The “internal” or “thermal energy”of moving molecules is already something we have identified with

1. The “internal” or “thermal energy”of moving molecules is already something we have identified with TEMPERATURE LIQUIFIES/BOILS SOLIDIFIES/MELTS MERCURY 356.58oC -38.87oC WATER100.00oC 0.000oC NITROGEN -195.8oC -210.1oC OXYGEN -183.0oC -218.4oC HYDROGEN -252.5oC -259.1oC HELIUM -268.6oC -272.1oC

2. 20 15 10 5 Pressure (lb/in2) -200o -100o 0oC 100o room temperature

3. 20 15 10 5 Pressure (lb/in2) -300o -200o -100o 0oC 100o Absolute zero -273.15oC 20 15 10 5 Pressure (lb/in2) P T 0 K 273.15 373.15 Provided T is measure in the Kelvin scale

4. A head-on collision between identical molecules just exchanges momenta: v1 v2 v2 v1

5. Glancing blows are a little more complicated. But you may remember the normal components of motion just exchange as in head-on collisions While the perpendicular components (parallel to the contact surface between them) remain unaffected.

6. The total momentum and kinetic energy remains unchanged in such collisions. And there is still the same amount of momentum being carried upward/downward and left/right.

7. The more and more and more air we force into a tire (basketball or football) the more taut its rubber/fabric casing becomes and the firmer and more solid its surface grows.

8. number of molecules trapped in a container Pressure  We also saw by a simple demonstration that this pressure is UP as well as DOWN and increased as the speed of the particles creating it increased.

9. The force of any individual impact in a collision is delivered by the impulse Impulse delivered to wall mv 2mv -mv

10. In any interval of time, the number of times a single particle will return to strike the wall again and again v Impact of any single collision: Rate of collisions: Together, both imply mv2 Pressure

11. Not forgetting: number of molecules trapped in a container Pressure  All together: number of molecules kinetic energy of the molecules Pressure   Which is whatTemperaturereally measures!

13. Raising T increases molecular kinetic energy outward pressure of gas volume occupied by gas

14. Some of the expanding air escapes out the bottom; it takes less of the warmer air to fill the same space as the cooler air. Essentially the SAME VOLUME now occupied by less gas …which weighs less!

15. Static equilibrium of fluids P1 P2 • All fluids have settled. • Pressures have equalized and • are exerted in all directions. P1 = P2 • No fluid is moving. Only when there’s a pressure difference P1 P2 can there be any acceleration with flow from regions of high pressure to regions of lower pressure.

16. Increasing the VOLUME of the lungs reduces the pressure of the gas inside. External air at ~1 atmosphere of pressure is forced in! The Diaphragm (during inhalation)

20. Simple Ball Float Valve prevents drains from backing up Ordinarily water drains easily, but a backed up sewer during a storm seals the floating ball so no water flows into your home. Any water above the drain cannot push down the ball float unless its standing water with pressure greater than that pushing the ball float up.

22. Similar to the manual bicycle tire pump: Raising the sealed piston creates a vacuum beneath it. Assuming at least Atmospheric pressure is exerted on the reservoir of water beneath, water will be pushed up this pipe. Float valve!

23. Similar to the manual bicycle tire pump: Raising the sealed piston creates a vacuum beneath it. Assuming at least Atmospheric pressure is exerted on the reservoir of water beneath, water will be pushed up this pipe. Float valve!

25. Another “Positive Displacement” Pump

26. Much simpler to understand is the impeller pump OUT IN which can continuously drive water through. Momentum Transfer Pumps

27. Industrial impeller