in radiative heating controls weather
Radiation intensity affects fuel moisture
Fire is a high-temperature heat source
Radiation influences fire spread
Radiation creates problems in fire behavior and fire control
Some radiation problems can be alleviated
RADIATION AND FIREFIGHTING SAFETY
The body's ability to withstand heat is limited
Proper clothing will reduce heating by radiation
Survival in wildland fires is possible
The main flame wave is the greatest hazard
Motor vehicles can provide shelter
Buildings can sometimes be used
Escape from the fire if possible
Part 1: The Nature of Heat (1975)
Part 2: Heating Conduction (1975)
Part 3: Heat Conduction and Wildland Fire (1976)
Part 4: Radiation (1976)
Part 5: Radiation and Wildland Fire (1976)
The Nature of Heat
Three ingredients are essential for a wildland fire to start and to burn. First, there must be burnable fuel available. Then enough heat must be applied to the fuel to raise its temperature to the ignition point. And finally, there must be enough air to supply oxygen needed to keep the combustion process going and thus maintain the heat supply for ignition of unburned fuel. These three indispensable ingredients—fuel, heat, and oxygen—make up the fire triangle. All must be present if there is to be fire. In the following discussion, we will examine some of the basic characteristics of the heat segment of the fire triangle—the nature of heat itself.
The science of heat is relatively new
Everyone knows how heat feels, and is well aware of its many applications in daily life. Heat from the sun is the basic control of our weather, and this heat is also essential in the growing of food crops and other vegetation. Without the sun's heat, life could not exist on the earth.
Through the science of thermodynamics, heat has a place in many of the industrial processes that bring us the conveniences of modern life. But as recently as 200 years ago, the true nature of heat was not understood. In the early days of science the phenomena associated with heat were ascribed to a mystical and intangible fluid called "caloric." This fluid was believed to have the power of penetrating and expanding materials, sometimes melting or dissolving them, and converting some substances to vapor. Heat produced by friction or the compression of gases was attributed to stored caloric that was squeezed or ground out of the material. The caloric fluid was considered intangible, since even the most careful experiments in adding or subtracting heat by nondestructive heating or cooling of a substance failed to produce any changes in its weight.
Heat is energy
We know now that heat is not a fluid, nor a substance at all, but is really one of the several forms of energy. Other common forms are electrical energy, radiant energy, chemical energy, and the mechanical or kinetic energy possessed by moving materials and objects, such as falling water or a rotating wheel. Atomic and nuclear energy are still other forms. Heat is often labeled thermal energy.
According to molecular theory, all substances are made up of molecules, and as long as the temperature of the substance is above absolute zero (-469°F), these molecules are in some degree of motion. When heat is applied to a substance, the molecular activity increases and the temperature rises. Conversely, if a substance loses heat, the molecular activity decreases and so does the temperature. We can think of heat, then, as the energy of molecules in motion.
Energy cannot be created or destroyed in any way that we know. But it can be changed from one form to another, and this transformation is constantly going on, both in nature and through the activities of man. For example, radiant energy from the sun is transformed by the process of photosynthesis to stored chemical energy in vegetation. When the vegetation is burned, the chemical energy is transformed to thermal energy, radiant energy, and the kinetic energy in the
