IMPROVED VELOCITY POTENTIAL FORMULATIONS OF HIGHLY ACCURATE BOUSSINESQ-TYPE MODELS

SummaryThe approximate supersonic flow past a slender ducted body of revolution having an annular intake is determined by using the Heaviside operational calculus applied to the linearised equation for the velocity potential. It is assumed that the external and internal flows are independent. The pressures on the body are integrated to find the drag, lift and moment coefficients of the external forces. The lift and moment coefficients have the same values as for a slender body of revolution without an intake, but the formula for the drag has extra terms given in equations (32) and (56). Under extra assumptions, the lift force due to the internal pressures is estimated. The results are applicable to propulsive ducts working under the specified condition of no “ spill-over “ at the intake.

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Local Dynamic Path Planning for an Ambulance Based on Driving Risk and Attraction Field

Sustainability ◽

10.3390/su13063194 ◽

2021 ◽

Vol 13 (6) ◽

pp. 3194

Author(s):

Fang Zong ◽

Meng Zeng ◽

Yang Cao ◽

Yixuan Liu

Keyword(s):

Path Planning ◽

Potential Field ◽

Velocity Potential ◽

Attractive Potential ◽

Local Dynamic ◽

Repulsive Potential ◽

Ambulance Personnel ◽

Lane Changing ◽

Dynamic Path Planning ◽

Dynamic Path

Path planning is one of the most important aspects for ambulance driving. A local dynamic path planning method based on the potential field theory is presented in this paper. The potential field model includes two components—repulsive potential and attractive potential. Repulsive potential includes road potential, lane potential and obstacle potential. Considering the driving distinction between an ambulance and a regular vehicle, especially in congested traffic, an adaptive potential function for a lane line is constructed in association with traffic conditions. The attractive potential is constructed with target potential, lane-velocity potential and tailgating potential. The design of lane-velocity potential is to characterize the influence of velocity on other lanes so as to prevent unnecessary lane-changing behavior for the sake of time-efficiency. The results obtained from simulation demonstrate that the proposed method yields a good performance for ambulance driving in an urban area, which can provide support for designing an ambulance support system for the ambulance personnel and dispatcher.

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Contracting ducts of finite length

Aeronautical Quarterly ◽

10.1017/s0001925900000469 ◽

1951 ◽

Vol 2 (4) ◽

pp. 254-271 ◽

Cited By ~ 22

Author(s):

L. G. Whitehead ◽

L. Y. Wu ◽

M. H. L. Waters

Keyword(s):

Stream Function ◽

Finite Length ◽

Velocity Potential ◽

Three Dimensional ◽

Relaxation Method ◽

Two Dimensional ◽

Dimensional Flow ◽

Hodograph Plane ◽

Two Dimensional Flow ◽

Working Section

SummmaryA method of design is given for wind tunnel contractions for two-dimensional flow and for flow with axial symmetry. The two-dimensional designs are based on a boundary chosen in the hodograph plane for which the flow is found by the method of images. The three-dimensional method uses the velocity potential and the stream function of the two-dimensional flow as independent variables and the equation for the three-dimensional stream function is solved approximately. The accuracy of the approximate method is checked by comparison with a solution obtained by Southwell's relaxation method.In both the two and the three-dimensional designs the curved wall is of finite length with parallel sections upstream and downstream. The effects of the parallel parts of the channel on the rise of pressure near the wall at the start of the contraction and on the velocity distribution across the working section can therefore be estimated.

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Diffraction of plane elastic waves by a crack, with application to a problem of brittle fracture

Journal of the Australian Mathematical Society ◽

10.1017/s1446788700028354 ◽

1963 ◽

Vol 3 (3) ◽

pp. 325-339 ◽

Cited By ~ 2

Author(s):

M. Papadopoulos

Keyword(s):

Elastic Waves ◽

Scattered Field ◽

Velocity Potential ◽

Elastic Solid ◽

Step Function ◽

Free Surface Waves ◽

Dependent Variables ◽

Smooth Plane ◽

New Feature ◽

Set Up

AbstractA crack is assumed to be the union of two smooth plane surfaces of which various parts may be in contact, while the remainder will not. Such a crack in an isotropic elastic solid is an obstacle to the propagation of plane pulses of the scalar and vector velocity potential so that both reflected and diffracted fields will be set up. In spite of the non-linearity which is present because the state of the crack, and hence the conditions to be applied at the surfaces, is a function of the dependent variables, it is possible to separate incident step-function pulses into either those of a tensile or a compressive nature and the associated scattered field may then be calculated. One new feature which arises is that following the arrival of a tensile field which tends to open up the crack there is necessarily a scattered field which causes the crack to close itself with the velocity of free surface waves.

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Fluid Pressures on Unanchored Rigid Flat-Bottom Cylindrical Tanks Under Action of Uplifting Acceleration

Journal of Pressure Vessel Technology ◽

10.1115/1.4000374 ◽

2009 ◽

Vol 132 (1) ◽

Cited By ~ 1

Author(s):

Tomoyo Taniguchi ◽

Yoshinori Ando

Keyword(s):

Velocity Potential ◽

Fluid Velocity ◽

Fluid Pressure ◽

Angular Acceleration ◽

Bottom Plate ◽

Center Line ◽

Cylindrical Tank ◽

Cylindrical Coordinates ◽

Flat Bottom ◽

Cylindrical Tanks

To protect flat-bottom cylindrical tanks against severe damage from uplift motion, accurate evaluation of accompanying fluid pressures is indispensable. This paper presents a mathematical solution for evaluating the fluid pressure on a rigid flat-bottom cylindrical tank in the same manner as the procedure outlined and discussed previously by the authors (Taniguchi, T., and Ando, Y., 2010, “Fluid Pressures on Unanchored Rigid Rectangular Tanks Under Action of Uplifting Acceleration,” ASME J. Pressure Vessel Technol., 132(1), p. 011801). With perfect fluid and velocity potential assumed, the Laplace equation in cylindrical coordinates gives a continuity equation, while fluid velocity imparted by the displacement (and its time derivatives) of the shell and bottom plate of the tank defines boundary conditions. The velocity potential is solved with the Fourier–Bessel expansion, and its derivative, with respect to time, gives the fluid pressure at an arbitrary point inside the tank. In practice, designers have to calculate the fluid pressure on the tank whose perimeter of the bottom plate lifts off the ground like a crescent in plan view. However, the asymmetric boundary condition given by the fluid velocity imparted by the deformation of the crescent-like uplift region at the bottom cannot be expressed properly in cylindrical coordinates. This paper examines applicability of a slice model, which is a rigid rectangular tank with a unit depth vertically sliced out of a rigid flat-bottom cylindrical tank with a certain deviation from (in parallel to) the center line of the tank. A mathematical solution for evaluating the fluid pressure on a rigid flat-bottom cylindrical tank accompanying the angular acceleration acting on the pivoting bottom edge of the tank is given by an explicit function of a dimensional variable of the tank, but with Fourier series. It well converges with a few first terms of the Fourier series and accurately calculates the values of the fluid pressure on the tank. In addition, the slice model approximates well the values of the fluid pressure on the shell of a rigid flat-bottom cylindrical tank for any points deviated from the center line. For the designers’ convenience, diagrams that depict the fluid pressures normalized by the maximum tangential acceleration given by the product of the angular acceleration and diagonals of the tank are also presented. The proposed mathematical and graphical methods are cost effective and aid in the design of the flat-bottom cylindrical tanks that allow the uplifting of the bottom plate.

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