Abstract
Hot flaring, even from quite high flare stacks, may result in significant heat radiation outside a facility to, e.g., public roads where random passersby may be exposed. The present study suggests a novel method for analyzing a typical flare heat radiation exposure and investigates skin burns that may be inflicted on an exposed person if a facility needs to depressurize in an emergency situation. A typical radiation field from an ignited natural gas vent was taken as the boundary condition, and these values were compared to radiation levels mentioned by the American Petroleum Institute (API 521), e.g., 1.58 kW/m2 and above. Due to facility perimeter fences along roads in larger industry areas, it was assumed that an exposed person may flee along a road rather than in the ideal direction away from the flare. It was assumed that naked skin, e.g., a bare shoulder or a bald head is exposed. The Pennes bioheat equation was numerically solved for the skin layers while the person escapes along the road. Sun radiation and convective heat exchange to the ambient air were included, and the subsequent skin injury was calculated based on the temperature development in the basal layer. Parameters affecting burn severity, such as heat radiation, solar radiation, and convective heat transfer coefficient, were analyzed. For small flares and ignited small cold vents, no skin burn would be expected for 1.58 kW/m2 or 3.16 kW/m2 maximum heat radiation at the skin surface. However, higher flare rates corresponding to, e.g., 4.0 kW/m2 maximum flare heat radiation to the skin, resulted both in higher basal layer temperatures and longer exposure time, thus increasing the damage integral significantly. It is demonstrated that the novel approach works well. In future studies, it may, e.g., be extended to cover escape through partly shielded escape routes.
Highlights
Most hydrocarbon processing plants and gas transport systems operate at high pressures, i.e., up to and even above 100 bar
For the modeling of skin temperatures and skin damage integral as a person is walking along the pavement under a gradually decreasing flare stack heat flux, it is convenient to fit a polynomial expression to the calculated heat flux levels
A sixth-order polynomial was fitted to the calculated radiation levels
Summary
Most hydrocarbon processing plants and gas transport systems operate at high pressures, i.e., up to and even above 100 bar. Leaks, and other emergency situations, blowdown and vent/flare systems are recognized as very important safety barriers. The released gas inventory is burned at the flare tip. Depending on the size and pressures, flare rates up to 1000 tons per hour may be experienced. From quite high industrial flare stacks, this flaring may result in significant heat radiation levels inside the facility, i.e., inside the fenced-off area. Outside the facility perimeter, the heat radiation may be significant, e.g., at public roads where random passersby may be exposed
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