NATIONAL UNIVERSITY OF SINGAPORE NATIONAL UNIVERSITY OF SINGAPORE
ME3112
ME3112
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MECHANICS OF MACHINES MECHANICS OF MACHINES(Semester I :
(Semester I : AY2013/2014)AY2013/2014)
Time Allowed : 2 Hours Time Allowed : 2 Hours
Matriculation Number Matriculation Number __________ __________________________________________________________________________________________________________________________________________ INSTRUCTIONS TO CANDIDATES: INSTRUCTIONS TO CANDIDATES: 1.
1. Write your Matriculation Number in the box Write your Matriculation Number in the box above.above. 2.
2. This examination paper containsThis examination paper contains FOUR FOUR (4)(4) questions and comprises questions and comprises TWENTY- TWENTY-ONE (21)
ONE (21) printed pages. printed pages. 3.
3. Answer Answer ALL ALL FOUR (4)FOUR (4) questions.questions. 4.
4. Write your answers in the space provided in this question booklet.Write your answers in the space provided in this question booklet. 5.
5. This is anThis is an OPEN-BOOK EXAMINATION.OPEN-BOOK EXAMINATION. Question Question Number Number Marks Marks Obtained Obtained Maximum Maximum Marks Marks 1 1 2525 2 2 2525 3 3 2525 4 4 2525 Total Total 100100
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PAGE 2 2 ME3112ME3112
QUESTION 1 QUESTION 1 (a)
(a) An An experiment experiment was was conducted conducted by by starting starting a a wheel wheel at at rest rest and and letting letting it it roll roll down down aa plane
plane inclined inclined at at 30° 30° to to the the horizontal. horizontal. It It was was observed observed that that the the wheel wheel rolls rolls withoutwithout sliding and it travels a distance of 24 m over a time period of 4 s. With this sliding and it travels a distance of 24 m over a time period of 4 s. With this information, determine the moment of inertia of the wheel, given that its mass is 8 kg information, determine the moment of inertia of the wheel, given that its mass is 8 kg and its radius is
and its radius is 0.2 m. Acceleration due to 0.2 m. Acceleration due to gravity, g = 9.81 m/sgravity, g = 9.81 m/s22..
(15 marks) (15 marks)
Figure 1 Figure 1
(b)
(b) The inclination angle of the plane was increased slowly and the experiment wasThe inclination angle of the plane was increased slowly and the experiment was repeated. It was found that the wheel starts to slip when the inclination angle reaches repeated. It was found that the wheel starts to slip when the inclination angle reaches 45°. Determine the coefficient of static friction between the wheel and the incline 45°. Determine the coefficient of static friction between the wheel and the incline plane.
plane.
(10 marks) (10 marks)
QUESTION 2
Figure 2(a) shows an ice-cream cone which has a height h and an open base of radius r.
(a) (b)
Figure 2
(a) Given that r = 0.5 h, determine the surface area of the shell. Also, obtain the distance of the center of mass from the apex O given that the mass density is uniform.
(5 marks) (b) Determine the moment of inertia of the cone about its center of mass along an axis
perpendicular to OP.
(10 marks) (c) The ice-cream cone is placed, touching a table top, with the axis OP horizontal and
released from rest, as shown in Figure 2(b). Determine the angular acceleration of the ice-cream cone at the moment of release. You may assume that the table top is rough enough to prevent any slipping.
PAGE 12 ME3112
QUESTION 3
A block is packed in a rigid container as shown in Figure 3. During the transportation the block is assumed to be confined to vertical motion by the side frictionless supports. The internal packing is modeled as an equivalent spring with spring constant k = 2000 N/m and a viscous damper with damping ratio = c/cc = 0.05. cc is the critical damping constant and c is
the damping constant of the equivalent viscous damper. The mass of the block is 20 kg.
(a) If the base of the rigid container is subjected to a vertical displacement excitation of y = 0.2 sin t (in meter) with = 20 rad/s, determine the amplitude of vibration of the block.
(15 marks)
(b) If is near 10 rad/s, what can be done to protect the block? Justify your answer.
(10 marks)
QUESTION 4
Figure 4 shows two rotating disks with the left disk hinged at A and the right disk hinged at B. The two disks are connected together via a rigid bar hinged at point C of the left disk and point D of the right disk. All the hinged joints are assumed to be frictionless. The left disk hinged at point A has a radius of 0.6 m. The right disk hinged at point B has a radius of 0.4 m. The distance between point A and point B is 1.2 m. Both the angles CAB and DBA are equal to 60 degrees at this instant.
(a) If disk A is made to rotate 360 degrees, can disk B also make a full revolution? Define the mechanism using the Grashof’s criterion.
(5 marks) (b) If the angular velocity of the left disk hinged at A is 20 rad/s clockwise at this instant,
determine the angular velocity of the rigid link CD and the angular velocity of the right disk hinged at B at the same instant.
(20 marks)
