physicsyd.au/teach_res/jp/fluids09

1. http://www.physics.usyd.edu.au/teach_res/jp/fluids09 web notes: lect5.ppt

2. Assume an IDEAL FLUID Fluid motion is very complicated. However, by making some assumptions, we can develop a useful model of fluid behaviour. An ideal fluid is Incompressible – the density is constant Irrotational – the flow is smooth, no turbulence Nonviscous – fluid has no internal friction (=0) Steady flow – the velocity of the fluid at each point is constant in time.

3. A simple model EQUATION OF CONTINUITY (conservation of mass) A 1 A 2 DV Dt What changes ? volume flow rate? Speed? Q= DV Dt Q=

4. EQUATION OF CONTINUITY (conservation of mass) A 1 A 2 v 1 v 2 In complicated patterns of streamline flow, the streamlines effectively define flow tubes. where streamlines crowd together the flow speed increases.

5. EQUATION OF CONTINUITY (conservation of mass) m1 = m2  V1 =  V2 A1v1 t = A2v2 t A1v1 = A2v2 =Q=V/ t =constant Applications Rivers Circulatory systems Respiratory systems Air conditioning systems

6. Blood flowing through our body The radius of the aorta is ~ 10 mm and the blood flowing through it has a speed ~ 300 mm.s-1. A capillary has a radius ~ 410-3 mm but there are literally billions of them. The average speed of blood through the capillaries is ~ 510-4 m.s-1. Calculate the effective cross sectional area of the capillaries and the approximate number of capillaries. How would you implement the problem solving scheme Identify Setup Execute Evaluate ?

7. Identify / Setup aorta RA = 1010-3 m AA = cross sectional area of aorta = ? capillaries RC = 410-6 m AC = cross sectional area of capillaries = ? N = number of capillaries = ? speed thru. aorta vA = 0.300 m.s-1 speed thru. capillaries vC = 510-4 m.s-1 Assume steady flow of an ideal fluid and apply the equation of continuity Q = A v = constant AAvA = ACvC Execute AC = AA (vA / vC) =  RA2(vA / vC) AC = = 0.20 m2 If N is the number of capillaries then AC = N RC2 N = AC / (RC2) = 0.2 / { (410-6)2} N = 4109 aorta capillaries

8. IDEAL FLUID BERNOULLI'S PRINCIPLE How can a plane fly? How does a perfume spray work? What is the venturi effect? Why does a cricket ball swing or a baseball curve?

9. Daniel Bernoulli (1700 – 1782)

10. A1 A1 A2 Fluid flow

11. A1 A1 A2 v2 v1 v1 Streamlines closer Relationship between speed & density of streamlines? How about pressure?

12. A1 A1 A2 v2 v1 v1 Low speed Low KE High pressure high speed high KE low pressure Streamlines closer Low speed Low KE High pressure

13. p large p large p small v small v large v small

14. In a serve storm how does a house loose its roof? Air flow is disturbed by the house. The "streamlines" crowd around the top of the roof faster flow above house reduced pressure above roof than inside the house room lifted off because of pressure difference. Why do rabbits not suffocate in the burrows? Air must circulate. The burrows must have two entrances. Air flows across the two holes is usually slightly different slight pressure difference forces flow of air through burrow. One hole is usually higher than the other and the a small mound is built around the holes to increase the pressure difference. Why do racing cars wear skirts?

15. VENTURI EFFECT ?

16. VENTURI EFFECT Flow tubes Eq Continuity low pressure velocity increased pressure decreased high pressure (patm)

17. What happens when two ships or trucks pass alongside each other? Have you noticed this effect in driving across the Sydney Harbour Bridge?

18. force high speed low pressure force

19. artery Flow speeds up at constriction Pressure is lower Internal force acting on artery wall is reduced External forces are unchanged Artery can collapse Arteriosclerosis and vascular flutter

20. Bernoulli’s Principle Conservation of energy energy densities Work W = F d = p A d = p V W / V = p KE K = ½ m v2 = ½  V v2 K / V = ½  v2 PE U = m g h =  V g h U / V =  g h Along a streamline p + ½  v2 +  g h = constant

21. Bernoulli’s Principle Y X t i m e 2 What has changed between 1 and 2? r t i m e 1

22. A better model: Bernoulli’s

23. Derivation of Bernoulli's equation Mass element m moves from (1) to (2) m = A1 x1 = A2 x2 = VwhereV = A1 x1 = A2 x2 Equation of continuity A V = constant A1v1 = A2v2A1 > A2 v1 < v2 Since v1 < v2 the mass element has been accelerated by the net force F1 – F2 = p1A1 – p2A2 Conservation of energy A pressurized fluid must contain energy by the virtue that work must be done to establish the pressure. A fluid that undergoes a pressure change undergoes an energy change.

24. K = ½ m v22 - ½ m v12 = ½ Vv22 - ½ V v12 U = m g y2 – m g y1 = V g y2 = V g y1 Wnet = F1x1 – F2 x2 = p1A1 x1 – p2A2 x2 Wnet = p1V – p2V= K + U p1V – p2V = ½ Vv22 - ½ V v12 + V g y2 - V g y1 Rearranging p1 + ½ v12 + g y1 = p2 + ½ v22 + g y2 Applies only to an ideal fluid (zero viscosity)

25. Bernoulli’s Equation • for any point along a flow tube or streamline • p + ½ v2 +  g y = constant • Dimensions • p [Pa] = [N.m-2] = [N.m.m-3] = [J.m-3] • ½ v2 [kg.m-3.m2.s-2] = [kg.m-1.s-2] = [N.m.m-3] = [J.m-3] • g h [kg.m-3 m.s-2. m] = [kg.m.s-2.m.m-3] = [N.m.m-3] = [J.m-3] • Each term has the dimensions of energy / volume or energy density. • ½ v 2 KE of bulk motion of fluid • g h GPE for location of fluid • p pressure energy density arising from internal forces within • moving fluid (similar to energy stored in a spring)