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Chapter 13 T . Norah Ali Al moneef 1 •Motion is steady: velocity, density, pressure at a given point don’t change •Moves without turbulence T . Norah Ali Al moneef 2 Steady/Unsteady flow • • • • In steady flow the velocity of particles is constant with time Unsteady flow occurs when the velocity at a point changes with time. Turbulence is extreme unsteady flow where the velocity vector at a point changes quickly with time e.g. water rapids or waterfall. When the flow is steady, streamlines are used to represent the direction of flow. Steady flow is sometimes called streamline flow • Streamlines never cross. A set of streamlines can define a tube of flow, the borders of which the fluid does not cross Turbulent Flow Turbulent flow is an extreme kind of unsteady flow and occurs when there are sharp obstacles or bends in the path of a fastmoving fluid. In turbulent flow, the velocity at a point changes erratically from moment to moment, both in magnitude and direction. T . Norah Ali Al moneef 3 Viscous/Non viscous flow • • • • A viscous fluid such as honey does not flow readily, it has a large viscosity. Water has a low viscosity and flows easily. A viscous flow requires energy dissipation. Zero viscosity – requires no energy. with no dissipation of energy. Some liquids can be taken to have zero viscosity e.g. water. • An incompressible, non viscous fluid is said to be an ideal fluid T . Norah Ali Al moneef 4 T . Norah Ali Al moneef 5 13. 2 Stream flow . NorahAli Ali Al T . TNorah Almoneef moneef 6 The volume flow rate, Q is defined as the volume of fluid that flows past an imaginary (or real) interface. A v represents the volume of fluid per second that passes through the tube and is called the volume flow rate Q T . Norah Ali Al moneef 7 • If the fluid is incompressible, the density remains constant throughout Q Av A1v1 A2v2 • Av represents the volume of fluid per second that passes through the tube and is called the volume flow rate Q V Ax Avt This just means that the amount of fluid moving in any “section of pipe” must remain constant. •If the area is reduced the fluid must speed up! • Speed is high where the pipe is narrow and speed is low where the pipe has a large diameter T . Norah Ali Al moneef 8 The product of the area and the fluid speed at all points along a pipe is constant for an incompressible fluid. T . Norah Ali Al moneef 9 Q: Have you ever used your thumb to control the water flowing from the end of a hose? A: When the end of a hose is partially closed off, thus reducing its cross-sectional area, the fluid velocity increases. This kind of fluid behavior is described by the equation of continuity. Example: Oil is flowing at a speed of 1.22 m/s through a pipeline with a radius of 0.305 m. How much oil flows in 1 day? T . Norah Ali Al moneef 10 example example • A river flows in a channel that is 40. m wide and 2.2 m deep with a speed of 4.5 m/s. • The river enters a gorge that is 3.7 m wide with a speed of 6.0 m/s. • How deep is the water in the gorge? The area is width times depth. A1 = w1d1 Use the continuity equation. v1A1 = v2A2 v1w1d1 = v2w2d2 Solve for the unknown d2. d2 = v1w1d1 / v2w2 =(4.5 m/s)(40. m)(2.2 m) / (3.7m)(6.0 m/s) = 18 m T . Norah Ali Al moneef 11 example T . Norah Ali Al moneef 12 example If pipe 1 diameter = 50mm, mean velocity 2m/s, pipe 2 diameter 40mm takes 30% of total discharge and pipe 3 diameter 60mm. What are the values of discharge and mean velocity in each pipe? T . Norah Ali Al moneef 13 example T . Norah Ali Al moneef 14 example example T . Norah Ali Al moneef 15 Example: The volume rate of flow in an artery supplying the brain is 3.6x10-6 m3/s. If the radius of the artery is 5.2 mm, A) determine the average blood speed. B) Find the average blood speed if a constriction reduces the radius of the artery by a factor of 3 (without reducing the flow rate). T . Norah Ali Al moneef 16 Example: T . Norah Ali Al moneef 17 Example if the cross-section area, A, is 1.2 x 10-3m2 and the discharge, Q is 24 l / s , then the mean velocity, Example if the area A 1 = 10 x10-3 m2 and A 2 = 3 x10-3 m 2 and the upstream mean velocity, 1 = 2.1 m / s , then the downstream mean velocity T . Norah Ali Al moneef 18 Example, decrease in area of stream of water coming from tap. T . Norah Ali Al moneef 19 • • Example: The figure shows 3 straight pipes through which water flows. The figure gives the speed of the water in each pipe. Rank them according to the volume of water that passes through the cross-sectional area per minute, greatest first. 6 same Example: • • • • Water flows smoothly through the pipe shown in the figure, descending in the process. Rank the four numbered sections of pipe according to (a) the volume flow rate Q through them (b) the flow speed v through them (c) the water pressure p within them, greatest first. T . Norah Ali Al moneef a)Same b) 1,2,3,4 c ) 4,3,2,1 20 1) 2) 3) T . Norah Ali Al moneef 21 Pressure Pressure P is the magnitude of the force acting perpendicular to a surface divided by the area A over which the force acts. The greater the force, the greater the pressure is. The greater the area, the smaller the force is. T . Norah Ali Al moneef 22 example T . Norah Ali Al moneef 23 Example The mattress of a water bed is 2.00m long by 2.00m wide and 30.0cm deep. a) Find the weight of the water in the mattress. The volume density of water at the normal condition (0oC and 1 atm) is 1000kg/m3. So the total mass of the water in the mattress is m W VM 1000 2.00 2.00 0.300 1.20 103 kg Therefore the weight of the water in the mattress is W mg 1.20 103 9.8 1.18 10 4 N b) Find the pressure exerted by the water on the floor when the bed rests in its normal position, assuming the entire lower surface of the mattress makes contact with the floor. Since the surface area of the mattress is 4.00 m2, the pressure exerted on the floor is F mg 1.18 10 4 3 2 . 95 10 P A A 4.00 T . Norah Ali Al moneef 24 • Relates pressure to fluid speed and elevation • Bernoulli’s equation is a consequence of Work Energy Relation applied to an ideal fluid • Assumes the fluid is incompressible and nonviscous, and flows in a nonturbulent, steady-state manner T . Norah Ali Al moneef 25 P2 A P1A area A T . Norah Ali Al moneef 26 This work is negative because the force on the segment of ﬂuid is to the left and the displacement is to the right. Thus, the net work done on the segment by these forces in the time interval T . Norah Ali Al moneef 27 T . Norah Ali Al moneef 28 • States that the sum of the pressure, kinetic energy per unit volume, and the potential energy per unit volume has the same value at all points along a streamline T . Norah Ali Al moneef 29 Bernoulli’s Principle • In steady flow, the speed, pressure and elevation of an ideal fluid are related. Two situations. • (1) Horizontal pipe, changing Area A. – Pressure drop in thin pipe why? – Fluid speeds – acceleration – force required • (2) Elevation change but same area A – Lower fluid is under more pressure T . Norah Ali Al moneef T . Norah Ali Al moneef 30 Atmospheric Pressure • The atmosphere exerts a pressure on the surface of the Earth and all objects at the surface • Atmospheric pressure is generally taken to be 1.00 atm = 1.013 x 105 Pa = Patm T . Norah Ali Al moneef 31 13.4 static consequences of Bernoulli's equation Fluid At Rest In a Container : •Pressure in a continuously distributed uniform static fluid varies only with vertical distance and is independent of the shape of the container. • The pressure is the same at all points on a given horizontal plane in a fluid. Y a = y b = y c = yd • For liquids, which are incompressible, we have: pb + ρgh1 = patm + ρgh2 yA =yB=yC=yD pb = patm + ρg (h2 - h1) = patm + ρgd d h2 h1 T . Norah Ali Al moneef 32 Absolute Pressure and Gauge Pressure The pressure P is called the absolute pressure , because it is the actual value of the system’s pressure. Remember, P = Patm + ρ g h P – Patm = ρ g h ( so ρ g h is the gauge pressure) Gauge pressure: Pressure expressed as the difference between the pressure of the fluid and that of the surrounding atmosphere Usual pressure gauges record gauge pressure. To calculate absolute pressure: P = P atm + P gauge As a fluid moves along if it changes speed or elevation then the pressure changes and vice versa. Bernoulli’s equation is really just conservation of energy for the fluid • Bernoulli’s equation. • P + ½ ρv2 + ρg h = constant • Bernoulli’s equation shows that as the velocity of a fluid speeds up it’s pressure goes down…..this idea used in airplane wings and frisbees (difference in pressure leads to upward force we call Lift) T . Norah Ali Al moneef 33 PA>PB PA=PC PA – Patm = ρ g h P Patm gh PA = PB = PC = PD • P atm is atmospheric pressure =1.013 x 105 Pa • The pressure does not depend upon the shape of the container T . Norah Ali Al moneef 34 Variation of Pressure with Depth • If a fluid is at rest in a container, all portions of the fluid must be in static equilibrium • All points at the same depth must be at the same pressure – Otherwise, the fluid would not be in equilibrium • Pressure changes with elevation •The pressure gradient in the vertical direction is negative • The pressure decreases as we move upward in a fluid at rest • Pressure in a liquid does not change due to the shape of the container • The fluid would flow from the higher pressure region to the lower pressure region •the pressure at a point in a fluid depends only on density, gravity and depth T . Norah Ali Al moneef 35 example T . Norah Ali Al moneef 36 the Manometer is a device to measure pressures. A common simple manometer consists of a U shaped tube of glass filled with some liquid. Typically the liquid is mercury because of its high density Case 1 both ends of the tube are open to the atmosphere. Thus both points A and B are at atmospheric pressure. The two points also have the same vertical height. Case 2 the top of the tube on the left has been closed. We imagine that there is a sample of gas in the closed end of the tube. The right side of the tube remains open to the atmosphere. The point A, then, is at atmospheric pressure. The point C is at the pressure of the gas in the closed end of the tube. The point B has a pressure greater than atmospheric pressure due to the weight of the column of liquid of height h. The point C is at the same height as B, so it has the same pressure as B. And we have already seen that this is equal to the pressure of the gas in the closed end of the tube. Thus, in this case the pressure of the gas that is trapped in the closed end of the tube is greater than atmospheric pressure by the amount of pressure exerted by the column of liquid of height h. T . Norah Ali Al moneef 37 Case 3 Perhaps the closed end of the tube contains a sample of gas as before, or perhaps it contains a vacuum. The point A is at atmospheric pressure. The point C is at whatever pressure the gas in the closed end of the tube has, or if the closed end contains a vacuum the pressure is zero. Since the point B is at the same height as point A, it must be at atmospheric pressure too. But the pressure at B is also the sum of the pressure at C plus the pressure exerted by the weight of the column of liquid of height h in the tube. We conclude that pressure at C, then, is less than atmospheric pressure by the amount of pressure exerted by the column of liquid of height h. If the closed end of the tube contains a vacuum, then the pressure at point C is zero, and atmospheric pressure is equal to the pressure exerted by the weight of the column of liquid of height h. In this case, the manometer can be used as a barometer to measure atmospheric pressure. T . Norah Ali Al moneef 38 Pressure Measurements: The manometer • Manometers are devices in which one or more columns of a liquid are used to determine the pressure difference between two points. • • • U-tube manometer One end of the U-shaped tube is open to the atmosphere The other end is connected to the pressure to be measured P P P P gy P P gy P gy P gy P P gy gy P Patm g ( y 2 y1 ) A B A B atm A A 1 2 1 atm atm 2 2 1 P Patm gh T . Norah Ali Al moneef 39 • Pressure at B is P=Patm+ρgh Pressure at A > Patm Pressure in a continuous static fluid is the same at any horizontal level so, Pressure at A = Pressure at B P A = P B = Patm+ ρgh . NorahAli Ali Al T . TNorah Almoneef moneef 40 Blood Pressure measurements by cannulation Pressure at c =pressure at D PC = PD PC = PA + ρsgh PB = Patm + ρ gh PA + ρsgh = Patm + ρ gh PA = Patm + ρ g h – ρsgh Pblood =PA = Patm + ρ g h – ρsgh T . Norah Ali Al moneef 41 Blood Pressure Sphygmometer • Blood pressure is measured with a special type of manometer called a sphygmomano-meter • Pressure is measured in mm of mercury T . Norah Ali Al moneef 42 Pressure with depth Estimate the amount by which blood pressure changes in an actuary in the foot P2 and in the aorta P1 when the person is lying down and standing up Take density of blood = 1060kg/m3 Lying down P2 P1 gh 0 Pa s tan ding P2 P1 1060 9.8 1.35 1.4 10 4 Pa T . Norah Ali Al moneef 43 26.8 K P a T . Norah Ali Al moneef 44 example A fluid of constant density ρ = 960 kg / m3 is flowing steadily through the above tube. The diameters at the sections are d 1 =100 mm and d 2 = 80 mm . The gauge pressure at 1 is p1 = 200 k N/ m2 ,and the velocity here is u 1 = 5 m /s . We want to know the gauge pressure at section 2. The tube is horizontal, with y1 = y2 so Bernoulli gives us the following equation for pressure at section 2: P2 = 2 x10 5 + 960 { 52 – ( 7.8 )2} /2 = 182796.8 pa T . Norah Ali Al moneef 45 An example of the U-Tube manometer Using a u-tube manometer to measure gauge pressure of fluid density ρ = 700 kg/m3, and the manometric fluid is mercury, with a relative density of 13.6. What is the gauge pressure if: h1 = 0.4m and h2 = 0.9m? pB = pC pB = pA + ρgh1 pB = pAtmospheric + ρman gh2 We are measuring gauge pressure so patmospheric =0 pA = ρman gh2 - ρgh1 a) pA = 13.6 x 103 x 9.81 x 0.9 - 700 x 9.81 x 0.4 = 117 327 N, b) pA = 13.6 x 103 x 9.81 x (-0.1) - 700 x 9.81 x 0.4 = -16 088.4 N, The negative sign indicates that the pressure is below atmospheric T . Norah Ali Al moneef 46 example A MANOMETER (U-TUBE) is a variation of the Barometer in which the pressure of two gases may be compared. Here the difference in the pressures of the gases on the arms of the manometer is equal to the pressure 'exerted' by the column of fluid, ph = ρ g h. T . Norah Ali Al moneef 47 Example: The horizontal constricted pipe illustrated in the Figure, known as a Venturi tube, can be used to measure the flow speed of an incompressible fluid. Determine the flow speed at point 2 if the pressure difference P1 & P2 is known. T . Norah Ali Al moneef 48 example Calculate the column height of water corresponding to a pressure of 50 kPa P=ρgh h = P/ρg = 50 X 103 / 10 3 X 9.8 = 5.1 m T . Norah Ali Al moneef 49 Example: Fluid is flowing from left to right through the pipe. Points A and B are at the same height, but the cross-sectional areas of the pipe differ. Points B and C are at different heights, but the cross-sectional areas are the same. Rank the pressures at the three points, from highest to lowest. A) A and B (a tie), C B) C, A and B (a tie) C) B, C, A D) C, B, A E) A, B, C E) PA > PB > PC T . Norah Ali Al moneef 50 Example: A stream of water of water d = 0.10 m flows steadily from a tank of diameter D = 1.0 m as shown in the figure. What flow-rate is needed from the inlet to maintain a constant water volume in the header tank depth? The depth of water at the outlet is 2.0 m . Can regard outlet as a free jet (note water level at (1) is not going down). T . Norah Ali Al moneef 51 Pressure Measurements: • A long closed tube is filled with mercury and inverted in a dish of mercury • Measures atmospheric pressure as ρ g h •Since the closed end is at vacuum, it does not exert any force. Vacuum pressure = 0 Patm Patm gh h g p=0 patm Vacuum! h For mercury, h = 760 mm. How high will water rise? No more than h = patm/g = 10.3 m T . Norah Ali Al moneef 52 example erusaem ew erehw si ro dnuorg eht no si eloh eht emussa( We can set atm. So we have1 evah osla eW .)morf thgieh h T . Norah Ali Al moneef v2 53 example T . Norah Ali Al moneef 54 T . Norah Ali Al moneef 55 example P2 =p1 + ρ (v12 –v22 ) / 2 = 180X103 + 103X(22 – 182) = 20X 103 pa T . Norah Ali Al moneef 56 example T . Norah Ali Al moneef 57 T . Norah Ali Al moneef 58 If a fluid is at rest in a container, all portions of the fluid must be in static equilibrium • If the height doesn’t change much, Bernoulli becomes: y1 = y2 P1 12 v12 P2 12 v22 FL • Where speed is higher, pressure is lower. • Speed is higher on the long surface of the wing – creating a net force of lift. T . Norah Ali Al moneef 59 example T . Norah Ali Al moneef 60 example T . Norah Ali Al moneef 61 Water flows through the pipe as shown at a rate of .015 m3/s. If water enters the lower end of the pipe at 3.0 m/s, what is the pressure difference between the two ends? 1.5m A2 = 20 cm2 Q AV Q 0.015 7.5 m /s V 2 A 20 4 10 1 1 2 2 g g y y p V V 1 2 1 1 2 2 2 2 1 2 2 p1 p2 2 V 2 V 1 g y 2 y1 1 3 2 2 3 P 10 7.5 3 10 9.8 1.5 2 p T . Norah Ali Al moneef 62 T . Norah Ali Al moneef 63 Example Estimate the force exerted on your eardrum due to the water above when you are swimming at the bottom of the pool with a depth 5.0 m. We first need to find out the pressure difference that is being exerted on the eardrum. Then estimate the area of the eardrum to find out the force exerted on the eardrum. Since the outward pressure in the middle of the eardrum is the same as normal air pressure P Patm W gh 1000 9.8 5.0 4.9 10 4 Pa Estimating the surface area of the eardrum at 1.0cm2=1.0x10-4 m2, we obtain F P P0 A 4.9 10 4 1.0 10 4 4.9 N T . Norah Ali Al moneef 64 Absolute and Relative Pressure How can one measure pressure? One can measure pressure using an open-tube manometer, where one end is connected to the system with unknown pressure P and the other open h to air with pressure P0. The measured pressure of the system P P gh 0 is This is called the absolute pressure, because it is the actual value of the system’s pressure. In many cases we measure pressure difference with P P0 gh respect to atmospheric pressure due to changes in P0 depending on the environment. This is called gauge or relative pressure. P P0 The common barometer which consists of a mercury column with one end closed at vacuum and the other open to the atmosphere was invented by Evangelista Torricelli. Since the closed end is at vacuum, P0 gh (13.595 103 kg / m3 )(9.80665m / s 2 )(0.7600m) it does not exert any force. 1 atm is 1.013 105 Pa 1atm T . Norah Ali Al moneef 65 Q: Is it possible to stand on the roof of a five-story (20 m) building and drink, using a straw, from a glass on the ground? Even if a person could completely remove all of the air from the straw, the height to which the outside air pressure pushes the water up the straw would not be high enough for him/her to drink the water, no matter how hard he/she sucks T . Norah Ali Al moneef 20m 66 Applications of Bernoulli's Equation The tarpaulin that covers the cargo is flat when the truck is stationary but bulges outward when the truck is moving. T . Norah Ali Al moneef 67 •Air speeds up in the constricted space between the car & truck creating a low-pressure area. Higher pressure on the other outside pushes them together. •Hold two sheets of paper together, as shown here, and blow between them. No matter how hard you blow, you cannot push them more than a little bit apart! T . Norah Ali Al moneef 68 T . Norah Ali Al moneef 69