Abstracts

ENGINEERING AND TECHNOLOGY

Using egg albumin foam to extinguish fires

Hytham A. Alsaati; Danielle Ditzler; Vorakan Burapatana; Robert D. Tanner^* * Author for correspondence

Chemical Engineering Department; Vanderbilt University; Fax: (615) 343-7951; rtanner@vuse.vanderbilt.edu; Nashville, TN 37235; USA

ABSTRACT

Oil, coal and chemical fires are often difficult to put out using water. In certain hydrocarbon fires, protein foam can extinguish fires better than water by keeping air (oxygen) away from the flames and by ''blowing'' the flame away from its fuel source. Egg albumin is a relatively inexpensive protein and is representative of foaming proteins, which are candidates for use as fire suppression agents. This paper begins to deal with the effect of the foam bulk pH, foam protein concentration and generating air flow rate into the foam on the fire extinguishing time in laboratory experiments. A Bunsen burner was used to generate a small, controlled laboratory fire within a plastic container, which represented a point source in a partially open room in the experiments. The Bunsen burner represents a gaseous hydrocarbon fire, which can be difficult to extinguish. Both a low pH foam and one made with a high air flow rate favor a reduction in time required to put out the Bunsen burner flame.

Key words: Protein Foam, Albumin, Fire Suppression, Biodegradable Foams, Natural Gas Flame

RESUMO

Chamas produzidas por óleo, carvão e produtos químicos (incêndios provocados) são difíceis de ser extinguidos com água. Algumas chamas de hidrocarbonetos podem ser extinguidas por espumas protéicas melhor do que a manutenção de ar (oxigênio) fora do alcance das chamas ou pelo sopramento da chama para longe da sua fonte.

Albumina de ovo é uma proteína relativamente barata e é representativa dentre as proteínas usadas como espuma para a (supressão) extinção de agentes causadores de incêndio. Este artigo trata do estudo do efeito do pH e concentração da espuma protéica, além da geração de ar no interior da espuma, sobre o tempo de extinção de incêndio em experimentos laboratoriais. Nos experimentos um bico de Bunsen foi usado para gerar uma pequena chama, controlada em um container de plástico, representando uma fonte pontual em um ambiente parcialmente aberto. A chama do bico de Bunsen representa uma chama gasosa de hidrocarbonetos, que são difíceis de ser extintas. Ambos os fatores, baixo pH de espuma e uma alta de aeração, favorecem a redução do tempo de extinção da chama de Bunsen.

INTRODUCTION

''The conventional method of putting out fires using water can be ineffective against liquid fuel fires fed by gasoline, coal or chemicals. Using water to suppress fires can also pose other problems like damage to neighboring electrical appliances and computers. Water is relatively heavy so it may not be suitable for putting out fires in airplanes or spacecraft'' (Reisch, 2001), where it must be carried. A partial alternative to using water for fire suppression is to employ fire-extinguishing protein foam (which contains only a fraction of the water used in the former method). Foam can create a barrier between the required oxygen in the air and a flame. Halons are widely used to create fire suppression foams, but halons are ozone depleting and may contribute to increased UV exposure on the earth (US Department of Transportation, 2001). The replacement of halons with non-fluorocarbons such as proteins may reduce the rate of ozone depletion.

This paper deals with the feasibility of using egg albumin foam to suppress a gaseous hydrocarbon fire. Egg albumin protein is selected as a representative foaming protein due to its relativly low cost, low-toxicity and biodegradability. Methane is used as the gaseous hydrocarbon fuel.

MATERIALS AND METHODS

Albumin (lot no. 119H0910) was purchased from Sigma. The protein solution was prepared by dissolving solid albumin in water to the desired concentration. The pH of the solution was adjusted by the addition of 0.1 M HCl or 0.1M NaOH. The pH was measured by a Chemcadet pH meter (model No. 5984-50).

The apparatus is depicted in Fig. 1. The foam was formed by passing air through the bulk solution in the column. The glass column was 2.5cm in diameter, 45cm long and contained 100 ml of bulk protein solution initially. The compressed air from the building air line was first passed through a beaker containing water (the air humidifier) before entering the column, in order to minimize the loss of water from the column during the foaming process. The airflow was measured by a rotameter. Following the rotameter, the air flowed through a glass fritted disc sparger at the bottom of the column creating small air bubbles in the bulk fluid. The air superficial velocity (airflow rate divided by the inside cross-sectional area of the column) was varied between 2 and 2.7 cm/s. The fire quenching time, measured with a wrist watch, was the time required to put out the natural gas-fed Bunsen burner flame in a plastic container which was open to foam at the top. The Bunsen burner was inserted into the spout of this bottomless 1-gallon plastic milk jug as illustrated in Fig. 1. The Bunsen burner flame represents a hydrocarbon fire. The flame height was controlled using the natural gas line valve. It was adjusted to two positions in this study: 5 and 10 cm.

RESULTS AND DISCUSSION

A hydrocarbon fire may be easily ignited but difficult to extinguish. It was observed here that at the time the top of the flame was extinguished by foam, a final flash of the flame was emitted from the bottom of the plastic jug. The reference pH of the generated foamate solution (before adding HCl or NaOH) was 6.3. The isoelectric point of albumin is around pH 4.7. The effect of pH on the quenching time for a 5 cm flame is shown in Fig. 2. It was observed that the quenching time decreased away from the peak at pH 6.3 for both acidic and basic foams. For the 10 cm flame it is seen in Fig. 3 that as the pH decreased from 6.3 to 3.9, the quenching time decreased from 23 seconds to 19 seconds. Raising the pH above 6.3 leads to an increase in quenching time up to pH 8.2, followed by a decline for higher pH's. Thus, it is observed that it takes longer to put out a 10 cm natural gas flame than a 5 cm flame at all pH's using albumin foam and especially for pH's above 6.3.

The effect of the air superficial velocity used to generate the foam on the fire quenching time was observed. An increase in the foam generating air flowrate is directly translated to an increase in the rate at which the foam enters the quenching container. The air superficial velocity of the generated foam was changed by adjusting the airflow rate into the column. The air superficial velocity also affected the character of the foam by changing the foam air void fraction. Higher velocities generally lead to more water entrapment in the foam, hence, wetter foams. Wetter foams in this study seemed to put out flames better than drier foams. As noted in Fig. 4, an increase in air superficial velocity from 2 cm/s to 2.7 cm/s reduces the quenching time by 53% for a 5 cm flame. The data were readily replicated when the air superficial velocity was varied, as noted by the small magnitude of the standard deviation in Fig. 4.

The protein concentration of the bulk solution also exhibited an inverse relationship with the quenching time. As the protein concentration increased for the runs where the superficial velocity was above 2.25 cm/s, the quenching time decreased. From Fig. 5, it was seen that an increase in air superficial velocity enhanced the effect of an increase in the concentration of the bulk solution on reducing the quenching time for all of the tested superficial velocities. In addition, the difference in quenching times between the different concentrations increased as the air superficial velocity increased. At an air superficial velocity of 2 cm/s, the quenching times were all within 1 second of the mean 15 seconds quenching time. At the air superficial velocity of 2.7 cm/s, the quenching times varied within 3 seconds of the mean 5 seconds quenching time, indicating very rapid extinguishing conditions. Presumably, the increase in air superficial velocity leads to a greater protein mass recovery and the resulting increase in water in the foam. The enhanced water content most likely is responsible for the faster quenching rate.

Use of egg albumin foam was found to be an effective method for natural gas fire suppression in a confined space. It successfully pushed the fire away from the source and prevented air from reaching to the flame. Here, the plastic milk jug (with the bottom cut off) served as a laboratory model for a room. The Bunsen burner served as a point source of a fire flame within the room. The quenching time for a 5 cm flame can be reduced from as much as 21 seconds to 2 seconds by adjusting the foam pH, air superficial velocity and albumin concentration.

CONCLUSIONS

The fire quenching time depended directly on the pH, air superficial velocity, and concentration of the albumin bulk solution for a given Bunsen burner flame height. A low pH, a high superficial velocity and a concentrated bulk solution together are one combination for rapid fire suppression using an egg albumin foam.

Received: December 22, 2002

Revised: May 02, 2003

Accepted: June 02, 2003

Publication Dates

History