Basics of Fluid Dynamics

Abstract

In this chapter, studies on basic properties of fluids are conducted. Mathematical and scientific backgrounds that helps sprint well into studies on fluid mechanics is provided. The Reynolds Transport theorem and its derivation is presented. The well-known Conservation laws, Conservation of Mass, Conservation of Momentum and Conservation of Energy, which are the foundation of almost all Engineering mechanics simulation are derived from Reynolds transport theorem and through intuition. The Navier–Stokes equation for incompressible flows are fully derived consequently. To help with the solution of the Navier–Stokes equation, the velocity and pressure terms Navier–Stokes equation are reduced into a vorticity stream function. Classification of basic types of Partial differential equations and their corresponding properties is discussed. Finally, classification of different types of flows and their corresponding characteristics in relation to their corresponding type of PDEs are discussed.

Related Papers

• → Conservation laws. Their role in evolutionary processes (The method of skew-symmetric differential forms)(2003)6 cited
• → Derivation of Conservation Law Equations(2012)
• → Conservation of Heat Flux and Energy(2014)
• → Discretization of Conservation Laws(2007)
• Comparative Studies of Laws of Conservation of Mass, Energy, and Elecctric Charge, and Multiform Laws of Conservation of Energy and the like — No.2 of Comparative Chemistry Series Papers(2016)