Ch. 9 Fluids

1. Ch. 9 Fluids • Problems: 1, 9, 13, 21, 27, 35. • pressure & pascal’s principle • buoyancy & archimedes’ principle • (sections 7-11)

2. Giambattista: • compressibility • pressure • /

3. Density r = mass/volume • SI Unit: kg/m3 • common unit: 1 g/cm3 = 1,000 kg/m3 • Example densities: • Water: r = 1.00 g/cm3 • Aluminum: r = 2.70 g/cm3 • Iron: r = 7.87 g/cm3 • Lead: r = 11.3 g/cm3

4. Pressure, p • p = force/area • Unit: pascal, Pa • 1 Pa = 1N/m2. • Example: 100N applied to 0.25m2. Pressure = 100/0.25 = 400N/m2.

5. Gauge Pressure is Differential Pressure Pgauge = P – Patm

6. Depth and Fluid Pressure • P = Po + rgd • P is the pressure at depth d. • Po is the pressure at the fluid surface • r is the fluid density • Example: increase in pressure at a depth of 1m in water = (1,000)(9.8)(1.0) Pa

7. Barometer

8. Pascal’s Principle

9. Buoyancy and Archimedes’ Principle

10. L=0.5m cube of steel in water • Vo = L3 = (0.5m)3 = 0.125 m3 • FB = (fl.density)(Vo)(g) • = (1,000kg/m3 )(0.125 m3 )(9.8N/kg) • = 1,225 N • W = mg = {(… kg/m3 )(… m3 )}(g) • = (7,800)(0.125)(9.8) • = 9,555 N • Weight under water: • W’ = W – FB = 8,330 N

11. 1kg object is weighed in water • W’ = 9.2N. What is its density? • FB = W – W’ = 9.8N – 9.2N = 0.6N • FB = (fl.den.)(ob.vol.)(g) = 0.6N • FB = (1000)(ob.vol.)(g) = 0.6N • (ob.vol.) = 6.12x10-5cubic meter • (ob.den.) = mass/vol. = 1kg/(6.12x10-5) • 16,333 kg/m3. = 16.333 g/cm3. • This is not pure gold.

12. S.G. Method Density is 16.33 x density of water, or 16.33 gram/cc.

13. Summary • Pressure and its Variation with Depth • Pascal’s Principle • Archimedes Principle • (Continuity Equation (conservation of mass) • Bernoulli’s Equation (conservation of energy) • Viscosity and Viscous Drag • Surface Tension)

14. Solid Deformation stress = force/area = pressure strain = fractional change in length Solid Moduli ~ stress/strain ~ stiffness Hooke’s Law is force/strain: k = F/x 14

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16. Solid Deformation Length Change: stress = F/A, strain = DL/Lo, Ex. Hooke’s Law F = kDx Young’s Modulus, Y = stress/strain. Volume Change: stress = F/A = p, strain = -DV/Vo, Bulk Modulus, B = -Dp/(DV/Vo) 16

17. Example: Object mass 0.150kg density 2g/cm3 is weighed in water.

19. Example: calculate speed water exits the hole in terms of the given parameters.

22. 10cm Cube Submerged in Water • Bottom surface is 10cm deeper than top. • P2 = P1 + (fl.density)(g)(d) • Net force = (P2-P1)(Area) • = (fl.density)(g)(d)(0.1m)2. • = (1000)(9.8)(0.1m)(0.1m)2. • = 9.8N • Mass of (1cc = 1mL) of water = 1gram. • (10cm)3 = 1000cc = 1000grams = 1kg • Weight of 1kg is 9.8N

23. Ex. Pascal principle • One piston moves d1= 5cm, another piston moves d2 = 0.10cm. What is the MA (mechanical advantage) of this hydraulic system? • MA = 5cm/0.10cm = 50 • e.g. if F1 = 2N, F2 = 2Nx50 = 100N

24. Ex2. Pascal principle • One piston has diameter D1= 5cm, another piston D2 = 10cm. What is the MA (mechanical advantage) of this hydraulic system? • MA = (D2/D1)^2 = (10cm/5cm)^2 = 4

25. Object weighs 5N in air and 3N in water. What is its density? • S.G. = (ob.den/wat.den) • =(mog/mwg) • =(5N/2N) • =2.5=2.5gram/cc

26. Object has density 6gram/cc, mass 1kg. What is its apparent mass in water?

27. Water density & Volume • 1cc = 1mL • Density of water: • 1gram/cc = 1gram/mL • Ex: 25 mL of water has mass 25grams • Mass = rhoxVolume • =1gram/mL x 25mL = 25grams