years as some of the most fundamental rules which are followed when a thermodynamic system goes through some sort of energy change.
HISTORY OF THERMODYNAMICS
The history of thermodynamics begins with Otto von Guericke who, in 1650, built the world's first vacuum pump and demonstrated a vacuum using his Magdeburg hemispheres.
Guericke was driven to make a vacuum to disprove Aristotle's long-held supposition that 'nature abhors a vacuum'. Shortly after Guericke, the English physicist and chemist Robert Boyle had learned of Guericke's designs and, in 1656, in coordination with English scientist Robert Hooke, built an air pump. Using this pump, Boyle and Hooke noticed a correlation between pressure, temperature and volume. In time, Boyle's Law was formulated, which states that pressure and volume are inversely proportional.
CONSEQUENCES OF THE LAWS OF THERMODYNAMICS
The laws of thermodynamics tend to be fairly easy to state and understand ... so much so that it's easy to underestimate the impact they have. Among other things, they put constraints on how energy can be used in the universe. It would be very hard to over-emphasize how significant this concept is. The consequences of the laws of thermodynamics touch on almost every aspect of scientific inquiry in some way.
A publication of The Italian Association of Chemical Engineering Online at www.aidic.it/cet
The evolution of fires in confined space such as chemical and pharmaceutical warehouses is characterized by the complex interaction between the combustion process, the enclosure and occupants, which has to be managed when coping with fire emergency and, more in general, for fire safety. This paper proposes a quick, decision-making tool based on adversity scenarios and more specifically through the definition of four main elements: i) the potential fire spread categories, which describe the potential paths and extents of fire propagation; ii) the thermal load expressed as hot gas layer temperature; iii) the available safe egress time (ASET) for people to leave the enclosure, which is essential for organizing people evacuation; and iv) other specific hazards. The proposed tool can be usefully adopted to improve the level of information to interested stakeholders (building owner, fire service, etc.) concerning both the fire hazard and the building fire performance. 1. Introduction Fires constitute one of the most important hazards from chemical and pharmaceutical warehouses. They can give rise to serious damage to people as well as to the environment and they can cause extensive economical losses. For these reasons, in order to assist the management to identify the most suitable countermeasures (both organizational and technical), it is useful to have a tool that allows identifying in advance the potential adverse situations that could characterize the analysed system. In the present work, two indicators describe the potential fire-induced adverse situations, the first is a qualitative description of the potential fire, and the second is a quantitative evaluation of the thermal load on sensible targets, based on Hot Gas Layer Temperature (HGLT). The assessment process is based on the inspection of the workplace (Dusso et al., 2015): the workplace is divided into cells, i.e. single rooms or enclosures, or in more in general, subsections of the same workplace separated from those adjacent by physical elements as walls or floors and - in the open - barriers or separation distances. Then, important information regarding the characteristics of the stored materials, the storage conditions and the features of the enclosure such as floor area, ceiling height, openings should be collected.
Successful Litigation Relies on Proper Analysis
by Roman Kickirillo, P.E., CFEI, CVFI, Donan Engineering Company, Inc. Nashville, Tennessee
The investigation into the cause and origin of motor vehicle fires should be considered a separate field of study than structure fires. Although the basic Fire Science remains the same, there are important differences in the interpretation and analysis of fire patterns and other evidence. An understanding of these differences before litigation begins can avoid lost time and expenses later in the process. There are very few absolute rules in vehicle fire investigations, but one always holds true: If your expert’s analysis is incorrect, the opposing side will be more than happy to let you know about it - at the worst possible time.
Study by: Albert Simeoni, Zachary C. Owens, Erik W. Christiansen, Abid KemalExponent, Inc. USAMichael Gallagher, Kenneth L. Clark, Nicholas SkowronskiNorthern Research Station, USDA Forest Service, USAEric V. Mueller, Jan C. Thomas, Simon Santamaria, Rory M. HaddenSchool of Engineering, University of Edinburgh, UK
Two experimental fires, with contrasting intensities, were conducted in March 2016, in the Pinelands National Reserve (PNR) of New Jersey, United States in order to provide a preliminary assessment of the reliability of the fire direction indicators used in wildland fire investigation. The experiments were part of a larger project intended to measure firebrand production in a forested ecosystem. As part of this project, fire behavior, as well as the environmental and fuel conditions were also measured. Two burn parcels, covering an area of approximately 30 hectares each, were ignited from unimproved forest roads which delimited them. The forest canopy was comprised primarily of pitch pine with intermittent oaks. The understory contained a mixed shrub layer of huckleberry, blueberry, and scrub oaks. In order to explore a wide range of indicators, objects such as bottles, cans and small fence elements were planted in the burn area, and photographed before and after the fire. To obtain an accurate measure of pre- and post-fire fuel properties, fuel load, fuel bulk density, and fuel moisture content were also measured. In addition, environmental data (wind velocity and direction, air temperature and humidity) were recorded. The fire behavior can be reconstructed using measurements of fire rate of spread, fire front temperatures, fire front geometry, and heat fluxes. Video and infrared cameras were used to document the general fire behavior in selected locations. This paper represents the first step in the analysis of the fire indicators and focuses on the more intense of the two burns and on the appearance of the macro- and microscale fire pattern indicators. A majority of the indicators were assessed, although the configuration of the burn parcels, the ignition technique, and precipitation immediately following the fires limited a full study. The results show that some fire direction indicators are highly dependent on local fire conditions and fire behavior and may be in contradiction with the general spread of the fire. Overall, this study demonstrates that fire pattern indicators are a useful tool but must be interpreted in the frame of a general analysis of the fire, combined with a good understanding of fire behavior and fire dynamics.
From Out of the Abyss...
This week’s article from the past is titled Incendiary Fires Can Be Spotted and was written by Benjamin Horton, CPCU, who was President of the National Adjuster Traing School in Louisville, Kentucky.. It is taken from the Decembe 1968 Vol. XVI No.5 issue.
Incendiary Fires Can Be Spotted
Candles can enhance décor or be a source of light. However, they can also start fires. National estimates of reported fires derived from the U.S. Fire Administration’s National Fire Incident Reporting System (NFIRS) and NFPA’s annual fire department experience survey show that candles were the heat source in an estimated average of 9,300 reported home fires annually during 2009-2013. These fires caused an average of 86 civilian deaths, 827 civilian injuries and $374 million in direct property damage per year. More than one-third (36%) of home candle fires started in the bedroom. Almost three of every five (58%) fires occurred because the candle was too close to something that could burn. Candle fires are most common around the winter holidays. Candles used for light in the absence of electrical power appear to pose a particular risk of fatal fire. Home candle fires climbed through the 1990s but have fallen since the 2001 peak. ASTM F15.45 has developed a number of standards relating to candle fire safety. Despite the considerable progress made in reducing candle fires, they are still a problem. In 2009-2013, candle fires ranked second among the major causes in injuries per thousand fires and average loss per fire. Efforts to prevent these fires must continue.
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