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- 1. Fluids at Rest APowerPoint Presentation by Mashilane M Sphs000 Exam pre
- 2. HOT AIR BALLOONS use heatedair, which is less dense than the surrounding air, to create an upward buoyant force. According to Archi- medes’ Principle, the buoyant force is equal to the weight of the air displaced by the balloon. Fluids at Rest Paul E. Tippens
- 3. Objectives: After completingthis module, you should be able to: • Define and apply the concepts of density and fluid pressure to solve physical problems. • Define and apply concepts of absolute, gauge, and atmospheric pressures. • State Pascal’s law and apply for input and output pressures. • State and apply Archimedes’ Principle to solve physical problems.
- 4. Mass Density 2 kg,4000 cm3 Wood 177 cm3 45.2 kg ; mass m Density volume V = = Lead: 11,300 kg/m3 Wood: 500 kg/m3 4000 cm3 Lead Same volume 2 kg Lead Same mass
- 5. Example 1: Thedensity of steel is 7800 kg/m3. What is the volume of a 4-kg block of steel? 4 kg 3 4 kg ; 7800 kg/m m m V V = = = V = 5.13 x 10-4 m3 What is the mass if the volume is 0.046 m3? 3 3 (7800 kg/m )(0.046 m ); m V = = m = 359 kg
- 6. Relative Density The relativedensity r of a material is the ratio of its density to the density of water (1000 kg/m3). Steel (7800 kg/m3) r = 7.80 Brass (8700 kg/m3) r = 8.70 Wood (500 kg/m3) r = 0.500 Examples: 3 1000 kg/m x r =
- 7. Pressure Pressure is theratio of a force F to the area A over which it is applied: Pressure ; Force F P Area A = = A = 2 cm2 1.5 kg 2 -4 2 (1.5 kg)(9.8 m/s ) 2 x 10 m F P A = = P = 73,500 N/m2
- 8. The Unit ofPressure (Pascal): A pressure of one pascal (1 Pa) is defined as a force of one newton (1 N) applied to an area of one square meter (1 m2). 2 1 Pa = 1 N/m Pascal: In the previous example the pressure was 73,500 N/m2. This should be expressed as: P = 73,500 Pa
- 9. Fluid Pressure A liquidor gas cannot sustain a shearing stress - it is only restrained by a boundary. Thus, it will exert a force against and perpendicular to that boundary. • The force F exerted by a fluid on the walls of its container always acts perpendicular to the walls. Water flow shows ⊥ F
- 10. Fluid Pressure Fluid exertsforces in many directions. Try to submerse a rubber ball in water to see that an upward force acts on the float. • Fluids exert pressure in all directions. F
- 11. Pressure vs. Depthin Fluid Pressure = force/area ; ; mg P m V V Ah A = = = Vg Ahg P A A = = h mg Area • Pressure at any point in a fluid is directly proportional to the density of the fluid and to the depth in the fluid. P = gh Fluid Pressure:
- 12. Independence of Shapeand Area. Water seeks its own level, indicating that fluid pressure is independent of area and shape of its container. • At any depth h below the surface of the water in any column, the pressure P is the same. The shape and area are not factors.
- 13. Properties of FluidPressure • The forces exerted by a fluid on the walls of its container are always perpendicular. • The fluid pressure is directly proportional to the depth of the fluid and to its density. • At any particular depth, the fluid pressure is the same in all directions. • Fluid pressure is independent of the shape or area of its container.
- 14. Example 2. Adiver is located 20 m below the surface of a lake ( = 1000 kg/m3). What is the pressure due to the water? h = 1000 kg/m3 DP = gh The difference in pressure from the top of the lake to the diver is: h = 20 m; g = 9.8 m/s2 3 2 (1000 kg/m )(9.8 m/s )(20 m) P D = DP = 196 kPa
- 15. Atmospheric Pressure atm atm h Mercury P= 0 One way to measure atmospheric pressure is to fill a test tube with mercury, then invert it into a bowl of mercury. Density of Hg = 13,600 kg/m3 Patm = gh h = 0.760 m Patm = (13,600 kg/m3)(9.8 m/s2)(0.760 m) Patm = 101,300 Pa
- 16. Absolute Pressure Absolute Pressure:The sum of the pressure due to a fluid and the pressure due to atmosphere. Gauge Pressure: The difference between the absolute pressure and the pressure due to the atmosphere: Absolute Pressure = Gauge Pressure + 1 atm h DP = 196 kPa 1 atm = 101.3 kPa DP = 196 kPa 1 atm = 101.3 kPa Pabs = 196 kPa + 101.3 kPa Pabs = 297 kPa
- 17. Pascal’s Law Pascal’s Law:An external pressure applied to an enclosed fluid is transmitted uniformly throughout the volume of the liquid. Fout Fin Aout Ain Pressure in = Pressure out in out in out F F A A =
- 18. Example 3. Thesmaller and larger pistons of a hydraulic press have diameters of 4 cm and 12 cm. What input force is required to lift a 4000 N weight with the output piston? Fout Fin Aout t Ain ; in out out in in in out out F F F A F A A A = = 2 2 (4000 N)( )(2 cm) (6 cm) in F = 2 ; 2 D R Area R = = F = 444 N Rin= 2 cm; R = 6 cm
- 19. Archimedes’ Principle • Anobject that is completely or partially submerged in a fluid experiences an upward buoyant force equal to the weight of the fluid displaced. 2 lb 2 lb The buoyant force is due to the displaced fluid. The block material doesn’t matter.
- 20. Calculating Buoyant Force FB= f gVf Buoyant Force: h1 mg Area h2 FB The buoyant force FB is due to the difference of pressure DP between the top and bottom surfaces of the submerged block. 2 1 2 1 ; ( ) B B F P P P F A P P A D = = − = − 2 1 2 1 ( ) ( ) B f f F A P P A gh gh = − = − 2 1 2 1 ( ) ( ); ( ) B f f F g A h h V A h h = − = − Vf is volume of fluid displaced.
- 21. Example 4: A2-kg brass block is attached to a string and submerged underwater. Find the buoyant force and the tension in the rope. All forces are balanced: mg FB = gV T Force diagram FB + T = mg FB = wgVw 3 2 kg ; 8700 kg/m b b b b b b m m V V = = = Vb = Vw = 2.30 x 10-4 m3 Fb = (1000 kg/m3)(9.8 m/s2)(2.3 x 10-4 m3) FB = 2.25 N
- 22. Example 4 (Cont.):A 2-kg brass block is attached to a string and submerged underwater. Now find the the tension in the rope. mg FB = gV T Force diagram FB + T = mg T = mg - FB FB = 2.25 N T = (2 kg)(9.8 m/s2) - 2.25 N T = 19.6 N - 2.25 N T = 17.3 N This force is sometimes referred to as the apparent weight.
- 23. Floating objects: When anobject floats, partially submerged, the buoyant force exactly balances the weight of the object. FB mg FB = f gVf mx g = xVx g f gVf = xVx g f Vf = xVx Floating Objects: If Vf is volume of displaced water Vwd, the relative density of an object x is given by: Relative Density: x wd r w x V V = =
- 24. Example 5: Astudent floats in a salt lake with one-third of his body above the surface. If the density of his body is 970 kg/m3, what is the density of the lake water? 1/3 2/3 Assume the student’s volume is 3 m3. Vs = 3 m3; Vwd = 2 m3; s = 970 kg/m3 w Vwd = sVs 3 w 3 3 2 m ; 3 m 2 s wd s w s V V = = = 3 w 3 3(970 kg/m ) 2 2 s = = w = 1460 kg/m3
- 25. Problem Solving Strategy 1.Draw a figure. Identify givens and what is to be found. Use consistent units for P, V, A, and . 2. Use absolute pressure Pabs unless problem involves a difference of pressure DP. 3. The difference in pressure DP is determined by the density and depth of the fluid: 2 1 m F ; = ; P = V A P P gh − =
- 26. Problem Strategy (Cont.) 4.Archimedes’ Principle: A submerged or floating object experiences an buoyant force equal to the weight of the displaced fluid: B f f f F m g gV = = 5. Remember: m, r and V refer to the displaced fluid. The buoyant force has nothing to do with the mass or density of the object in the fluid. (If the object is completely submerged, then its volume is equal to that of the fluid displaced.)
- 27. Problem Strategy (Cont.) 6.For a floating object, FB is equal to the weight of that object; i.e., the weight of the object is equal to the weight of the displaced fluid: x or x f x f f m g m g V V = = FB mg
- 28. Summary ; mass m Density volume V == 3 1000 kg/m x r = Pressure ; Force F P Area A = = 2 1 Pa = 1 N/m Pascal: P = gh Fluid Pressure:
- 29. Summary (Cont.) FB =f gVf Buoyant Force: Archimedes’ Principle: in out in out F F A A = Pascal’s Law:
- 30. CONCLUSION: Fluids at Rest anyquestion?