The Mathematics of Fluid Flow Through Porous Media. Myron B. Allen, III. Читать онлайн. Newlib. NEWLIB.NET

Информация о произведении:

Автор:	Myron B. Allen, III
Издательство:	John Wiley & Sons Limited
Серия:
Жанр произведения:	Математика
Год издания:	0
isbn:	9781119663874

Скачать книгу

Equation (2.7) is the differential mass balance.

Exercise 2.2 Verify the principle used to derive Eq. (2.7) from the integral equation (2.6). An argument by contradiction may be the easiest approach: Assume that the integrand on the left side of Eq. (2.6) is positive at some point bold x at some time . Since this function is continuous, it must be positive in a neighborhood of bold x at time . Consider a fixed region contained in this neighborhood. A similar argument dispatches the possibility that the integrand is negative at some point.

Exercise 2.3 Justify the following equivalent of the mass balance (2.7):

(2.8) StartFraction upper D rho Over upper D t EndFraction plus rho nabla dot bold v equals 0 period

The differential mass balance in the form (2.8) facilitates another observation. In certain motions, the density following any particle is constant. In this case, upper D rho slash upper D t equals 0 , so the mass balance implies that

In this case, we say that the motion is incompressible. This concept does not imply anything about the material being modeled; it merely describes the motion based on properties of the velocity field. A compressible material can undergo incompressible motion.

The mass balance is the simplest of the balance laws of continuum mechanics. Other balance laws include the momentum balance, the angular momentum balance, and the energy balance. A related thermodynamic law known, as the entropy inequality, also plays an important role in many settings. In each of these laws, an integral version is fundamental, and it is possible to derive differential versions under certain continuity conditions. For a detailed review of the integral balance laws and the derivation of their differential versions, see [4]. With the exception of several applications of the mass balance discussed in Chapters 5 and 6, the remainder of this book focuses on differential balance laws.

2.2.2 Momentum Balance

The differential momentum balance equation is

(2.9) StartLayout 1st Row rho StartFraction upper D bold v Over upper D t EndFraction minus nabla dot sans-serif upper T minus rho bold b equals bold 0 comma EndLayout

often called Cauchy's first law. (For its derivation from an integral form, see [4, Chapter 4]. Strictly speaking, the momentum balance states that there exists a frame of reference in which Cauchy's first law holds.) Each term in Eq. (2.9) is a vector‐valued function having dimension normal upper M normal upper L Superscript negative 2 Baseline normal upper T Superscript negative 2 . Thus, Cauchy's first law comprises three scalar PDEs.

The terms in Eq. (2.9) require explanation. First, with respect to any orthonormal basis StartSet bold e 1 comma bold e 2 comma bold e 3 EndSet ,

bold v dot nabla equals sigma-summation Underscript j equals 1 Overscript 3 Endscripts v Subscript j Baseline StartFraction partial-differential Over partial-differential x Subscript j Baseline EndFraction comma

so applying this operator to bold v yields

StartLayout 1st Row 1st Column StartFraction upper D bold v Over upper D t EndFraction equals left-parenthesis StartFraction partial-differential Over partial-differential t EndFraction plus bold v dot nabla right-parenthesis bold v 2nd Column equals left-parenthesis StartFraction partial-differential Over partial-differential t EndFraction plus sigma-summation Underscript j equals 1 Overscript 3 Endscripts v Subscript j Baseline StartFraction partial-differential Over partial-differential x Subscript j Baseline EndFraction right-parenthesis sigma-summation Underscript i equals 1 Overscript 3 Endscripts v Subscript i Baseline bold e Subscript i Baseline 2nd Row 1st Column Blank 2nd Column equals sigma-summation Underscript i equals 1 Overscript 3 Endscripts left-parenthesis StartFraction partial-differential v Subscript i Baseline Over partial-differential t EndFraction plus sigma-summation Underscript j equals 1 Overscript 3 Endscripts v Subscript j Baseline StartFraction partial-differential v Subscript i Baseline Over partial-differential x Subscript j Baseline EndFraction right-parenthesis bold e Subscript i Baseline comma EndLayout

which is clearly a vector‐valued function.

Second, the function bold b left-parenthesis bold x comma t right-parenthesis represents the body force per unit mass, having dimension normal upper L normal upper T Superscript negative 2 . In this book, the only body force of interest is gravity, and bold b reduces to the gravitational acceleration near Earth's surface. The total body force acting on a part of the body is

integral Underscript script upper V Endscripts rho bold b d v comma

where script upper V is the region occupied by the part.

Third, the function sans-serif upper T left-parenthesis bold x comma t right-parenthesis is the stress tensor. This entity deserves more extended discussion, starting with the term tensor. A second‐order tensor is a linear transformation that maps vectors into vectors. Its geometric action remains fixed under changes in coordinate systems, a requirement discussed in more detail in Section 3.7. The stress tensor is a linear transformation that describes a type of force different from the body force.

More specifically, any part of a body occupying a region script upper V in three‐dimensional space can experience forces acting

Скачать книгу