Book contents
- Frontmatter
- Contents
- Preface
- 1 Turbulent reacting flows
- 2 Statistical description of turbulent flow
- 3 Statistical description of turbulent mixing
- 4 Models for turbulent transport
- 5 Closures for the chemical source term
- 6 PDF methods for turbulent reacting flows
- 7 Transported PDF simulations
- Appendix A Derivation of the SR model
- Appendix B Direct quadrature method of moments
- References
- Index
5 - Closures for the chemical source term
Published online by Cambridge University Press: 07 December 2009
- Frontmatter
- Contents
- Preface
- 1 Turbulent reacting flows
- 2 Statistical description of turbulent flow
- 3 Statistical description of turbulent mixing
- 4 Models for turbulent transport
- 5 Closures for the chemical source term
- 6 PDF methods for turbulent reacting flows
- 7 Transported PDF simulations
- Appendix A Derivation of the SR model
- Appendix B Direct quadrature method of moments
- References
- Index
Summary
In this chapter, we present the most widely used methods for closing the chemical source term in the Reynolds-averaged scalar transport equation. Although most of these methods were not originally formulated in terms of the joint composition PDF, we attempt to do so here in order to clarify the relationships between the various methods. A schematic of the closures discussed in this chapter is shown in Fig. 5.1. In general, a closure for the chemical source term must assume a particular form for the joint composition PDF. This can be done either directly (e.g., presumed PDF methods), or indirectly by breaking the joint composition PDF into parts (e.g., by conditioning on the mixture-fraction vector). In any case, the assumed form will be strongly dependent on the functional form of the chemical source term. In Section 5.1, we begin by reviewing the methods needed to render the chemical source term in the simplest possible form. As stated in Chapter 1, the treatment of non-premixed turbulent reacting flows is emphasized in this book. For these flows, it is often possible to define a mixture-fraction vector, and thus the necessary theory is covered in Section 5.3.
Overview of the closure problem
In this section, we first introduce the ‘standard’ form of the chemical source term for both elementary and non-elementary reactions. We then show how to transform the composition vector into reacting and conserved vectors based on the form of the reaction coefficient matrix. We conclude by looking at how the chemical source term is affected by Reynolds averaging, and define the chemical time scales based on the Jacobian of the chemical source term.
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- Computational Models for Turbulent Reacting Flows , pp. 141 - 240Publisher: Cambridge University PressPrint publication year: 2003
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