Sears–Haack body

The Sears–Haack body is the shape with the lowest theoretical wave drag in supersonic flow, for a given body length and given volume. The mathematical derivation assumes small-disturbance (linearized) supersonic flow, which is governed by the Prandtl–Glauert equation. The derivation and shape were published independently by two separate researchers: Wolfgang Haack in 1941 and later by William Sears in 1947.[1]

Sears–Haack body

The theory indicates that the wave drag scales as the square of the second derivative of the area distribution, (see full expression below), so for low wave drag it is necessary that be smooth. Thus, the Sears–Haack body is pointed at each end and grows smoothly to a maximum and then decreases smoothly toward the second point.

Useful formulas

The cross-sectional area of a Sears–Haack body is

its volume is

its radius is

the derivative (slope) is

the second derivative is

where:

  • x is the ratio of the distance from the nose to the whole body length (this is always between 0 and 1),
  • r is the local radius,
  • is the radius at its maximum (occurs at center of the shape),
  • V is the volume,
  • L is the length.

From Slender-body theory, it follows that:

alternatively:

These formulae may be combined to get the following:

where:

  • is the wave drag,
  • is the density of the fluid,
  • U is the velocity.

Generalization by R. T. Jones

The Sears–Haack body shape derivation is correct only in the limit of a slender body. The theory has been generalized to slender but non-axisymmetric shapes by Robert T. Jones in NACA Report 1284.[2] In this extension, the area is defined on the Mach cone whose apex is at location , rather than on the plane as assumed by Sears and Haack. Hence, Jones's theory makes it applicable to more complex shapes like entire supersonic aircraft.

Area rule

A superficially related concept is the Whitcomb area rule, which states that wave drag due to volume in transonic flow depends primarily on the distribution of total cross-sectional area, and for low wave drag this distribution must be smooth. A common misconception is that the Sears–Haack body has the ideal area distribution according to the area rule, but this is not correct. The Prandtl–Glauert equation, which is the starting point in the Sears–Haack body shape derivation, is not valid in transonic flow, which is where the area rule applies.

gollark: If your text editor obtains enough IDE features, then great, I might also use that.
gollark: IDEs are helpfuL! They have autocomplete and syntax highlighting!
gollark: ddg! asmbb
gollark: Write forum software in it!
gollark: Yes, they're actually really very competent somehow.

See also

References

  1. Palaniappan, Karthik (2004). Bodies having Minimum Pressure Drag in Supersonic Flow – Investigating Nonlinear Effects (PDF). 22nd Applied Aerodynamics Conference and Exhibit. Antony Jameson. Retrieved 2010-09-16.
  2. NACA Report 1284, Theory of Wing-Body Drag at Supersonic Speeds, by Robert T. Jones, 8 July 1953
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.