Modern fire safety engineering seeks to ensure buildings are safe from fire by applying optimum levels of fire safety and protection resources without the need to overprotect. Similarly, the principles of sustainability aim to ensure resources are suitably applied to meet social, economic, and environmental objectives. However, there is a mismatch between the actual application of fire safety and the sustainability objectives for buildings, typically caused by the highly prescriptive historical approaches still largely adopted and legislated for in many countries. One solution that is increasingly adopted is the more flexible, “performance-based” fire engineering approach that bases fire safety and protection provisions on the development of key performance objectives, some of which could be influenced by sustainability engineering propositions for buildings, but very often this does not appear to be enough. The proposed new concept prompts separate assessment and scoring of the eight most important fire safety factors, allowing for calculation of the fire strategy risk index (FSRI). By comparing the FSRI of the actual submitted strategy against the baseline strategy, enforcement agencies or other interested stakeholders will have a methodology to determine optimal fire safety solutions for buildings.
There is a mismatch between the desire to introduce greater levels of sustainability in engineering design and in the need to provide effective engineering solutions, particularly where issues of human safety and asset protection are involved. Sustainability engineering typically incorporates economic, environmental, and social factors, all of which are highly relevant and applicable to fire safety and the design of fire protection systems. The term fire strategy denotes a documented methodology to encapsulate a full range of such systems, within a single framework, for more complex risks such as those found in the process industry. The subject of fire safety is emotive and its application within building design may not change unless we refocus on a holistic and strategic approach, especially for complex building profiles. Fire is a recognized critical safety issue for most types of industrial plants. Due to the complexity of the processes, even a relatively small fire accident can lead to a chain of events that could be devastating, resulting in huge asset and continuity losses, damage to the local environment, and of course, the threat to life. More complex processes require a more flexible and relevant approach. The use of fire safety engineering and performance-based evaluation techniques, instead of prescriptive rules, continues to grow in prominence because of this. This is the case when specifying fire protection and safety for modern power generating plants. However, when it comes to critical infrastructure, such as is the case with power plants, it is sometimes not clear whether optimum fire safety engineering solutions have been applied. One of the ideas specifically developed for evaluating the most appropriate fire safety strategies and systems, especially for such infrastructure examples, is a method based upon the British Standard Specification PAS 911. This method is captured in a diagram and identifies eight main elements for fire safety and protection. The idea presented in this article is to allow assessment of a submitted actual fire strategy for a building or other form of infrastructure, against what has been predetermined as a standard baseline fire strategy for, in this case, a power plant building. The assessment makes use of a multi-level questionnaire, in this case specifically formulated for power plant fire safety needs. By comparing the actual fire strategy diagram against a baseline fire strategy, enforcement agencies, or other interested stakeholders, can recognize which fire safety factors play the most important part in the fire strategy, and determine whether proper levels of fire safety and protection have been applied. The fire strategy evaluation is realized by a team of engineers, which consists of independent fire strategist from a consultant office, internal fire and technical experts from the industrial plant, such as the person responsible for fire safety, person responsible for explosion safety, person responsible for housekeeping, and building manager. Additionally, there should be representatives of insurance companies and independent fire experts. Typically, the group consists of 7 to 12 people.
Even though electric vehicles (EV) were invented over a century ago, their popularity has grown significantly within the last 10 years due to the development of Li-ion battery technology. This evolution created an increase in the fire risk and hazards associated with this type of high-energy battery. This review focuses on lessons learned from electric vehicle fires and fire risk mitigation measures for passenger road vehicles partially or fully powered by Li-ion batteries. The paper presents EV fire risks, as well as historical car fires, published large-scale fire tests, and some proposed fire protection strategies in the aspect of electromobility safety for the future. Technical solutions for EV fire hazard mitigation are discussed, and methods of performance-based analysis and simulations for fire safety in car park evaluation are demonstrated. The Fire Dynamic Simulator (FDS) was used for the CFD simulations for the prediction of smoke dispersion and temperature distribution during an EV fire. The presented case study demonstrates how fire simulations could predict conditions for the safe evacuation of people and Fire Brigade intervention conditions in the case of an EV fire in a car park.
The use of fire safety engineering and performance-based techniques continues to grow in prominence as building design becomes more ambitious, increasing complexity. National fire safety enforcement agencies are tasked with evaluating and approving the resulting fire strategies, which have similarly continued to become more advanced and specialist. To assist with the evaluation of fire strategies, this paper introduces a methodology dedicated to sustainable building fire safety level simulations. The methodology derives from ideas originally introduced in British Standard Specification PAS 911 in 2007 and combines a visual representation of fire strategies with a semi-quantitative approach to allow for their evaluation. The concept can be applied to a range of industrial fire safety assessments and can be modified for specific needs relative to different industries.
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