Combustion 2008

Background

In recent years, because attention has been concentrated on non-reacting flows, it must be admitted that the development of combustion modelling in PHOENICS has stagnated. Specifically:

The Simple Chemically Reacting system has continued to be used, but still with the restriction to a single fuel-supply stream.
Temperatures have continued to be calculated by way of enthalpy, which has conflicted with the direct solution for TEM1 that is preferred for problems involving conjugate heat transfer (i.e. interaction with heat conduction in neighbouring solids).
The Extended SCRS has been little used because of its limitations and complexity.

Recently however attention to the problem are has been renewed, with the results that:

multiple fuel-supply streams can be handled;

solution for enthalpy can be abandoned; and

direct solution for temperature (i.e. TEM1 ) can be recommended for all circumstances.

These developments involve:

replacing the MIXF (i.e. mixture fraction ) variable by MIX1, MIX2, MIX3 etcetera which represent the mass fractions of material introduced by the first, second, third etcetera fuel-supplying streams;
introducing the concept of the adiabatic-flow temperature, T1AD, which is the temperature which would prevail if heat transfer to the solids surrounding the flowing gases were absent;
recognising that the solved-for TEM1 variable, which has no chemical-reaction-related sources, represents the deviation of the actual temperature T1 from the adiabatic temperature, thus:
T1 = T1AD + TEM1; and
recognising that the enthalpy continues to have value as an auxiliary variable, but only as stored, not solved-for.

The extreme scenarios distinguished

In order to simplify the simulation process where possible, it is useful to distinguish the following extreme scenarios:

Adiabatic; mixed-is-burned; one fuel-bearing stream
Adiabatic; mixed-is-burned; several fuel-bearing streams
Adiabatic; mixed-is-burned; several different-fuel-bearing streams
Non-adiabatic; mixed-is-burned; one fuel-bearing stream
Non-adiabatic; mixed-is-burned; several fuel-bearing streams
Non-adiabatic; mixed-is-burned; several different-fuel-bearing streams
Adiabatic; finite reaction rate; one fuel-bearing stream
Adiabatic; finite reaction rate; several fuel-bearing stream
Adiabatic; finite reaction rate; several different-fuel-bearing stream

These scenarios will be discussed individually, one-by-one. a. Adiabatic; mixed-is-burned; one fuel-bearing stream The solved-for variable which is relevant to combustion is MIXF, the mass fraction of material emanating from the fuel-bearing in-flow stream, whatever its state of chemical aggregation.

Variables which it may be useful to store but not solve include:

the enthalpy H1,
the temperature T1,
the unburned fuel mass fraction FU,
the unburned oxygen mass fraction O2,
the product-of-combustion mass fraction PROD
If the fuel mass fraction of that stream is fuin,

Relevant material constants are:

The stoichiometric ratio (= bass of oxygen needed to burn unit mass of fuel), fst. b. Adiabatic; mixed-is-burned; several fuel-bearing streams c, Adiabatic; mixed-is-burned; several different-fuel-bearing streams d, Non-adiabatic; mixed-is-burned; one fuel-bearing stream e. Non-adiabatic; mixed-is-burned; several fuel-bearing streams f. Non-adiabatic; mixed-is-burned; several different-fuel-bearing streams g. Adiabatic; finite reaction rate; one fuel-bearing stream h, Adiabatic; finite reaction rate; several fuel-bearing stream i. Adiabatic; finite reaction rate; several different-fuel-bearing stream