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How air and water move things

How air and water move things. Bernoulli’s law and Magnus force. Hydrostatic pressure. Blaise Pascal. P = ρ gh. Hydrostatic pressure. ρ= fluid/gas density g =acceleration due to gravity h =height. P = ρ gh. Pressure in liquid/gas is isotropic. It acts equally in all directions

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How air and water move things

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  1. How air and water move things Bernoulli’s law and Magnus force

  2. Hydrostatic pressure Blaise Pascal P = ρgh

  3. Hydrostatic pressure ρ=fluid/gas density g=acceleration due to gravity h=height P = ρgh • Pressure in liquid/gas is isotropic. It acts equally in all directions • Pressure is force per unit area • Due to the gravity, pressure at a given level equals to the weight of the column of liquid/gas above this level over a unit area

  4. Pressure measurement: liquid (mercury) manometer

  5. Hydrostatic pressure of air and water

  6. Atmospheric pressure

  7. Hydrostatic pressure P = ρgh

  8. Bernoulli’s principle • For a non-turbulent flow of fluid or gas • As speed increases, the pressure in the fluid or gas decreases.

  9. Bernoulli’s equation P + ½ ρv2+ ρgh = const P=pressure of the fluid/gas along the streamline v=velocity of the fluid/gas along the streamline g=acceleration due to gravity h=height ρ=fluid/gas density The Bernoulli’s equation expresses conservation of enegy. It assumes that: The fluid/gas has a constant density The fluid/gas is traveling in a steady flow There is no friction The fluid/gas is non viscous and incompressable

  10. Bernoulli’s principle

  11. Bernoulli’s equation

  12. Derivation of Bernoulli Distance l Acceleration a -a Acceleration in the non-inertial frame moving with the flow Because velocity of the fluid/gas flow has changed (increased) from v1 to v2 , there must be a force which causes it to accelerate while passing the distance l. For simplicity, let us assume constant acceleration a.

  13. Derivation of Bernoulli Distance l Acceleration a -a Acceleration in the non-inertial frame moving with the flow The equivalence principle: In an accelerated reference frame moving with the flow we can calculate the pressure difference as if it were a pressure difference in a gravitational field, 𝚫P = P2 - P1 = ρ a l

  14. Inertial force and the equivalence principle

  15. Inertial force and the equivalence principle

  16. Inertial force and the equivalence principle The inertial mass relates force and acceleration in the Newton’s first law of motion: F = ma. The gravitational mass determines force of gravitational attraction in the Newton’s law of gravity: (= mg). The inertial mass and the gravitational mass are equal.

  17. Derivation of Bernoulli Distance l Acceleration a -a Acceleration in the non-inertial frame moving with the flow Kinematics of motion with constant acceleration, a, gives, v2 = v1 + at, l = v1t + ½ at2= (v22 - v12 )/(2a) where t is the time it took the flow to pass the distance l.

  18. Derivation of Bernoulli Distance l Acceleration a -a Acceleration in the non-inertial frame moving with the flow Combining the two results gives the Bernoulli equation, 𝚫P = P2 - P1 = ρ a l = ρ(v22 - v12 )/2

  19. Torricelli’s law Patm Patm ρ v2/2+Patm= ρgh+Patm => v2 = 2gh

  20. Examples of Bernoulli principle

  21. Sprayers and atomizers

  22. Ventouri effect and applications Ventouri detergent intake system in a powerwasher Dental Saliva Ejector Hose With Water Venturi Suction System Ventouri wine aerator

  23. Draft by wind in a chimney Becomes important for wind velocity v > √2gh (≈ 10 m/s for h ≈ 5 m).

  24. Pitot tube

  25. Pitot tube

  26. Pitot tubes

  27. Spectacular effect Bernoulli

  28. Ships passing on parallel course Ships sailing side by side can get too close together (as in picture above, at a certain point during the refueling). When this happens, the Venturi effect takes over, and the ships will head toward an unavoidable collision

  29. Bernoulli pull by passing trains

  30. An airfoil in a wind tunnel

  31. Airfoil lift schematics An airfoil creates a region of high pressure air below the wing, and a low pressure region above it. The air leaving the wing has adownward flow creating the Newtonian force.Bernoulli pressure field creates the downwash.

  32. Flying machines

  33. The Magnus effect • Where the cylinder is turning into the airflow, the air is moving faster and the pressure is lower • Where the cylinder is turning away from the airflow, the air is moving slower and the pressure is greater • The cylinder moves towards the low pressure zone

  34. Curveballs • The Magnus effect! • stitches help the ball to catch the air • the baseball curves towards the lower air pressure

  35. Physics of golf: dimples on the ball and the Magnus effect Typical ball spin-rates are: 3,600 rpm when hit with a 10° driver (8° launch angle) at a velocity of 134 mph 7,200 rpm when hit with a 5 iron (23° launch angle) at a velocity of 105 mph 10,800 rpm when hit with a 9 iron (45° launch angle) at a velocity of 90 mph Dimples cause the air-flow above the ball to travel faster and thus the pressure on the ball from the top to be lower than the air pressure below the ball. This pressure difference (i.e. more relative pressure from below than on top) causes the ball to lift (Magnus effect) and stay in the air for a longer time. Topping the ball (i.e. when the bottom of the club-face hits the ball above its center) will cause the ball to spin in the other direction - i.e. downward - which will cause the ball to dive into the ground.

  36. Flettner rotor ship Buckau (Baden-Baden) 1927

  37. Flettner rotor ship E-1 (Kiel 2010)

  38. Flettner rotor sail catamaran

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