Model of a strong discontinuity for the equations of spatial long waves propagating in a free-boundary shear flow

Teshukov, V. M.; Khe, A. K.

doi:10.1007/s10808-008-0086-3

Cited by 1 publication

(7 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the present section, use is made of the discontinuity relations obtained in [5] for the equations of stationary flows (1.2). It is shown that the set of states behind the jump is determined by some curve similar to the (θ, p)-polar curve in gas dynamics.…”

Section: Flows With Discontinuitiesmentioning

confidence: 99%

“…System (1.2) cannot be reduced to divergent form. In [5], it is proposed to use the following form of system (1.2), which is equivalent to the initial one for smooth solutions: (2.1)…”

Section: Flows With Discontinuitiesmentioning

confidence: 99%

“…It has been shown [5] that in this class of functions, the notion of a solution with a strong discontinuity is defined correctly [i.e., Eqs. (2.1) are meaningful in the class of generalized functions] and system (2.1) defines discontinuity relations.…”

Section: Flows With Discontinuitiesmentioning

confidence: 99%

“…Square brackets denote the jump of the function across the discontinuity: [ϕ] = ϕ 2 − ϕ 1 (subscript 1 corresponds to the state ahead of the discontinuity front; subscript 2 to the state behind the front). Strong-discontinuity relations for the model of spatial shear flows were derived in [5]. In the case of stationary flows, these relations become…”

Section: Flows With Discontinuitiesmentioning

confidence: 99%

“…It has also been proved [5] that the flow parameters behind the front of the jump are determined uniquely, given the flow parameters ahead of the jump, the velocity of the front, and the normal vector to the jump front.…”

Section: Flows With Discontinuitiesmentioning

confidence: 99%

See 4 more Smart Citations

Strong discontinuities in spatial stationary long-wave flows of an ideal incompressible fluid

Khe

2009

J Appl Mech Tech Phy

Self Cite

View full text Add to dashboard Cite

Spatial stationary flows over an even bottom of a heavy ideal fluid with a free surface are considered. Jump relations for flows with a strong discontinuity are studied. It is shown that the flow parameters behind the jump are defined by a certain curve which is an analog of the (θ, p) diagram in gas dynamics. A shock polar and examples of flows with a hydraulic jump are constructed for a particular class of solutions.Introduction. The long-wave approximation is widely used in the theoretical analysis of wave processes because, for real fluids, the asymptotics of solutions at large times is determined by long waves, due to the presence of viscosity. In addition, this approximation provides new results in analytical studies of nonlinear wave processes. The integrodifferential model of stationary ideal fluid flows studied in the present paper considers velocity shear along the vertical and is more complex than the classical shallow-water model.Shear plane-parallel flows with discontinuities were studied in [1], and barotropic fluid flows in [2]. Generalized characteristics and hyperbolicity conditions for systems of integrodifferential shallow-water equations describing spatial stationary shear flows of a free-boundary ideal fluid layer were obtained in [3], and theory of spatial simple waves was constructed in [4].The system of equations describing stationary long waves in spatial ideal fluid flows are not reduced to divergent form. It has been noted [5] that the flow equations can be rearranged so that the nondivergent terms are regular discontinuous functions. This allows one to consider solutions in the class of functions with a strong discontinuity and to derive jump relations from these equations. In the present paper, the indicated approach is used to study stationary hydraulic jumps. Relations linking the flow parameters behind the jump are found, and analogs of (θ, p) diagrams of two-dimensional gas dynamics are proposed. The problem of interaction of spatial shear flows is solved for a definite class.1. Formulation of the Problem. We consider the long-wave equations describing spatial stationary flows of an ideal incompressible fluid in a gravity field:

show abstract

Section: Flows With Discontinuitiesmentioning

confidence: 99%

“…System (1.2) cannot be reduced to divergent form. In [5], it is proposed to use the following form of system (1.2), which is equivalent to the initial one for smooth solutions: (2.1)…”

Section: Flows With Discontinuitiesmentioning

confidence: 99%

Section: Flows With Discontinuitiesmentioning

confidence: 99%

Section: Flows With Discontinuitiesmentioning

confidence: 99%

Section: Flows With Discontinuitiesmentioning

confidence: 99%

See 3 more Smart Citations