Handling of Equilibrium Reactions
Example I
The following short example illustrates how the Reaction Engineering interface and the Chemistry interface handle equilibrium reactions in the formulation of the material balance equations.
Consider the reaction:
(2-30)
According to Equation 2-2 the reaction rate (SI unit: mol/(m3·s)) is formulated as:
where cA and cB (SI unit: mol/m3) are the concentrations of A and B, and kf and kr (SI unit: 1/s) are the forward and reverse rate constants, respectively. The net rate expressions with respect to species A and B are then:
Assuming the reaction in Equation 2-30 is at equilibrium, the reaction rate r is 0:
The relationship between the forward and reverse reaction rates in Equation 2-30 is given by the following ratio:
(2-31)
The Reaction Engineering interface also sets up mass balances that are solved. The general material balances for species A and B, respectively, are:
(2-32)
(2-33)
The rate of consumption of species A equals the production rate of species B, as shown in Equation 2-32 and Equation 2-33.
With the combined information in Equation 2-32, Equation 2-33, and Equation 2-31, the Reaction Engineering interface is able to define the mass balances for the equilibrium system without the reaction rate expressions. The equation system solved for becomes:
(2-34)
(2-35)
In general, for a system of reactions contributing to k mass balances and with j reactions being at equilibrium, the reduced system of equations to be solved is composed of k – j mass balances and j equilibrium expressions. The elimination process producing the above system of equations is automated, allowing simple modeling of chemical equilibrium reactions together with irreversible and/or reversible reactions.
Example II
This example shows how equilibrium reactions are considered in the Reaction Engineering interface using the Equilibrium Species Vector section.
If two nonequilibrium reactions are taking place in a perfectly mixed isothermal reactor of constant volume:
(2-36)
the corresponding mass balances are:
(2-37)
(2-38)
(2-39)
Now compare Equation 2-37, Equation 2-38, and Equation 2-39 with the balance equations that the physics interface sets up for the related chemistry, where the second reaction is instead an equilibrium reaction:
(2-40)
(2-41)
In contrast to the reversible reaction given by Equation 2-36, to make use of the information contained in the equilibrium relation, the mass balances must be reformulated. Mass balances set up for the reactions given by Equation 2-40 and Equation 2-41 are then:
(2-42)
(2-43)
The equilibrium expression (Equation 2-43) introduces an algebraic relationship between the species’ concentrations.
Two species, B or C, can be set as Predefined Dependent Species in the Equilibrium Species Vector section. Selecting B as the dependent species solves Equation 2-42 for the concentration of C, while B is computed from Equation 2-43.