Calculate Distance for 5ft-lbs Impact w/ 1.18lb Sphere

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To calculate the vertical distance needed for a 5 ft-lbs impact with a 1.18 lb sphere, equate potential and kinetic energies using the formula E = mgh, where E is energy, m is mass, g is acceleration due to gravity, and h is height. The mass of the sphere converts to approximately 0.535 kg, and the impact energy is equivalent to 6.8 Joules. By rearranging the formula to solve for height (h), the distance can be calculated as h = E/(mg), leading to h = 5 ft / 1.18 lbs. This results in a distance of approximately 4.24 feet needed to achieve the desired impact energy. Understanding these principles allows for accurate calculations in impact testing scenarios.
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Hello,

I am probably going to suffer some embarassment, once I see the answer to my question. Anwyay, I need to calculate the distance needed to create a 5ft-lbs. impact with a 1.18lb. sphere being dropped vertically onto a surface.

How would I go about calucating the vertical distance needed?

This is for an impact test from UL, where the mass and impact force are defined, but the distance is not.

Please help a newbie. :rolleyes:
 
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(well I abhor those english units, but I reckon the principles are the same). what i like even less are words like "impact." since its in ft-lb, I assume they are looking for energy.

there are a few ways to go about this, but usually the most direct is to equate potntial and kinetic energies

wt*h=1/2Mv^2=impact energy
 
Still unclear...

So if the Mass of the sphere (M) = 1.18 lbs = .535kg & the impact force = 5 ft. lbs. = 6.8 Joules, then is the velocity = to acceleration by gravity ~ 9.8m/s^2?

So it's .5(.535kg * (9.8 m/s^2)) = 6.8 Joules ??
 
If your you want your final kinetic energy to be E, then use E=mgh. Or like denverdoc said, E=F*d (force times distance). Gravitational force is 1.18 lbs, you want 5 ft-lbs of impact energy, so d=E/F=(5/1.18) ft.
 

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