Use of foam for firefighting in tank farms of the oil and petrochemical industry

Tank farm fire at Deer Park, Texas, USA

Tank farm fires in the oil and petrochemical industry do not occur often.

When they do occur, it is with devastating consequences and negative publicity. This article will describe the typical incident scenarios and present foam as the most suitable extinguishing agent together with the firefighting equipment most commonly used. Finally, it is questioned whether the lessons learned from every incident are being taken into consideration.

In the past, a number of fires caused massive damage to tank farms, oil refineries and loading terminals. Prominent examples include the ITC tank farm at Deer Park, Texas, USA in March 2019 and the refinery fire at Baton Rouge, Louisiana, USA in February 2020.

Devastation after explosion and fire in a petrochemical plant

Sadly, only news of this kind makes its way into the news, unlike near-miss accidents where improved fire protection technology has prevented worse outcomes. This means that both fire protection and extinguishing methods must be improved to minimize the effects of future fires. Fire protection systems in hazardous areas of the oil and gas industry (fire class B) require unique extinguishing systems as foam is considered the best extinguishing agent for liquid fires. However, the use of water can be important as well for cooling the tank wall and adjacent tanks.

Luckily, such large-scale incidents do not happen frequently, but when they do, they may have a severe impact on humans, local ecosystems and the general environment. Extinguishing full-surface oil tank fires is very challenging. Many authorities and companies have not learned from such incidents, some of which can be disastrous.

The tanks in use are typically classified by roof type and diameter. They are distinguished between fixed roof, floating roof and fixed roof tanks with a floating cover. Flammable liquids are commonly stored in tanks with a floating cover or roof; explosive fluids, in turn, are stored in tanks with a fixed roof. The tank diameters are normally between 65 ft and 265 ft, although larger tanks up to 394 ft are also used. Their heights usually vary between 33 ft and 246 ft. This article is focusing on firefighting techniques and will not deal with tank types in more detail.

Diverse regional and national laws exist worldwide concerning fire protection. This article will be addressing the basics of the globally applied NFPA 11 issued by the National Fire Protection Association, the standard for firefighting with foam.

Fire incidents in tank farms of the oil and petrochemical industry occur in different scenarios, with consequences ranging from minor to disastrous. The most typical scenarios are listed as the following:

Foam has proven to be the best medium to extinguish fluid fires. Foam consists of water, foam concentrate and air. The foam concentrate is mixed with the extinguishing water at a precisely defined rate. Air is then added to this premix to generate the foam. Depending on the foam concentrate and the quantity of air, different types of foam are produced to extinguish different types of fire. Foam forms a homogenous layer of air bubbles, increasing the extinguishing agent's volume and, hence, reducing its density. The foam floats on top of the flammable liquid and spreads across its surface. Due to this and its chemical properties, the foam blanket suppresses the release of flammable vapors, cuts off the supply of air and cools down the substance on fire. Continuous application of foam until fully covering the entire surface of the burning liquid will finally smother the fire.

Foam concentrates are developed for specific proportioning rates. The most common ones are 1% and 3%. As a general rule, a foam concentrate can form a stable and functioning foam only if it is mixed to the extinguishing water at no less than the correct proportioning rate. An increased proportioning rate will still form a stable and functioning foam, however, the foam concentrate stored will be consumed faster. A proportioning rate falling short will produce a foam which is unable to develop its full extinguishing power.

○ Suitable foam concentrate

○ Sufficient foam concentrate supply

○ Sufficient water supply

○ Functioning extinguishing equipment in sufficient quantity (well-maintained, quick and easy access, correct strategic placement)

○ Trained personnel

○ Quick implementation of a suitable plan of action

Depending on the tank type and the size of the tank farm, the extinguishing systems must be designed specifically for each site. A fixed-roof tank must have a fixed extinguishing system which allows discharging foam under the roof. An application from mobile systems outside is possible only if the roof has been damaged or removed by a fire or an explosion. In case of a floating-roof tank, the foam can be applied by use of fixed or mobile systems from outside.

Fixed extinguishing systems typically consist of one or more stationary fire pumps, one proportioner and tank for the foam concentrate, discharge devices such as foam nozzles, sprinklers, foam pipes or fire monitors and the corresponding piping.

Mobile systems generally consist of the same components (fire pump, proportioner, supply tank); these must, however, be available in mobile form on vehicles or trailers. In addition, only fire monitors are usually used as discharge devices. The piping/lines consist of hoses and suction pipes. Besides the tactical positioning of the foam discharge points, including mobile units, the foam concentrate and its proportioning into the extinguishing water are the most important factors for successful extinguishing. This will be looked at more closely referring to NFPA 11.

Fire monitor M9 in a test run at a tank farm

When storing the foam concentrate in suitable containers, attention must be paid that they are stored a safe distance away from the objects to be protected. The quantity must be sufficient to allow extinguishing of the largest protected object, or of the objects to be protected simultaneously as a minimum. The proportioning rate will dictate the quantity of the foam concentrate required. Generally, it is important not to mix different foam concentrates or foam concentrates with different proportioning rates as this can lead to unstable foam formation. Below is an example calculation for the foam demand according to NFPA 11:

Tank surface x specific extinguishing water quantity x proportioning rate of foam concentrate x requested minimum extinguishing time.

In case of a crude oil tank of 196 ft (60 m) diameter with fixed-roof, NFPA 11 requires an application of 0.16 gpm/ft² (6.5 l/min*m2) for an extinguishing time of 65 min.

When using a 3% foam concentrate, this results in a minimum amount of approximately 9,500 gallons (36,000 liters) of foam concentrate and a required extinguishing water flow rate of approximately 4,750 gpm (18,000 l/min). NFPA 11 recommends stocking additional foam concentrate for the dyke area of about the same amount. In addition, a safety factor of 1.5 is recommended to compensate foam losses during extinguishing caused by, e.g., wind and other factors. This results in a stock of 28,500 gallons (108,000 l) of 3% foam concentrate. The choice of foam concentrate and proportioning rate is dictated by the fluid to be extinguished.

In the continuation of this article you will learn more about foam proportioning technologies, mobile extinguishing systems and how these contribute to an increased safety in tank farms of the oil and petrochemical industry.

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