Presentation is loading. Please wait.

Presentation is loading. Please wait.

conservation and continuity

Published byElsa Viken Modified over 5 years ago

Similar presentations

Presentation on theme: "conservation and continuity"— Presentation transcript:

1 conservation and continuity
Fluid Flow conservation and continuity § 15.6

2 Volume Flow Rate Volume per time through an imaginary surface perpendicular to the velocity DV/Dt units: m3/s

3 Volume Flow Rate DV/Dt = v·A if v is constant over A

4 Mass Flow Continuity Constant mass flow for a closed system Dm = Dt
1 2 r1A1v1 = r2A2v2

5 Volume Flow Continuity
Constant volume flow if incompressible If r1 = r2, DV Dt = 1 2

6 Poll Question Where is the velocity greatest in this stream of incompressible fluid? Here. Same for both. Can’t tell.

7 Quick Question Where is the density greatest in this stream of incompressible fluid? Here. Same for both. Can’t tell.

8 Poll Question Where is the volume flow rate greatest in this stream of incompressible fluid? Here. Same for both. Can’t tell.

9 Bernoulli’s Equation Energy in fluid flow § 15.7

10 Incompressible Fluid Continuity condition: constant volume flow rate
dV1 = dV2 v1A1 = v2A2

11 Poll Question Where is the kinetic energy of a parcel greatest in this stream of incompressible fluid? Here. Same for both. Can’t tell.

12 Changing Cross-Section
Fluid speed varies Faster where narrow, slower where wide Kinetic energy changes Work is done!

13 Ideal Fluid No internal friction (viscosity) No non-conservative work!

14 Poll Question Where would the pressure be greatest if the fluid were stationary? Here. Same for both. Can’t tell.

15 Work-Energy Theorem Wnet = DK K1 + Wnet = K2
K1 + U1 + Wother = K2 + U2 Wother = DK + DU dW = dK + dU 16

16 Work done by Pressure W = F·Ds
Work done on fluid at bottom: W1 = p1A1·Ds1 Work done on fluid at top: W2 = –p2A2·Ds2 Total work done on fluid : W = p1A1·Ds1–p2A2·Ds2 = (p1 – p2)DV

17 Kinetic Energy Change Steady between “end caps” Lower cap: K1 = ½ mv12
Upper cap: K2 = ½ mv22 m = rV DK = 1/2 rV (v22–v12)

18 Potential Energy Change
Steady between “end caps” Lower cap: U1 = mgy1 Upper cap: U2 = mgy2 m = rV DU = rgV (y2–y1)

19 Put It All Together Wother = DK + DU
(p1 – p2)V = 1/2 rV (v22–v12) + rgV (y2–y1) (p1 – p2) = 1/2 r (v22–v12) + r g(y2–y1) p1 + 1/2 rv12 + rgy1 = p2 + 1/2 rv22 + rgy2 This is a conservation equation Strictly valid only for incompressible, inviscid fluid

20 What Does It Mean? Faster flow  lower pressure
Maximum pressure when static pV is energy

21 Example problem A bullet punctures an open water tank, creating a hole that is a distance h below the water level. How fast does water emerge from the hole?

22 Torricelli’s Law p1 + 1/2 rv12 + rgy1 = p2 + 1/2 rv22 + rgy2 v22 = 2gh
1/2 rv22 = rg(y2–y1) + (p2–p1) – 1/2 rv12 1/2 rv22 = rgh v22 = 2gh v2 =    2gh look familiar?

Download ppt "conservation and continuity"

Similar presentations

Chapter 15B - Fluids in Motion

Chapter 15B - Fluids in Motion
Archimedes’ Principle Physics 202 Professor Lee Carkner Lecture 2.

Archimedes’ Principle Physics 202 Professor Lee Carkner Lecture 2.
Physics 101: Lecture 25, Pg 1 Physics 101: Lecture 25 Fluids in Motion: Bernoulli’s Equation l Today’s lecture will cover Textbook Sections 11.7-11.10.

Physics 101: Lecture 25, Pg 1 Physics 101: Lecture 25 Fluids in Motion: Bernoulli’s Equation l Today’s lecture will cover Textbook Sections
Fluid Dynamics AP Physics B.

Fluid Dynamics AP Physics B.
Physics 203 College Physics I Fall 2012

Physics 203 College Physics I Fall 2012
Lecture 3 Bernoulli’s equation. Airplane wing Rear wing Rain barrel Tornado damage.

Lecture 3 Bernoulli’s equation. Airplane wing Rear wing Rain barrel Tornado damage.
Fluids Physics 202 Professor Vogel (Professor Carkner’s notes, ed) Lecture 20.

Fluids Physics 202 Professor Vogel (Professor Carkner’s notes, ed) Lecture 20.
CHAPTER-14 Fluids. Ch 14-2, 3 Fluid Density and Pressure  Fluid: a substance that can flow  Density  of a fluid having a mass m and a volume V is given.

CHAPTER-14 Fluids. Ch 14-2, 3 Fluid Density and Pressure  Fluid: a substance that can flow  Density  of a fluid having a mass m and a volume V is given.
Physics 151: Lecture 30 Today’s Agenda

Physics 151: Lecture 30 Today’s Agenda
Archimedes’ Principle Physics 202 Professor Lee Carkner Lecture 2 “Got to write a book, see, to prove you’re a philosopher. Then you get your … free official.

Archimedes’ Principle Physics 202 Professor Lee Carkner Lecture 2 “Got to write a book, see, to prove you’re a philosopher. Then you get your … free official.
Chapter 4: Flowing Fluids & Pressure Variation (part 2) Review visualizations Frames of reference (part 1) Euler’s equation of motion.

Chapter 4: Flowing Fluids & Pressure Variation (part 2) Review visualizations Frames of reference (part 1) Euler’s equation of motion.
PHY 231 1 PHYSICS 231 Lecture 22: fluids and viscous flow Remco Zegers Walk-in hour: Tue 4-5 pm Helproom.

PHY PHYSICS 231 Lecture 22: fluids and viscous flow Remco Zegers Walk-in hour: Tue 4-5 pm Helproom.
Fluid Flow. Streamline  Motion studies the paths of objects.  Fluids motion studies many paths at once.  The path of a single atom in the fluid is.

Fluid Flow. Streamline  Motion studies the paths of objects.  Fluids motion studies many paths at once.  The path of a single atom in the fluid is.
Fluid Flow 1700 – 1782 Swiss physicist and mathematician. Wrote Hydrodynamica. Also did work that was the beginning of the kinetic theory of gases. Daniel.

Fluid Flow 1700 – 1782 Swiss physicist and mathematician. Wrote Hydrodynamica. Also did work that was the beginning of the kinetic theory of gases. Daniel.
The Physics of Balloons and Submarines…cont’d…. The Ideal Gas Law Equation We learned that Pressure of an Ideal Gas is proportional to Particle Density.

The Physics of Balloons and Submarines…cont’d…. The Ideal Gas Law Equation We learned that Pressure of an Ideal Gas is proportional to Particle Density.
Unit 3 - FLUID MECHANICS.

Unit 3 - FLUID MECHANICS.
Chapter 15B - Fluids in Motion

Chapter 15B - Fluids in Motion
Fluids Fluids in Motion. In steady flow the velocity of the fluid particles at any point is constant as time passes. Unsteady flow exists whenever the.

Fluids Fluids in Motion. In steady flow the velocity of the fluid particles at any point is constant as time passes. Unsteady flow exists whenever the.
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.
R. Field 10/29/2013 University of Florida PHY 2053Page 1 Ideal Fluids in Motion Bernoulli’s Equation: The Equation of Continuity: Steady Flow, Incompressible.

R. Field 10/29/2013 University of Florida PHY 2053Page 1 Ideal Fluids in Motion Bernoulli’s Equation: The Equation of Continuity: Steady Flow, Incompressible.

Similar presentations

Ads by Google