Top Banner
Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 7: Rotations around a fixed axis Q8 19: General motion: Velocities Q20 25: Instantaneous Centres Comments and corrections to [email protected] Lecture resources may be found on Blackboard and at http://connormyant.com
25

Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

May 09, 2018

Download

Documents

buingoc
Welcome message from author
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Page 1: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Tutorial Problem sheet 1:

Planar Kinematics

DE2 EA2.1 M4DE

Q1 – 7: Rotations around a fixed axisQ8 – 19: General motion: VelocitiesQ20 – 25: Instantaneous Centres

Comments and corrections to [email protected]

Lecture resources may be found on Blackboard and at http://connormyant.com

Page 2: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q1

At the instant shown, the disk’s angular velocity is 2 rad/s counter-clockwise and its angular acceleration is 6 rad/s2 counter-clockwise.

What are the magnitudes of the velocity and acceleration of point 𝐴, if 𝑟 = 0.2 m?

𝑂

𝐴

𝑟

𝜔

𝛼

v = 0.4 m/s

an = 0.8 m/s2

at = 1.2 m/s2

Page 3: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q2

The angle 𝜃 (in radians) is given as a function of time by 𝜃 = 0.2𝜋𝑡2. At 𝑡 = 4 s, determine the magnitudes of:

(a) the velocity of point 𝐴 and

(b) the tangential and normal components of acceleration of point 𝐴.

Page 4: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q3

The mass 𝐴 starts from rest at 𝑡 = 0 and falls with a constant acceleration of 8 m/s2. When the mass has fallen one meter, determine the magnitudes of

(a) the angular velocity of the pulley and

(b) the tangential and normal components of acceleration of a point at the outer edge of the pulley.

Page 5: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q4

At the instant shown, the left disk has an angular velocity of 3 rad/s counter-clockwise and an angular acceleration of 1 rad/s2 clockwise.

(a) What are the angular velocity and angular acceleration of the right disk? (Assume that there is no relative motion between the disks at their point of contact.)

(b) What are the magnitudes of the velocity and acceleration of point 𝐴?

(a) ωR = 1.2 rad/sαR = 0.4 rad/s2

(b) vA = 2.4m/s𝑎𝐴 = 2.99m/s2

Page 6: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q5

Consider the bicycle below;

(a) If the bicycle’s 120-mm sprocket wheel rotates through one revolution, through how many revolutions does the 45-mm gear turn?

(b) If the angular velocity of the sprocket wheel is 1 rad/s, what is the angular velocity of the gear?

𝜃𝐵 = 2.67 revωB = 2.67 rad/s

Page 7: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q6

The disk is rotating about the origin with a constant clockwise angular velocity of 100 rpm.

Determine the 𝑥 and 𝑦 components of velocity of points 𝐴 and 𝐵 (in cm/s).

Page 8: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q7

A disk of radius 𝑅 = 0.5 m rolls on a horizontal surface. The relationship between the horizontal distance x the center of the disk moves and the angle 𝛽 through which the disk rotates is 𝑥 = 𝑅𝛽.

Suppose that the center of the disk is moving to the right with a constant velocity of 2 m/s.

a) What is the disk’s angular velocity?

b) Relative to a nonrotating reference frame with its origin at the center of the disk, what are the magnitudes of the velocity and acceleration of a point on the edge of the disk?

ω = 4 rad/s𝑣 = 2 m/s𝑎 = 8 m/s2

Page 9: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q8

The rectangular plate swings in the 𝑥 – 𝑦 plane from arms of equal length. What is the angular velocity of (a) the rectangular plate and (b) the bar 𝐴𝐵?

Page 10: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q9

Bar 𝑂𝑄 is rotating in the clockwise direction at 4 rad/s. What are the angular velocity vectors of the bars 𝑂𝑄 and 𝑃𝑄?

Strategy: Notice that if you know the angular velocity of bar 𝑂𝑄, you also know the angular velocity of bar 𝑃𝑄.

Page 11: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q10

A disk of radius 𝑅 = 0.5 m rolls on a horizontal surface. The relationship between the horizontal distance 𝑥 the center of the disk moves and the angle 𝛽 through which the disk rotates is 𝑥 = 𝑅𝛽. Suppose that the center of the disk is moving to the right with a constant velocity of 2 m/s.

(a) What is the disk’s angular velocity?

(b) What is the disk’s angular velocity vector?

Page 12: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q11

The bracket is rotating about point 𝑂 with counter-clockwise angular velocity 𝜔. The magnitude of the velocity of point 𝐴 relative to point 𝐵 is 4 m/s.

Determine 𝜔.

Page 13: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q12

The helicopter is in planar motion in the 𝑥 – 𝑦 plane.

At the instant shown, the position of its center of mass, 𝐺, is 𝑥 = 2 𝑚, 𝑦 = 2.5 𝑚, and its velocity is 𝑣𝐺 = 12𝑖 + 4𝑗 (𝑚/𝑠). The position of point 𝑇, where the tail rotor is mounted, is 𝑥 = −3.5 𝑚, 𝑦 = 4.5 𝑚. The helicopter’s angular velocity is 0.2 (rad/s) clockwise.

What is the velocity of point 𝑇?

𝑣𝑇 = 12.4𝑖 + 5.1𝑗 m/s

Page 14: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q13

Points 𝐴 and 𝐵 of the 2 m bar slide on the plane surfaces. Point 𝐵 is moving to the right at 3 m/s.

What is the velocity of the midpoint G of the bar?

Page 15: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q14

At the instant shown, the piston’s velocity is 𝑣𝐶 = −14𝑖 𝑚/𝑠.

What is the angular velocity of the crank 𝐴𝐵?

Page 16: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q15

Bar 𝐴𝐵 rotates in the counter-clockwise direction at 6 rad/s.

Determine the angular velocity of bar 𝐵𝐷 and the velocity of point 𝐷.

Page 17: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q16

The horizontal member 𝐴𝐷𝐸 supporting the scoop is stationary. If the link 𝐵𝐷 is rotating in the clockwise direction at 1 rad/s, what is the angular velocity of the scoop?

Page 18: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q17

The disk rolls on the curved surface. The bar rotates at 10 rad/s in the counter-clockwise direction.

Determine the velocity of point 𝐴.

𝑣𝐴 = 1200𝑖 + 1200𝑗 mm/s

Page 19: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q18

An athlete exercises his arm by raising the mass 𝑚. The shoulder joint 𝐴 is stationary. The distance 𝐴𝐵 is 300 mm, and the distance 𝐵𝐶 is 400 mm.

At the instant shown, 𝜔𝐴𝐵 = 1 rad/s and 𝜔𝐵𝐶 = 2 rad/s.

How fast is the mass 𝑚 rising?

Page 20: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q19

If the bar has a clockwise angular velocity of 10 rad/s and 𝑣𝐴 = 20 m/s, what are the coordinates of its instantaneous center of the bar, and what is the value of 𝑣𝐵?

𝑣𝐵 = 10𝑗 m/s

Page 21: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q20

The velocity of point 𝑂 of the bat is 𝑣𝑂 = −1.83𝑖 −4.27𝑗 m/s, and the bat rotates about the 𝑧 axis with a counter-clockwise angular velocity of 4 rad/s.

What are the 𝑥 and 𝑦 coordinates of the bat’s instantaneous center?

Page 22: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q21

Points 𝐴 and 𝐵 of the 1 m bar slide on the plane surfaces. The velocity of B is 𝑣𝐵 = 2𝑖 m/s.

(a) What are the coordinates of the instantaneous center of the bar?

(b) Use the instantaneous center to determine the velocity at 𝐴.

Coordinates; (0.3420, 0.9397) m𝑣𝐴 = −0.7279𝑗 m/s

Page 23: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q22

The angle 𝜃 = 45°, and the bar 𝑂𝑄 is rotating in the counterclockwise direction at 0.2 rad/s.

Use instantaneous centers to determine the velocity of the sleeve 𝑃.

𝑣𝑝 = 0.566 m/s to the left

Page 24: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q23

The crank 𝐴𝐵 is rotating in the clockwise direction at 2000 rpm.

(a) At the instant shown, what are the coordinates of the instantaneous center of the connecting rod 𝐵𝐶?

(b) Use instantaneous centers to determine the angular velocity of the connecting rod 𝐵𝐶 at the instant shown.

Page 25: Tutorial Problem sheet 1 - WordPress.com · Tutorial Problem sheet 1: Planar Kinematics DE2 EA2.1 M4DE Q1 –7: Rotations around a fixed axis Q8 –19: General motion: Velocities

Q24

The horizontal member 𝐴𝐷𝐸 supporting the scoop is stationary. The link 𝐵𝐷 is rotating in the clockwise direction at 1 rad/s.

Use instantaneous centers to determine the angular velocity of the scoop.

ω𝐶𝐸 = 1.47 rad/s