Presentation is loading. Please wait.

Presentation is loading. Please wait.

1414 Loaded hoop Mário Lipovský 5. 1414 Task Fasten a small weight to the inside of a hoop and set the hoop in motion by giving it an initial push. Investigate.

Published byJanel Jones Modified over 8 years ago

Similar presentations

Presentation on theme: "1414 Loaded hoop Mário Lipovský 5. 1414 Task Fasten a small weight to the inside of a hoop and set the hoop in motion by giving it an initial push. Investigate."— Presentation transcript:

1 1414 Loaded hoop Mário Lipovský 5

2 1414 Task Fasten a small weight to the inside of a hoop and set the hoop in motion by giving it an initial push. Investigate the hoop’s motion. 2

3 1414 Types of hoop motion 1)Rolling 2)Spinning Skidding 3)Jump 3 ω N v

4 1414 1) Rolling 4 m weight = 22g m hoop = 28g r hoop = 41 mm

5 1414 1) Rolling Conservation of mechanical energy Rolling condition can be calculated from 5 θ G[x, y] Friction force is strong enough to prevent slipping ω N F Potential energy of the system Translational kinetic energy of the system Rotational kinetic energy of the system

6 1414 2) Spinning/Skidding 6 m weight = 322g m hoop = 28g r hoop = 41 mm

7 1414 2) Spinning/Skidding Newton’s laws of motion ω can be calculated by numerical integration of ε 7 θ G[x, y] N F Friction force reaches it’s maximum Torque equation my : mx : mg

8 1414 3) Jump 8 m weight = 220g m hoop = 28g r hoop = 41 mm

9 1414 my : 3) Conditions needed to jump Forces –gravity –centrifugal Condition of leaving the ground 9 ω mx : mg N

10 1414 3) When does hoop jump? 10 Jump occurs θ G[x, y] ω

11 1414 3) When does hoop jump? 11 Jump occurs θ G[x, y] ω

12 1414 3) Jump Hoop – Constant ω around centre of gravity Centre of gravity – projectile motion 12

13 1414 Types of hoop motion 1)Rolling 2)Spinning Skidding 3)Jump 13 ω N v F How to determine changes of motion types?

14 1414 What has been done 14 Analysis of Rolling Motion of Loaded Hoops [ W.F.D. Theron ] 4 types of motion Combined into 36 patterns Numerical simulation Observed only 1 x 360° rotation Stopped right after the hoop leaves ground Our own simulation Compare with our experiments Simulate jump

15 1414 Simulation 15 3) Jump 1) Rolling 2) Skidding / Spinning Numerical solution, using method of small increments (t) Init. conditions (x, θ, ω)

16 1414 Simulation 16

17 1414 Experiments Constant parameters –r – hoop radius –hoop material (rigid) –f – coefficient of friction (ground) Changing parameters –ω – initial velocity –m – mass of weight 17

18 1414 1) Rolling 18 m weight = 22g m hoop = 28g r hoop = 41 mm

19 1414 Angular displacement in timeθ(t) 19

20 1414 Position of centre of mass y(t) 20

21 1414 2) Spinning/skidding 21 m weight = 322g m hoop = 28g r hoop = 41 mm

22 1414 Position of centre of mass y(t) 22

23 1414 3) Jump 23 m weight = 220g m hoop = 28g r hoop = 41 mm

24 1414 4) Oscillation 24 m weight = 3,6g m hoop = 3,9g r hoop = 20,4 mm

25 1414 m weight = 22g 25 rolling skidding spinning jump Phase diagram of movement = small eccentricity mostly boring rolling What happens in time? ω 0 = 10 rad/s - rolling ω 0 = 15 rad/s - still rolling … ω 0 = 20 rad/s - spinning/skidding occur ω 0 = 25 rad/s – finally some jump

26 1414 m weight = 214g 26 Irregularities – spinning/skidding occur at lower velocities Immediate jump rolling skidding spinning jump Phase diagram of movement = higher eccentricity

27 1414 m weight = 322g 27 Increasing eccentricity – shift of patterns to lower velocities rolling skidding spinning jump Phase diagram of movement

28 1414 1) Rolling 2) Spinning/Skidding 3) Jump 1) Rolling 2) Spinning/Skidding 3) Jump Theoretical prediction of motions Numerical simulation Conclusion Description of types of motion 28 Thank you for your attention Theory & simulation proved by experiments

29 1414 THANK YOU FOR YOUR ATTENTION 29

30 1414 APPENDICES 30

31 1414 Comparison to original paper [W.F.D. Theron] 31 γ = 3/4 f = 0,4

32 1414 32 γ = 3/4 f = 0,09 Comparison to original paper [W.F.D. Theron]

33 1414 my : Description of the system 33 θ G[x, y] S[X,Y] ω N F Centre of hoop S [X, Y] Angular displacement θ Centre of gravity G [x, y] Normal force Friction force mx : mg

34 1414 my : Description of the system 34 θ G[x, y] S[X,Y] ω N F mx :

35 1414 Elastic hoop – obvious difference in motion 35

Download ppt "1414 Loaded hoop Mário Lipovský 5. 1414 Task Fasten a small weight to the inside of a hoop and set the hoop in motion by giving it an initial push. Investigate."

Similar presentations

Angular Motion in Cars Applying Physics of Rotational Motion, Newton’s Laws and Kinematics to the motion of a car.

Angular Motion in Cars Applying Physics of Rotational Motion, Newton’s Laws and Kinematics to the motion of a car.
AP Physics C Mechanics Review.

AP Physics C Mechanics Review.
PLANAR KINETICS OF A RIGID BODY: CONSERVATION OF ENERGY

PLANAR KINETICS OF A RIGID BODY: CONSERVATION OF ENERGY
今日課程內容 CH10 轉動 轉動牛頓第二運動定律 轉動動能 轉動慣量. 10-1 Angular Quantities Here is the correspondence between linear and rotational quantities:

今日課程內容 CH10 轉動 轉動牛頓第二運動定律 轉動動能 轉動慣量 Angular Quantities Here is the correspondence between linear and rotational quantities:
Chapter 11 Angular Momentum

Chapter 11 Angular Momentum
Chapter 9 Rotational Dynamics.

Chapter 9 Rotational Dynamics.
Chapter 9 Rotational Dynamics. 9.5 Rotational Work and Energy.

Chapter 9 Rotational Dynamics. 9.5 Rotational Work and Energy.
Chapter 11 Rolling, Torque, and angular Momentum.

Chapter 11 Rolling, Torque, and angular Momentum.
PHY131H1S - Class 20 Today: Gravitational Torque Rotational Kinetic Energy Rolling without Slipping Equilibrium with Rotation Rotation Vectors Angular.

PHY131H1S - Class 20 Today: Gravitational Torque Rotational Kinetic Energy Rolling without Slipping Equilibrium with Rotation Rotation Vectors Angular.
Force and Moment of Force Quiz

Force and Moment of Force Quiz
Angular Impulse Chapter 13 KINE 3301 Biomechanics of Human Movement.

Angular Impulse Chapter 13 KINE 3301 Biomechanics of Human Movement.
Chapter 9 Rotational Dynamics.

Chapter 9 Rotational Dynamics.
2008 Physics 2111 Fundamentals of Physics Chapter 11 1 Fundamentals of Physics Chapter 12 Rolling, Torque & Angular Momentum 1.Rolling 2.The Kinetic Energy.

2008 Physics 2111 Fundamentals of Physics Chapter 11 1 Fundamentals of Physics Chapter 12 Rolling, Torque & Angular Momentum 1.Rolling 2.The Kinetic Energy.
Rotational Dynamics Chapter 9.

Rotational Dynamics Chapter 9.
Chapter 5 Rotation of a Rigid Body. §5-5 Angular Momentum of a rigid Body Conservation of Angular Momentum §5-1 Motion of a Rigid body §5-2 Torque The.

Chapter 5 Rotation of a Rigid Body. §5-5 Angular Momentum of a rigid Body Conservation of Angular Momentum §5-1 Motion of a Rigid body §5-2 Torque The.
5. LOADED HOOP “Fasten a small weight to the inside of a hoop and set the hoop in motion by giving it an initial push. Investigate the hoop’s motion.”

5. LOADED HOOP “Fasten a small weight to the inside of a hoop and set the hoop in motion by giving it an initial push. Investigate the hoop’s motion.”
Rolling. Rotation and Translation  A rolling wheel is moving forward with kinetic energy.  The velocity is measured at the center of mass. K CM = ½.

Rolling. Rotation and Translation  A rolling wheel is moving forward with kinetic energy.  The velocity is measured at the center of mass. K CM = ½.
Department of Physics and Applied Physics 95.141, F2010, Lecture 19 Physics I 95.141 LECTURE 19 11/17/10.

Department of Physics and Applied Physics , F2010, Lecture 19 Physics I LECTURE 19 11/17/10.
Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lectures 35-37 Hw: Chapter 15 problems and exercises.

Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lectures Hw: Chapter 15 problems and exercises.
Phy 212: General Physics II Chapter 15: Oscillations Lecture Notes.

Phy 212: General Physics II Chapter 15: Oscillations Lecture Notes.

Similar presentations

Ads by Google