Difference between revisions of "Sears-Haack body"

Explanation
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=== Does the Sears-Haack body follow Whitcomb’s area rule? ===
 
=== Does the Sears-Haack body follow Whitcomb’s area rule? ===
 
No, it does not. The [[Whitcomb area rule|area rule]] finds its application in the reduction of wave drag at transonic speeds. Sears-Haack body is a theoretical shape for supersonic flow, derived from the Prandtl-Glauert equation, which itself is valid only in subsonic and supersonic flows and not in a transonic flow.
 
No, it does not. The [[Whitcomb area rule|area rule]] finds its application in the reduction of wave drag at transonic speeds. Sears-Haack body is a theoretical shape for supersonic flow, derived from the Prandtl-Glauert equation, which itself is valid only in subsonic and supersonic flows and not in a transonic flow.
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=== Why rockets are not shaped like Sears-Haack body? ===

Revision as of 10:52, 5 January 2017

Explanation

A mathematically generated Sears-Haack body.

Sears-Haack body is the theoretical fuselage design that produces the most efficient supersonic flight for a certain volume and diameter with the lowest possible wave drag. The area distribution is as smooth as possible and it follows a profile as shown in the picture.

Frequently Asked Questions

Does the Sears-Haack body follow Whitcomb’s area rule?

No, it does not. The area rule finds its application in the reduction of wave drag at transonic speeds. Sears-Haack body is a theoretical shape for supersonic flow, derived from the Prandtl-Glauert equation, which itself is valid only in subsonic and supersonic flows and not in a transonic flow.

Why rockets are not shaped like Sears-Haack body?