Applying HAZAN methodology to hazmat transportation risk assessment

As conceptualized and put forward by Kletz, avoiding hazard at first instance is always desirable than trying to protect or manage it. However, there could be certain hazards which may not be possible to be totally eliminated and thus shall be analyzed and assessed in order to either reduce the probability of occurrence or limit the severity of consequences. Trevor's methodologies on HAZOP and hazard analysis (HAZAN) for process hazards are quite straightforward where the hazard is considered as a point source unlike hazmat transportation which is a moving source of hazard. The authors applied the HAZAN techniques to the transportation risk assessment of three different United Nations classes of hazardous materials (hazmats) through important industrial corridors of Surat district in western India that helped local authorities not only to decide on the minimum risk routes to regulate hazmat traffic but also to prepare an effective evacuation and emergency response strategies.     

Optimizing removal of ibuprofen from water by magnetic nanocomposite using Box–Behnken design

Purpose  

The present research aims to optimize the removal of ibuprofen (IBP), a non-steroidal anti-inflammatory, analgesic, and antipyretic drug from the aqueous solution using a synthesized magnetic carbon–iron nanocomposite, and to investigate the individual and combined effects of the independent process variables.     

Using consequence – based hazard zone assessment for effective evacuation planning of vulnerable settlements along hazmat transport corridors through industrial city of Surat in western India

Following a toxic hazmat release, decisions need to be made vis-a-vis a safe evacuation distance for population along the transportation route, or whether to shelter-in-place if there is insufficient time to conduct an evacuation. The first responder may have to take these decisions through a quick estimation of the Initial Isolation Zone (IIZ) and protective action distances based on assumed rate of releases. Real-time evacuation planning models could be used for effective evacuation purposes. However, factors that usually were taken into account include weather conditions, population density, time of day, and uncertainty about the chemicals involved and/or the accumulating concentrations in public areas. Emergency planning including evacuation in India is generally in line with UNEP's APELL (Awareness and Preparedness for Emergencies at Local Level) methodology. However, quantitative risk based assessment is catching up particularly in large industrial zones. The paper highlights a case study of the evaluation of identified seven critical evacuation planning zones along three highway study routes in and around the industrial city of Surat in western India. The elapsed time after a release is estimated through ALOHA and evacuation travel time estimates are made for each zone. For identified scenarios, evacuation of IIZ, generally comprising of road side population, is effectively possible in six out of seven identified emergency planning zones except in zone-7, where certain people would still be exposed, as full evacuation may not be achieved. However, shelter-in-place would be advisable for population residing in permanent settlements within the protective action zone.