Physics Rotational Mechanics Level: High School
A coin is placed 25 cm from the center of a horizontal turntable , initially at rest . The turntable then begins to rotate . When the speed of the coin is 110 cm / s (rotating at a constant rate ) , the coin just begins to slip . The acceleration of gravity is 980 cm / s^2 . What is the coefficient of static friction between the coin and the turntable ?
Physics Work,Power & Energy Level: High School
Vertical Circle
A pail of water of mass 2.05 kg is rotated in a vertical circle of radius 2.03 m . What is the minimum speed of the pail a the top of the circle if no water is to split out ?1) 2.23013 m / s
2) 19.894 m / s
3) 8.92054 m / s
4) 6.30777 m / s
5) 4.46027 m / s
Physics Work,Power & Energy Level: High School
Circular Motion
A 5.38 kg block is released from A at height 4.02 m on a frictionless track shown in the figure at “click here” . Determine the magnitude of the acceleration for the block at P . Answer in units of m / s^2 .
Physics Rotational Mechanics Level: High School
A racing car travels on a circular track of radius 105 m . The car moves with a constant linear speed of 37.2 m / s . Find the angular speed . Answer in units of rad / s .a) Find the magnitude of its acceleration . Answer in units of m / s^2 .
Physics Rotational Mechanics Level: High School
A flywheel with a very low friction bearing takes 1.1 hours to stop after the motor power is turned off . The flywheel was originally rotating at 41 rpm . What was the initial rotation rate in radians per second ? Answer in units of rad / s .a) How many revolutions does the flywheel make before it stops ? Answer in units of revs .
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
A 1200 N uniform boom is supported by a cable perpendicular to the boom , as seen in the figure at “click here” . The boom is hinged at the bottom , and a m = 2060 N weight hangs from its top . Assume the angles to be alpha = 64.4 degrees and theta = 90.0 degrees – alpha . Find the tension in the supporting cable .
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
The mobile in the figure at “click here” is in equilibrium . The object B has mass of 0.630 kg .a) Determine the mass of object C . Assume L1 = 30.0 cm , L2 = 7.30 cm , L3 = 14.4 cm , L4 = 5.10 cm , L5 = 16.8 cm and L6 = 5.10 cm . (Neglect the weights of the crossbars .)
b) Determine the mass of the object A .
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
A shop sign weighing 220 N is supported by a uniform 128 N beam of length L = 1.89 m as shown in the figure at “click here” . The guy wire is connected D = 1.35 m from the backboard .a) Find the tension in the guy wire . Assume theta = 38.3 degrees .
b) find the horizontal force exerted by the hinge on the beam .
c) Find the vertical force exerted by the hinge on the beam . Use “up” as the positive direction .
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
Three boys are trying to balance on a seesaw , which consists of a fulcrum rock as a pivot at the center , and a very light board L = 3.66 m long , see figure at “click here” . Two boys are already on either end . One has a mass of m1 = 44.0 kg , and the other a mass of m2 = 30.8 kg . How far from the center should the third boy , whose mass is m3 = 26.8 kg . place himself so as to balance the seesaw ?
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
A uniform m = 14.2 N picture frame is supported as shown in the figure at “click here” .The length of the frame is L = 32.2 cm , the width is W = 14.7 cm and assume the angle is alpha = 53.3 degrees .a) Find the tension in cord T1 .
b) Find the tension in the cord T2 .
c) Calculate the magnitude of the horizontal force at m that is required to hold the frame in the position shown .
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
The arm in the figure which is shown at “click here” weighs 42.6 N . The force of gravity acting on the arm acts through point A . Assume that L1 = 0.0730 m , L2 = 0.335 m and infinite = 10.4 degrees .a) Determine the magnitude of the tension force F1 in the deltoid muscle .
b) Determine the magnitude of the tension force Fs of the shoulder on the humerus (upper-arm bone) to hold the arm in the position shown .
c) Determine the angle of tension force Fs relative to the x-axis .
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
Calculate the mass m needed in order to suspend the leg shown in figure at “click here”. Assume the leg (with cast) has a mass of 13.0 kg , and its CG is 37.0 m from the hip joint ; the sling is 77.2 cm from the hip joint .
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
In the figure which is shown at “click here” are seven situations where a student is holding a meter stick at the left end at various angles . A 1.0 kg mass is hung on the meter sticks at different locations . The meter stick is held stationary in all cases . All of the meter sticks are identical , but the distance along the meter stick at which the 1.0 kg mass is hung and the angles at which the student holds the meter stick vary . Specific values are given in each figure . (Ignore the mass of the meter stick.) Which of the following statements are true about the situations depicted in the figures above ?a) The torque is the same in all situations .
b) The lever arm is the same in picture B and C .
c) The net force acting on the meter stick in picture G is larger than in picture C .
d) The lever arm in picture A is : L/2 .
e) The meterstick is harder to hold in picture A than in picture B .
Physics Rotational Mechanics Level: High School
Balancing a Meter Stick
A meter stick is found to balance at the 45.0 cm mark when placed on a fulcrum . When a 46.0 g mass is attached at the 12.6 cm mark , the fulcrum must be moved to the 35.2 cm mark for balance . What is the mass of the meter stick ?
Physics Rotational Mechanics Level: High School
Rotational Equilibrium
A window washer with a mass of 73.0 kg stands a distance , D = 0.800 m , from the left end of a plank of length , L = 1.90 m ,with a mass of 17.0 kg . The plank is hung on two cables . Find T2, the tension in the right cable .