Rookie
Let's suppose you are designing a supercar with a narrow cabin and a wide track.
What would be more aerodynamic?
A. To have a narrow body with the wheels being covered by wide fender flares. Maybe somewhat streamlined fender flares.
B. To have a wider body covering the wheels.
Furniture
Just to let you know, instead of starting multiple threads, there is a thread where you can ask all these questions.
The Technical Questions Thread - Page 81 - Ultimatecarpage.com forums
Enthusiast
A very well designed set of flares has the potential to be more aero (less change in cross sectional area at the cabin), but most are not well designed.Originally Posted by Eggnog
Chief of Secret Police and CFO - Brotherhood of Jelly
No Mr. Craig, I expect you to die! On the inside. Of heartbreak. You emo bitch
Rookie
check out the box fish, you dont need a tear drop shape to have low drag
http://en.wikipedia.org/wiki/Mercedes-Benz_Bionic
a good modern example of shape optimization is the 2012 Nissan GTR. basically looks exactly the same as the 2011 model
Enthusiast
coefficient of drag = cross sectional area
Gone:
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Current:
10 BMW 335d
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Rookie
Please elaborate.
I don't understand how flares can provide LESS change in cross section area. If you get a narrow body and wide flares the difference in area would be larger than a wide body which has more or less a constant area.
Enthusiast
You asked which is more aerodynamic; simply put, the lowest CD should be most efficient... but isn't determined by frontal area alone.
It may be achieved both fendered or by complete coverage of the wheels (flares or not) but there are many other calculations required.
To wit:
CD = Coefficient of Drag is a reflection of the aerodynamic efficiency of the shape
CL = Coefficient of Lift
CS = Coefficient of Side Force
q = Dynamic Pressure in the Test Section
r = Mass Density of Air
A = Frontal Area of Vehicle
V = Velocity
Which brings us to an example of the required energy to propel an object to designed terminal velocity:
HP = (DV)/550 = (CDqAV)/550 = (CDA 1/2 r V2)V / 550 = (CDA 1/2 rV3)/ 550
Wherein
D = Drag Force
CD = Coefficient of Drag is a reflection of the aerodynamic efficiency of the shape
V = Velocity
q = Dynamic Pressure in the Test Section
A = Frontal Area of Vehicle
r = Mass Density of Air
Aerodynamic Drag:
CD: Coefficient of Drag
Invariant with velocity unless there is Reynolds Number sensitivity. The lower the CD the more efficient the shape is to the air.
With a reference frontal area of 21 ft2, a production car will have a CD around the 0.340 range
CDA: Coefficient of Drag Area
Coefficient of Drag x Area: CD x A
Reynolds Number: the ratio of inertial forces (vsρ) to viscous forces (μ/L) and consequently it quantifies the relative importance of these two types of forces for given flow conditions.
Dynamic Pressure: (PSF) A2 measures the test section speed in q which is the dynamic pressure.
q = ½ r V2
Flow Rate: (ft3/minute)
CFM = Area (ft2) x Speed (ft/min)
Source: APPENDIX
Last edited by csl177; 12-26-2011 at 09:40 PM. Reason: added source
Never own more cars than you can keep charged batteries in...
Enthusiast
For a closed cockpit, i.e. Sedan/Coupe type car if the flares taper in at the front as the windscreen slopes up, and taper out at the back as the rear window tapers down then the cross section or the car has the potential to remain constant.
If, however, you have an open cockpit car eg Lotus 7, Sprite, etc running no windscreen, or only a tiny air deflector then the cockpit has no additional cross sectional area and you would be generally better off going for the wider body.
General rules of thumb only, you must measure to make sure! That is why I quoted Eggnog.
Chief of Secret Police and CFO - Brotherhood of Jelly
No Mr. Craig, I expect you to die! On the inside. Of heartbreak. You emo bitch
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