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Archimede’s Principle An object immersed in a fluid has an upward (buoyant) force equal to the weight of the fluid it displaces. F B =  gV F B = buoyant.

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Presentation on theme: "Archimede’s Principle An object immersed in a fluid has an upward (buoyant) force equal to the weight of the fluid it displaces. F B =  gV F B = buoyant."— Presentation transcript:

1 Archimede’s Principle An object immersed in a fluid has an upward (buoyant) force equal to the weight of the fluid it displaces. F B =  gV F B = buoyant force  = mass density of the fluid g = acc. due to gravity V = volume of the fluid displaced

2 Floating Since apparent weight = 0, the weight of the object = weight of the fluid displaced (or buoyant force). W app = 0 so W obj = F B = W fd Volume of the fluid displaced = volume of the submerged part of the object. V fd = V submerged density of the object < density of the fluid

3 Sinking The object can’t displace enough fluid to equal its own weight. W obj > F B The volume of the fluid displaced = the volume of the object. V fd = V obj W app = W air - F B W app = apparent weight W air = weight of object in air (= mg) F B = buoyant force (= W fd =  f Vg)

4 Pressure Force per unit area Units: Pa (N/m 2 ) P = pressure F=force A= area

5 Pascal’s Principle Pressure applied to a fluid is transmitted throughout that fluid unchanged in all directions. Pressure increases in a fluid with depth  P =  g  h, where  = density of fluid, g= acc. due to gravity, and  h = height of the fluid column The shape of the container has no effect on pressure. Only Depth! The pressure at the bottom of the each is the same.

6 Hydraulics Machines using hydraulics use fluids to multiply forces. These machines have a small piston and a large piston connected by a chamber filled with hydraulic fluid. P 1 =P 2 so… F 1 /A 1 = F 2 /A 2 Pressure is constant MA = F 2 / F 1 = A 2 / A 1

7 Bernouilli’s Principle As the velocity of a fluid increases, the pressure exerted by that fluid decreases. (not valid for turbulent flow)

8 Applications of Bernouilli’s Principle Lift on an airplane wing - air has to travel farther over the top of the wing, so velocity is greater and pressure is less on top of the wing than underneath. Spoilers on a race car - opposite of the airplane wing.

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