The Mathematics of Fluid Flow Through Porous Media. Myron B. Allen, III

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      In 1851, in a tour de force of vector calculus, Stokes [139] published the solution to this boundary‐value problem, along with an expression for the total viscous force exerted on the sphere: bold upper F equals upper F bold e 1 equals 6 pi mu upper R v Subscript infinity Baseline bold e 1. This force is called the Stokes drag.

      For our purposes, we need not examine the calculation of upper F in detail. Instead, we use a simpler dimensional analysis, exploiting concepts from elementary linear algebra, to deduce the functional form of the drag force. Since the only parameters in the boundary‐value problem are mu, v Subscript infinity, and upper R, any solution to the problem of calculating upper F defines a relationship of the form

      for some function phi. By a theorem widely attributed to American physicist Edgar Buckingham [31], this relationship, involving variables that have physical dimensions, implies the existence of an equivalent relationship

normal upper Phi left-parenthesis normal upper Pi 1 comma normal upper Pi 2 comma ellipsis right-parenthesis equals 0

      involving only dimensionless variables normal upper Pi 1 comma normal upper Pi 2 comma ellipsis Appendix C reviews this theorem.

      Arbitrarily picking n 4 equals negative 1 yields the single dimensionless variable normal upper Pi equals upper F mu Superscript negative 1 Baseline v Subscript infinity Superscript negative 1 Baseline upper R Superscript negative 1; all other dimensionless variables for this problem must be multiples of this product.

      The calculation in Exercise 2.13 shows that any relationship equivalent to Eq. (2.22) but involving only dimensionless variables has the form normal upper Phi left-parenthesis normal upper Pi right-parenthesis equals 0. Solutions to such an equation are constant values of normal upper Pi. Setting normal upper Pi equals upper C for a generic constant upper C, we conclude that Stokes drag has the form

      This result is consistent with that of Stokes's original calculation, except that we have an undetermined constant upper C instead of 6 pi.

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