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Lec 3: Conservation of mass continued, state postulate, zeroth law, temperature

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Lec 3: Conservation of mass continued, state postulate, zeroth law, temperature

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    1. 1 Lec 3: Conservation of mass continued, state postulate, zeroth law, temperature

    2. 2 For next time: Read: § 10-1 to 10-2, 10-4 to 10-5, and 2-5 to 2-8. Outline: Conservation of mass example problems Equilibrium and states Zeroth law of thermodynamics Important points: Problem solving methodology State, path, and process Temperature scales

    3. 3 Review

    4. 4 Steady flow

    5. 5 Conservation of mass

    6. 6 Look at some simplifying cases:

    7. 7 One more simplifying case:

    8. 8 TEAMPLAY

    9. 9 Review--State The state of a system is defined by the values of its properties.

    10. 10 TEAMPLAY How many properties can you name that apply to the gas in a high pressure cylinder of nitrogen? How many are independent and how many are dependent?

    11. 11 Equilibrium A system is in equilibrium if its properties are not changing at any given location in the system. This is also known as “thermodynamic equilibrium” or “total equilibrium.” We will distinguish four different subtypes of thermodynamic or total equilibrium.

    12. 12 Types of thermodynamic equilibrium: Thermal equilibrium--temperature does not change with time. Mechanical equilibrium--Pressure does not change with time. Phase equilibrium--Mass of each phase is unchanging with time. Chemical equilibrium--molecular structure does not change with time.

    13. 13 Equilibrium Equilibrium implies balance--no unbalanced potentials (driving forces) in the system.

    14. 14 State Principle or State Postulate Text says, “The state of a simple compressible system is completely given by two independent, intensive properties.” Properties are independent if one can be constant while the other varies. This only applies at equilibrium.

    15. 15 Process Change in state of a system from one equilibrium state to another.

    16. 16 Path

    17. 17 Properties at end points are independent of the process

    18. 18 Constant property processes The prefix “iso” is used to indicate a property that remains constant during a process: Isothermal is constant temperature Isobaric is constant pressure Isochoric or isometric is constant volume

    19. 19

    20. 20 Quasiequilibrium Process

    21. 21 Quasiequilibrium Processes Engineers are interested in quasiequilibrium processes for two reasons: They are easy to analyze because many (relatively) simple mathematical relations apply. It will be shown later that devices produce maximum work or require minimum work when they operate on quasiequilibrium processes.

    22. 22 Cycle

    23. 23 State Principle (more rigorous definition) The number of independent, intensive properties needed to characterize the state of a system is n+1 where n is the number of relevant quasiequilibrium work modes. This is empirical, and is based on the experimental observation that there is one independent property for each way a system’s energy can be independently varied.

    24. 24 State Principle continued The “1” is for heat transfer (Q). The “n” is the number of relevant quasiequilibrium work modes. In this course, we will usually have n = 1.

    25. 25 Simple system

    26. 26 For a simple system, We may write: p = p(v,T) Or perhaps: v = v(p,T).

    27. 27 Forms of Energy Energy is usually symbolized by E, representing total energy e is energy per unit mass

    28. 28 Forms of Energy Macroscopic forms--possessed with respect to some outside reference frame. Kinetic energy, Potential energy,

    29. 29 Forms of energy Microscopic forms are called internal energy (internal to the molecule) and represent the energy a molecule can have as it translates, rotates, and vibrates. There are other contributors--nuclear spin, for example--as well. We will not concern ourselves with the details, but will use the symbols U and u.

    30. 30 Energy Now, we have and for stationary, closed systems, ?KE and ?PE are 0. So, for stationary closed systems, ?E= ?U

    31. 31 Energy Sensible energy--the portion of the internal energy associated with all forms of kinetic energy of the molecules. Latent energy--refers to internal energy associated with binding forces between molecules. Phase changes, such as vaporizing (boiling) water are latent energy changes.

    32. 32 Thermal Equilibrium Occurs when two bodies are at the same temperature T and no heat transfer can occur.

    33. 33 Zeroth Law of Thermodynamics If two bodies are in thermal equilibrium with a third body, they are in thermal equilibrium with each other.

    34. 34

    35. 35 Temperature relationships T (ºR) = T (ºF) + 459.67 [use 460] T (K) = T (ºC) + 273.15 [use 273]

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