Presentation is loading. Please wait.

Presentation is loading. Please wait.

9 Water bombs Mário Lipovský.

Published byCharleen Richardson Modified over 8 years ago

Similar presentations

Presentation on theme: "9 Water bombs Mário Lipovský."— Presentation transcript:

1 9 Water bombs Mário Lipovský

2 Task Some students are ineffective in water balloon fights as the balloons they throw rebound without bursting. Investigate the motion, deformation, and rebound of a balloon filled with fluid. Under what circumstances does the balloon burst?

3 Content Motion and deformation Rebound Burst Summary Two types
Angle of rebound Burst Energies in balloon Elastic Kinetic Potential Summary

4 How it looks

5 How it looks

6 Motion and deformation
Kinetic energy Potential energy Elastic energy

7 Motion and deformation

8 Motion and deformation
Water flows to the sides

9 Motion and deformation
Maximal radius of balloon Water stopped by rubber Some energy lost - water flows

10 Motion and deformation
Rubber is contracting

11 Motion and deformation

12 Motion and deformation

13 Motion and deformation
Energy losses Water convection Heat

14 Different type of deformation
The view is from the bottom of the aquarium

15 Different type of deformation
Elongated balloon Easier to stretch

16 Different type of deformation
Hard to stretch Easier to stretch Hard to stretch Hard to stretch Hard to stretch Hard to stretch Hard to stretch

17 Different type of deformation

18 Different type of deformation

19 Different type of deformation
Maximal length Starts to contract

20 Different type of deformation
Balloon jumps

21 “Investigate the motion, deformation and rebound…”

22 Rebound Jumps to the side Balloon is accelerating in horizontal way
Balloon wants to rotate Jumps to the side

23 Jumping balloon

24 Jumping balloon

25 Jumping balloon

26 “Investigate the motion, deformation, and rebound of a balloon filled with fluid. Under what circumstances does the balloon burst?”

27 Apparatus m h Balloon with mass m Changing height h from h=0cm
Find the smallest h, when it bursts Do it with many balloons m h

28 Height, which causes burst
We can calculate the potential energy… m h

29 Potential energy needed to burst
Kinetic energy Potential energy Elastic energy

30 Elastic energy of balloon
Can be calculated from pressure change during inflation

31 Pressure measurement

32 Elastic energy of balloon

33 More measurements of elastic energy

34 Elastic energy of balloon with water

35 Total energy given to balloon
Potential energy of fall Elastic energy

36 Total energy needed to burst (Potential + Elastic)
Let’s measure the energy without losses

37 Compressing Parallel plates Height Scale Force

38 Apparatus Height-meter Compressed balloon Scale (Force)

39 Compressed balloon Plate Balloon Plate

40 Force vs. depth of compression

41 Force vs. depth of compression

42 Work done by apparatus for many balloon volumes
Let’s add the initial elastic energy More than 1000 measure-points

43 Total energy needed for burst (Work + Elastic)
Rising tendency

44 Big balloon Elastic energy is almost maximal Almost maximal tension

45 Small balloon Elastic energy is less than maximal Low tension
Max tension Low tension Low tension Low tension Low tension Elastic energy is less than maximal Friction Tension at the bottom remains the same

46 Total energy needed for burst (Work + Elastic)
max max min min Let’s compare it with the first experiment! max max max max E max max max max

47 Energy needed to burst trough fall & through compression

48 Falling balloon In graph In real life There are losses
Water convection Heat Let’s assume that constant ratio of energy is preserved

49 Energy needed to burst trough fall & through compression

50 Energy needed to burst trough fall & through compression
k=0,38 Very simple assumption Ratio of losses is constant (k) Remarkable result!

51 What we have We can derive approximately the velocity of throw
needed to burst a balloon

52 Approximate velocity needed for burst

53 Summary Motion and deformation Rebound friction

54 Summary - Burst m

55 Summary - Burst m k=0,38

56 Thank you for your attention!

57 Appendices

58 Energy needed to burst trough fall & through compression
k=0,38

59 Rubber stretch at rebound

60 Rubber stretch at rebound

61 Adding air

62 Other liquid

63 Elastic energy of the balloon
Stretching a piece of rubber, surface tension In terms of pressure inside:

64 Spherical shape: Elastic energy

Download ppt "9 Water bombs Mário Lipovský."

Similar presentations

How is Work and Power Related? Chapter 5 Work and Power

How is Work and Power Related? Chapter 5 Work and Power
Vectors and Scalars Scalars have magnitude only e.g. mass, speed, distance Vectors have magnitude and direction e.g. force of 10 N to the left.. Velocity,

Vectors and Scalars Scalars have magnitude only e.g. mass, speed, distance Vectors have magnitude and direction e.g. force of 10 N to the left.. Velocity,
Lecture 15: Capillary motion

Lecture 15: Capillary motion
Work Done by a Constant Force

Work Done by a Constant Force
Liquids and Gasses Matter that “Flows”

Liquids and Gasses Matter that “Flows”
Flow Over Notches and Weirs

Flow Over Notches and Weirs
Drawing pins Michal Hledík 7.. 7. Drawing pins A drawing pin (thumbtack) floating on the surface of water near another floating object is subject to an.

Drawing pins Michal Hledík Drawing pins A drawing pin (thumbtack) floating on the surface of water near another floating object is subject to an.
Chapter 15 Fluids.

Chapter 15 Fluids.
Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lecture 23.

Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lecture 23.
PHYSICS 231 Lecture 24: Walking on water & other ‘magic’

PHYSICS 231 Lecture 24: Walking on water & other ‘magic’
Physics 11 Scale Up Fall 2014 Chapter 13.

Physics 11 Scale Up Fall 2014 Chapter 13.
Introduction to Energy Lesson Objectives: Relate energy to work. Describe kinetic energy. Identify two types of potential energy. Give examples of energy.

Introduction to Energy Lesson Objectives: Relate energy to work. Describe kinetic energy. Identify two types of potential energy. Give examples of energy.
Mechanical Energy and Simple Harmonic Oscillator 8.01 Week 09D1 2006.

Mechanical Energy and Simple Harmonic Oscillator 8.01 Week 09D
Jump! An elastic potential to kinetic energy investigation.

Jump! An elastic potential to kinetic energy investigation.
Elastic Potential Energy: More Practice. Conservation of Mechanical Energy: Learning Goal The student will investigate a simple energy transformation,

Elastic Potential Energy: More Practice. Conservation of Mechanical Energy: Learning Goal The student will investigate a simple energy transformation,
Tell me and I'll forget Show me and I may remember Let me do and I'll understand RA Moffatt WELB A Mousetrap Powered Racer This project looks to be an.

"Tell me and I'll forget Show me and I may remember Let me do and I'll understand" RA Moffatt WELB A Mousetrap Powered Racer This project looks to be an.
ENG. SAMRA ESSALAIMEH PHILADELPHIA UNIVERSITY 2 ND SEMESTER 2013-2014 Thermo-Fluid.

ENG. SAMRA ESSALAIMEH PHILADELPHIA UNIVERSITY 2 ND SEMESTER Thermo-Fluid.
Air Pocket 8th problem. A vertical air jet from a straw produces a cavity on a water surface. What parameters determine the volume and the depth of the.

Air Pocket 8th problem. A vertical air jet from a straw produces a cavity on a water surface. What parameters determine the volume and the depth of the.
Physics 1B03summer-Lecture 12 1 Day of Wrath Tuesday June 16 9:30-11:30 am CNH-104 30 MC Questions, Cumulative.

Physics 1B03summer-Lecture 12 1 Day of Wrath Tuesday June 16 9:30-11:30 am CNH MC Questions, Cumulative.
Fluids Physics 152. A piece of iron hanging on a string is lowered into a beaker of water on a spring scale, the water level reaches the top of the beaker.

Fluids Physics 152. A piece of iron hanging on a string is lowered into a beaker of water on a spring scale, the water level reaches the top of the beaker.

Similar presentations

Ads by Google