At a plant producing intermediate organic synthesis compounds, a runaway reaction coupled with an explosion (approx. 1 kg of TNT equivalent) took place in the 3.5-m high glass column overlooking a 3,000- litre reactor. The explosion triggered a fire outbreak inside the unit. A 110-kg cloud of hydrochloric acid (HCl) hovered over the site before dispersing after a few minutes due to a favourable wind. The noise alerted the technical staff, who promptly placed the installation in safe operating mode and launched the internal emergency plan. The staff began to fight the fire using the resources at hand, and were then joined by fire-fighters who brought the blaze under control within twenty minutes. One employee sustained loss of hearing due to the explosion and property damage amounted to €700,000.
On the day of the accident, a batch production had been underway involving the addition of 1,000 kg of a cold liquid ethylene compound along with 750 kg of a highly flammable and volatile silyl (hydrosilane). The homogeneous mix was then supposed to be poured into a 2nd reactor at 100°C in the presence of a catalyst to form the final product. The hydrosilylation reaction was maintained under control by gradually introducing the mix. However, in this incident, a sudden rise in mix temperature caused a pressure surge and a pneumatic burst of the column. The hydrosilane was hydrolyzed into HCl upon coming into contact with humid air and then decomposed into the hydrogen that triggered this fire.
The investigation revealed that in order to compensate for the loss of catalyst activity (this was the seventh consecutive batch), which would have necessitated an extended batch time, a technician took the initiative to insert around 10g of new catalyst into the reactor at the same time as the raw materials. Data studies and laboratory tests actually indicated that the reaction could not have started in the low temperature reactor (5-20°C), since deviation from the temperature required for synthesis (at 90°C) appears to safeguard the reaction safety of this modification, i.e. now deemed to be minor. Nonetheless, the tests conducted by the operator following the accident revealed that at these temperatures, an exothermic hydrosilylation reaction could arise following an induction period lasting several hours in the presence of trace alcohol amounts. Since the catalyst had been placed in solution with a ketone, an infinitesimal quantity of ketone (in the order of 0.01%) was found in the mix inside the reactor and subsequently reduced to alcohol by the hydrosilane. Despite an extensive process of analysing reaction risks plus the synthesis of 36 batches without an accident in six years, the accident occurred on the only batch for which the process had been slightly modified.
The operator reminded plant technicians that: 1. this modification should have been rated as significant and undergone an in-depth, collective analysis prior to implementation; and 2. any modification to a process must be justified and accompanied by compensatory safety measures.
Source:Aria database