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11/05/2012PHY 113 A Fall 2012 -- Lecture 261 PHY 113 A General Physics I 9-9:50 AM MWF Olin 101 Plan for Lecture 26: Chapter 14: The physics of fluids.

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Presentation on theme: "11/05/2012PHY 113 A Fall 2012 -- Lecture 261 PHY 113 A General Physics I 9-9:50 AM MWF Olin 101 Plan for Lecture 26: Chapter 14: The physics of fluids."— Presentation transcript:

1 11/05/2012PHY 113 A Fall 2012 -- Lecture 261 PHY 113 A General Physics I 9-9:50 AM MWF Olin 101 Plan for Lecture 26: Chapter 14: The physics of fluids 1.Density and pressure 2.Variation of pressure with height 3.Buoyant forces

2 11/05/2012 PHY 113 A Fall 2012 -- Lecture 262

3 11/05/2012PHY 113 A Fall 2012 -- Lecture 263 The physics of fluids. Fluids include liquids (usually “incompressible) and gases (highly “compressible”). Fluids obey Newton’s equations of motion, but because they move within their containers, the application of Newton’s laws to fluids introduces some new forms.  Pressure: P=force/area 1 (N/m 2 ) = 1 Pascal  Density:  =mass/volume 1 kg/m 3 = 0.001 gm/ml Note: In this chapter P  pressure (NOT MOMENTUM)

4 11/05/2012PHY 113 A Fall 2012 -- Lecture 264 Pressure Note: since P exerted by a fluid acts in all directions, it is a scalar parameter

5 11/05/2012PHY 113 A Fall 2012 -- Lecture 265 Example of pressure calculation High heels ( http://www.flickr.com/photos/moffe6/3771468287/lightbox /) http://www.flickr.com/photos/moffe6/3771468287/lightbox F

6 11/05/2012PHY 113 A Fall 2012 -- Lecture 266 Pressure exerted by air at sea-level 1 atm = 1.013x10 5 Pa Example: What is the force exerted by 1 atm of air pressure on a circular area of radius 0.08m? F = PA = 1.013x10 5 Pa x  (0.08m) 2 = 2040 N P atm

7 11/05/2012PHY 113 A Fall 2012 -- Lecture 267 Density = Mass/Volume

8 11/05/2012PHY 113 A Fall 2012 -- Lecture 268 Relationship between density and pressure in a fluid Effects of the weight of a fluid: y  g  y = mg/A P(y+  y) P(y) Note: In this formulation +y is defined to be in the up direction.

9 11/05/2012PHY 113 A Fall 2012 -- Lecture 269 For an “incompressible” fluid (such as mercury):  = 13.585 x 10 3 kg/m 3 (constant)  x 10 3 kg/m 3 Example:

10 11/05/2012PHY 113 A Fall 2012 -- Lecture 2610 Barometric pressure readings Historically, pressure was measured in terms of inches of mercury in a barometer  x 10 3 kg/m 3

11 11/05/2012PHY 113 A Fall 2012 -- Lecture 2611 Weather report :

12 11/05/2012PHY 113 A Fall 2012 -- Lecture 2612 Question: Consider the same setup, but replace fluid with water (  = 1000 kg/m 3 ). What is h?  kg/m 3 iclicker equation: Will water barometer have h: A.Greater than mercury. B.Smaller than mercury. C.The same as mercury.

13 11/05/2012PHY 113 A Fall 2012 -- Lecture 2613 Question: Consider the same setup, but replace fluid with water (  = 1000 kg/m 3 ). What is h?  kg/m 3

14 11/05/2012PHY 113 A Fall 2012 -- Lecture 2614 iclicker question: A 0.5 m cylinder of water is inverted over a piece of paper. What will happen A.The water will flow out of the cylinder and make a mess. B.Air pressure will hold the water in the cylinder.

15 11/05/2012PHY 113 A Fall 2012 -- Lecture 2615 General relationship between P and 

16 11/05/2012PHY 113 A Fall 2012 -- Lecture 2616 P (atm) y-y 0 (mi) Approximate relation of pressure to height above sea-level

17 11/05/2012PHY 113 A Fall 2012 -- Lecture 2617 iclicker question: Have you personally experienced the effects of atmospheric pressure variations? A.By flying in an airplane B.By visiting a high-altitude location (such as Denver, CO etc.) C.By visiting a low-altitude location (such as Death Valley, CA etc.) D.All of the above. E.None of the above.

18 11/05/2012PHY 113 A Fall 2012 -- Lecture 2618 Buoyant forces in fluids (For simplicity we will assume that the fluid is incompressible.) Image from the web of a floating iceberg. Image from the web of a glass of ice water

19 11/05/2012PHY 113 A Fall 2012 -- Lecture 2619 Buoyant force for fluid acting on a solid: F B =  fluid V displaced g mg F B  mg = 0  fluid V submerged g   solid V solid g = 0 A yy

20 11/05/2012PHY 113 A Fall 2012 -- Lecture 2620 Summary: Some densities: ice  = 917 kg/m 3 fresh water  = 1000 kg/m 3 salt water  = 1024 kg/m 3

21 11/05/2012PHY 113 A Fall 2012 -- Lecture 2621 iclicker question: Suppose you have a boat which floats in a fresh water lake, with 50% of it submerged below the water. If you float the same boat in salt water, which of the following would be true? A.More than 50% of the boat will be below the salt water. B.Less than 50% of the boat will be below the salt water. C.The submersion fraction depends upon the boat's total mass and volume. D.The submersion fraction depends upon the barometric pressure.

22 11/05/2012PHY 113 A Fall 2012 -- Lecture 2622 Archimede’s method of finding the density of the King’s “gold” crown W water W air

23 11/05/2012PHY 113 A Fall 2012 -- Lecture 2623 Application of Newton’s second law to fluid (near Earth’s surface) Summary:

24 11/05/2012PHY 113 A Fall 2012 -- Lecture 2624 iclicker question: Suppose that a caterer packed some food in an air tight container with a flexible top at sea-level. This food was loaded on to an airplane with a cruising altitude of ~6 mi above the earth’s surface. Assuming that the airplane cabin is imperfectly pressurized, what do you expect the container to look like during the flight? (A) (B) (C)

25 11/05/2012PHY 113 A Fall 2012 -- Lecture 2625 Example: Hydraulic press incompressible fluid A 1  x 1 =A 2  x 2 F 1 /A 1 = F 2 /A 2

26 11/05/2012PHY 113 A Fall 2012 -- Lecture 2626

27 11/05/2012PHY 113 A Fall 2012 -- Lecture 2627

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