Presentation is loading. Please wait.

Presentation is loading. Please wait.

Aside: M 2 = V 2 /(kRT) = directed K.E. / random K.E. Flow of air at standard sea level conditions and M=2, then internal energy of 1 kg of air = 2.07.

Published byBernadette Dean Modified over 8 years ago

Similar presentations

Presentation on theme: "Aside: M 2 = V 2 /(kRT) = directed K.E. / random K.E. Flow of air at standard sea level conditions and M=2, then internal energy of 1 kg of air = 2.07."— Presentation transcript:

1 Aside: M 2 = V 2 /(kRT) = directed K.E. / random K.E. Flow of air at standard sea level conditions and M=2, then internal energy of 1 kg of air = 2.07 x 10 5 J, whereas the directed KE is = 2.31 x 10 5 J; when flow decreases, part of this energy reappears as internal energy - hence increasing the temperature of the gas. For perfect gas, intermolecular forces can be ignored (on average gas molecules are more than 10 molecular diameters apart). Energy of molecule (e.g. O 2 ) = sum of translational, vibrational, rotational and electronic energies. For point particle only have translational energy. Sum of all the energies of the molecules = internal energy Really Interesting Fact ~

2 C d, (0 lift) vs M Northrup T-38 jet trainer

3 What causes fluid properties to change?

4 Ch.12 - COMPRESSIBLE FLOW WHAT CAUSES FLUID PROPERTIES TO CHANGE IN A 1-D FLOW?

5 Ch.12 - COMPRESSIBLE FLOW 1 st – assume flow can be affected by: areas change, friction, heat transfer, shock Use continuity, x-momentum, energy, entropy and eq. of state.

6 Fluid properties = T(x), p(x),  (x), A(x), v(x), s(x), h(x) What can affect fluid properties? Changing area, heating, cooling, friction, normal shock One-Dimensional Compressible Flow dQ/dt heat/cool RxRx Surface force from friction and pressure P1P1 P2P2 (+ s 1, h 1 ) (+ s 2, h 2 )

7 One-Dimensional Compressible Flow f(x 1 ) f(x 2 ) (+ S 1, h 1 ) (+ S 2, h 2 ) To make problem more tractable assume steady, fluid properties are uniform at each x-location, body forces are negligible, ideal gas, constant specific heats

8 V(s) V(x,y) (a) No viscous effects(b) Viscous effects

9 7 Variables = T(x), p(x),  (x), A(x), v(x), s(x), h(x) 7 Equations = mass, x-momentum, 1 st and 2 nd Laws of Thermodynamics, Equation of State (3 relationships) One-Dimensional Compressible Flow f(x 1 ) f(x 2 ) + S 1, h 1 + S 2, h 2

10 EQ 4.12 dA 1 dA 2 Velocity  (x),V(x),A(x) Quasi-1-Dimensional Flow =

11 Does the flow have to be inviscid? Does the flow have to incompressible? Does the flow have to one-dimensional? Does the flow have to steady?

12 Volume flow in over A 1 = A 1 V 1  t Volume flow in over A 2 = A 2 V 2  t mass in over A 1 =  1 A 1 V 1  t mass in over A 2 =  2 A 2 V 2  t  1 A 1 V 1  t =  2 A 2 V 2  t  1 A 1 V 1 =  2 A 2 V 2 If steady, what comes in must go out! (Cool way to derive 1-D continuity equation – steady) ? Vol 1 = Vol 2 ?? m 1 = m 2 ?

13

14 Glass #1 has volume V of red wine. Glass #2 has volume V of white wine. Take teaspoon of red wine from glass #1 and put into glass #2, then take same amount of wine from glass #2 and replace back in glass #1 so both glasses have volume V. Case 1: did not mix well Question – which glass has the purest wine? Case 2: mixed vigorously Question – which glass has the purest wine?

15 EQ 4.18a F = rate of change of momentum

16 EQ 4.18a (also steady; 1-D) R x is surface forces arising from friction and pressure on top* and bottom + + + *

17 CONSERVATION of ENERGY

18

19 EQ. 4.56 Conservation of Energy rate of change of total energy of system = net rate of energy addition by heat transfer to fluid + net rate of energy addition by work done on fluid also steady, 1-D only pressure work, pg147

20 F shear  V on boundary since V = 0 ASIDE ~

21 W normal = F normal  ds work done on area element d W normal / dt = F normal  V = p dA  V rate of work done on area element - d W normal / dt = - p dA  V = - p(  v)dA  V + for going in + for going out ASIDE ~

22 dm/dt

23 EQ. 12.1c

24 dS/dt| system  (dQ/dt)/T

25  h = c p  T ~ ideal gas p =  RT ~ ideal gas EQ. 11.1 EQ. 11.3 EQ. 11.11b ~ ideal gas and constant c p EQUATIONS OF STATE

26 EQ. 12.1d EQ. 12.1c EQ. 12.1f EQ. 12.1e EQ. 12.1g EQ. 12.1b EQ. 12.1a Did NOT assume  S=0  A=0 No friction No shocks Most general case ~

27 Variables = T(x), p(x),  (x), A(x), v(x), s(x), h(x) Equations = mass, momentum, 1 st and 2 nd Laws of Thermodynamics, Equation of State (3 relationships) One-Dimensional Compressible Flow Cons. of mass Cons. of momentum Cons. of energy 2 nd Law of Thermodynamics equations of state – relations between intensive thermo. var. Ideal gas Ideal gas & constant c v, c p

Download ppt "Aside: M 2 = V 2 /(kRT) = directed K.E. / random K.E. Flow of air at standard sea level conditions and M=2, then internal energy of 1 kg of air = 2.07."

Similar presentations

Lecture 15: Capillary motion

Lecture 15: Capillary motion
One-dimensional Flow 3.1 Introduction Normal shock

One-dimensional Flow 3.1 Introduction Normal shock
Continuity Equation. Continuity Equation Continuity Equation Net outflow in x direction.

Continuity Equation. Continuity Equation Continuity Equation Net outflow in x direction.
Conservation of Linear Momentum.

Conservation of Linear Momentum.
Aka the Law of conservation of energy, Gibbs in 1873 stated energy cannot be created or destroyed, only transferred by any process The net change in energy.

Aka the Law of conservation of energy, Gibbs in 1873 stated energy cannot be created or destroyed, only transferred by any process The net change in energy.
Flow over an Obstruction MECH 523 Applied Computational Fluid Dynamics Presented by Srinivasan C Rasipuram.

Flow over an Obstruction MECH 523 Applied Computational Fluid Dynamics Presented by Srinivasan C Rasipuram.
CIEG 305 DERIVATION OF THE ENERGY EQUATION 1 st Law of Thermodynamics Change in energy per time Rate at which heat is added to system Rate at which work.

CIEG 305 DERIVATION OF THE ENERGY EQUATION 1 st Law of Thermodynamics Change in energy per time Rate at which heat is added to system Rate at which work.
2-1 Problem Solving 1. Physics  2. Approach methods

2-1 Problem Solving 1. Physics  2. Approach methods
For next time: Outline: Important points: Read: § 5-2 to 5-3

For next time: Outline: Important points: Read: § 5-2 to 5-3
Introduction to Convection: Flow and Thermal Considerations

Introduction to Convection: Flow and Thermal Considerations
Fluid mechanics 3.1 – key points

Fluid mechanics 3.1 – key points
Instructor: André Bakker

Instructor: André Bakker
Flow and Thermal Considerations

Flow and Thermal Considerations
St Venant Equations Reading: Sections 9.1 – 9.2.

St Venant Equations Reading: Sections 9.1 – 9.2.
PTT 201/4 THERMODYNAMIC SEM 1 (2013/2014) CHAPTER 7: Entropy.

PTT 201/4 THERMODYNAMIC SEM 1 (2013/2014) CHAPTER 7: Entropy.
PTT 201/4 THERMODYNAMIC SEM 1 (2012/2013). Objectives Apply the second law of thermodynamics to processes. Define a new property called entropy to quantify.

PTT 201/4 THERMODYNAMIC SEM 1 (2012/2013). Objectives Apply the second law of thermodynamics to processes. Define a new property called entropy to quantify.
ME 231 Thermofluid Mechanics I Navier-Stokes Equations.

ME 231 Thermofluid Mechanics I Navier-Stokes Equations.
Conservation Laws for Continua

Conservation Laws for Continua
Heat Engines Coal fired steam engines. Petrol engines Diesel engines Jet engines Power station turbines.

Heat Engines Coal fired steam engines. Petrol engines Diesel engines Jet engines Power station turbines.
PHAROS UNIVERSITY ME 259 FLUID MECHANICS FOR ELECTRICAL STUDENTS Basic Equations for a Control Volume.

PHAROS UNIVERSITY ME 259 FLUID MECHANICS FOR ELECTRICAL STUDENTS Basic Equations for a Control Volume.

Similar presentations

Ads by Google