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Fluid Speed in a Pipe

Fluid Speed in a Pipe. v 2. v 1. x 1. x 2. A 1. A 2. An incompressible fluid, like water, flowing through a pipe will slow down if the pipe gets wider. blue volume = purple volume A 1 x 1 = A 2 x 2 A 1 (v 1 t) = A 2 (v 2 t) A 1 v 1 = A 2 v 2 A v = constant

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Fluid Speed in a Pipe

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  1. Fluid Speed in a Pipe v2 v1 x1 x2 A1 A2 An incompressible fluid, like water, flowing through a pipe will slow down if the pipe gets wider. blue volume= purple volume A1x1= A2x2 A1(v1t) = A2(v2t) A1v1 = A2v2 Av = constant The bigger the area, the slower the fluid speed.

  2. Bernoulli’s Principle Bernoulli’s principle says that the faster a fluid is moving the less pressure it exerts. v1 v2

  3. Bernoulli Example 2 air flow h w a t e r Because air flows faster in the thin section of the top pipe, the pressure is lower there, and the water level beneath it rises more than in the other two. The difference in pressure between the thick section of the top pipe and the thin section is given by: P = gh.

  4. Airplanes Air on top must travel farther, so it moves faster, and the pressure there is lower, creating lift. Also, because of the wing’s upward tilt, air is pushed downward. So, the air pushes back on the wing in the direction of F. F

  5. Curve Ball

  6. Whiffle Ball

  7. Stream Lined Flow Stream line flow occurs in non-viscous fluids moving over smooth objects. The Bernoulli principle only applies to stream lined flow. Viscous fluids, or blunt objects can create turbulent flow

  8. Types of Solids • Solids are of two types: • Crystalline solids- consist of crystals which are substances which are organized in symmetric, geometric ways. • Amorphous solids-non crystalline solid where the particles are arranged randomly.

  9. Crystalline Solids Exist either as single crystals or group of crystals fused together. The total three dimensional arrangement of particles is called as crystal structure. Ex: diamond, salt, ice Amorphous Solids Unlike crystalline solids, amorphous solids do not have a regular shape. Amorphous solids are formed when liquids are cooled gradually, so particles are not arranged in any particular order. Ex: Plastic, Glasses Amorphous and Crystalline Solids

  10. Crystalline Solids The cohesive forces that hold a substance together depend on the distance between molecules When an liquid cools down sufficiently, the cohesive forces become greater, and the particles become fixed in their arrangement. The molecules form a crystal lattice if they arrange themselves in a fixed pattern,

  11. Amorphous Solids • If a substance does not have a fixed crystal structure, it is hard to distinguish between its solid and its liquid state • These substances are classified as to as amorphous solids, or highly viscous liquids • When an amorphous solid cools sufficiently, the molecules have a random arrangement (glass, plastic)

  12. Thermal Expansion • As an object heats up, its molecules gain energy, and the distances between particles increases • This increase in distance increases the volume of the object. • This effect is called thermal expansion • This is the reason for many phenomena

  13. What Happened Here?

  14. Why does it help to run a jar lid under hot water to get it open? The hot water makes the lid expand and loosen. This reduces the friction between the lid and the threads

  15. Why doesn’t the jar expand with the lid? Different materials have a different rate at which they expand due to temperature changes

  16. Coefficient Expansion • Every material experiences a different change in size from temperature change. • This difference is reflected in the coefficient of expansion. • There are three different values that represent this expansion, but they are essentially the same

  17. Coefficient of Expansion • Linear Expansion • The change in length divided by the original length and the change in Temperature • Volume Expansion • The change in volume divided by the original volume, and the change in Temperature

  18. Example • Find the change in volume of an aluminum cube with side lengths of 2m after the temperature increases from 20⁰C to 90⁰C. • What is the new volume?

  19. Volume Expansion • .042m3 • Final Volume = 8.042m3

  20. Linear Expansion • -6 • L1=2m • ∆L = L*α*∆T = .0035m • Final Length = 2.0035m • Final Volume = 8.042

  21. Volume and Linear Expansion • The relationship between the linear and spatial dimensions of objects is fixed, the relationship between the coefficients of linear and volume expansion is fixed • The coefficient of Volume expansion is always 3 times the coefficient of linear expansion.

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