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Need. In 2050 15% of the Earths carbon dioxide emissions will be from aircrafts (U.S. Global Change Research, 2001) $61billion has already been spent in aviation for fuel alone (Segelstein, 2008) - PowerPoint PPT PresentationTRANSCRIPT
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Need In 2050 15% of the Earths carbon dioxide emissions will be from aircrafts (U.S. Global Change Research, 2001)$61billion has already been spent in aviation for fuel alone (Segelstein, 2008)If the drag coefficient of a car was reduced by .1 the U.S. oil consumption would decrease by 7.5%. This would save 10 billion gallons of fuel per year
Golf Ball Suspension System (GBSS) (Libii, 2005)
Purpose The purpose of this experiment is to use golf ball dimpling as a model to improve aerodynamic The purpose of this experiment is to use golf ball dimpling as a model to improve aerodynamic efficiency. This may be applied to trucks, or airplane propellers and in turn decrease fuel consumption. efficiency. This may be applied to trucks, or airplane propellers and in turn decrease fuel consumption.
Hypotheses Field TestField TestNull Hypothesis H(o)Null Hypothesis H(o)- The golf balls will all travel the same distance and have the same accuracy. - The golf balls will all travel the same distance and have the same accuracy. Alternate Hypothesis H(a)Alternate Hypothesis H(a)- The golf balls with the greatest number of dimples will travel the furthest- The golf balls with the greatest number of dimples will travel the furthestAlternate Hypothesis H(a)1- Alternate Hypothesis H(a)1- The dimpleless golf ball will be the most accurate. The dimpleless golf ball will be the most accurate. Lab TestLab TestNull Hypothesis H(o)- Null Hypothesis H(o)- The golf balls will all have the same drag force. The golf balls will all have the same drag force. Alternate Hypothesis H(a)- Alternate Hypothesis H(a)- The drag force will decrease as the numbers of dimples increase.The drag force will decrease as the numbers of dimples increase.Alternative Hypothesis H(a)- Alternative Hypothesis H(a)- The dimple characteristics of hexx, smooth, steep, and dimpleless will The dimple characteristics of hexx, smooth, steep, and dimpleless will yield progressively greater drag forces.yield progressively greater drag forces.
http://www.dimpletape.com/article.htm
boojum.as.arizona.eduwww.callawaygolf.com/Global/en-GB/Innovation/GolfBallTechnology/ HEXAerodynamics.html
http://www.eng.monash.edu.au/uicee/worldtransactions/WordTransAbstractsVol5No3/23_NjockLibii15.pdf
http://pdf.aiaa.org/preview/CDReadyMAAC03_774/PV2003_3662.pdf
Drag Coefficients for Conventionally Dimpled, Hexx, and Dimpleless Sphere Bearman and Harvey (1976)
Laminar vs. Turbulent Flow Flow Around Smooth Sphere Flow Around Dimpled Sphere
•Ogg, 2004- Development of the hexx ball
•Libi, 2005- Golf Ball Suspension System
•Kato, 2005- Steep versus dimpled sphere
•Bearman and Harvey (1976)- graph representing the drag coefficients of hexx ball, conventional ball, and smooth sphere
Smooth Dimples
Steep Dimples
Smooth vs. Steep Dimples (Kato, 2005)
Figure 1- This picture shows the possible dimpling of an airplane propeller. Although just a prototype should dimples be proved to reduce drag, they could greatly decrease fuel consumption.
Figure 2- This picture shows the two types of flow around an object; laminar and turbulent. Laminar or streamline flow is when a fluid flows in parallel layers. The opposite of this flow is turbulent flow, which is when a fluid undergoes irregular fluctuations or mixing.
Figure 3 Figure 4Figures 3,4,and 5 all show the flow around different spheres. In figure 3 the wake around the smooth sphere is considerably larger compared to the dimpled or hexxgolf ball sphere. This larger wake increases drag. Figure 4 shows the flow around a dimpled sphere and the wake behind that ball is thinner meaning less drag. Finally in figure 5 the airflow around the hexxgolf ball is shown and exhibits an even smaller airflow, decreasing drag to an even greater extent.
Figure 5
Knowledge Base
http://www.aviation-history.com/theory/lam-flo
Literature Review
Figure 6
Figure 7
Figure 8
Figure 6 compares the smooth dimples to steep dimples. Results showed that the flow around the sphere with the smooth dimples created less drag.
Figure 7 shows the GBSS inside a wind tunnel. As the wind starts to flow the ball creates an angle with the protractor. In the experiment a dimpled sphere was compared to a smooth sphere. The results showed that the dimpled sphere had a lower drag force.
Figure 8- The x-axis shows the initial velocity (m/s) while the y-axis shows the drag coefficient. The results of the experiment showed that at higher speeds the hexx ball has a lower drag coefficient compared to a smooth sphere, and conventionally dimpled sphere.
http://www.aviation-history.com/theory/lam-flo
Drag Force=Mass*Graviy*Tan(