Two identical uniform solid spheres are attached by a solid uniform thin rod, as shown in the figure.

Two identical uniform solid spheres are attached by a solid uniform thin rod, as shown in the figure. The rod lies on a line connecting the centers of mass of the two spheres. The axes A, B, C, and D are in the plane of the page (which also contains the centers of mass of the spheres and the rod), while axes E and F (represented by black dots) are perpendicular to the page. (Figure 1).

ABC

Rank the moments of inertia of this object about the axes indicated. Rank from largest to smallest. To rank items as equivalent, overlap them.

Solutions

Expert Solution

Rank the moments of inertia of this object about the axes indicated. Rank from largest to smallest. To rank items as equivalent, overlap them.

Moments of inertia depend on the masses and the perpendicular distance from the axis of rotation. Mathematically it can be expressed as

I=Δmr2
The factor that effect the moment of inertia is the distance of the center of mass of the objects in question to the axis of rotation, so in this case

Axes C and F would represent the largest moments of inertia because the center of mass of the rotating body is furthest from these two axes of rotation. However, C and F would

have equal moments of inertia because they have equal distance from the center of mass to their respective axis of rotation.

The next largest would be B because it is the next closest distance from the center of mass.

A and E would come next in order because although they are exactly between the two rotating masses, they still generate a moment of inertia related to (y/2)^2

Finally, D has the lowest moment of inertia because the perpendicular distance from the axis of rotation never exceeds theradius of one of the balls. So in order from highest to

lowest:
(C and F), B, (A and E), D

genius_generous answered 1 year ago

Next > < Previous

Related Solutions

Two uniform solid spheres are joined by a light rigid rod to form a dumbbell. The...

Two uniform solid spheres are joined by a light rigid rod to form a dumbbell. The spheres are identical, and each has mass M/2. One end of a spring is attached to the center of the rod, the spring is stretched perpendicular to the rod, and the other end of the spring is attached to a wall. The dumbbell rests on a horizontal surface. Friction between the surface and the spheres prevents slipping. The system is released from rest. a)...

The figure is an overhead view of a thin uniform rod of length 0.467 m and...

The figure is an overhead view of a thin uniform rod of length 0.467 m and mass M rotating horizontally at angular speed 15.7 rad/s about an axis through its center. A particle of mass M/3 initially attached to one end is ejected from the rod and travels along a path that is perpendicular to the rod at the instant of ejection. If the particle's speed vp is 3.32 m/s greater than the speed of the rod end just after...

Two identical metal spheres A and B are connected by a plastic rod.

Two identical metal spheres A and B are connected by a plastic rod. Both are initially neutral. 4.0×1012 electrons are added to sphere A, then the connecting rod is removed. a)Afterward, what is the charge of A? b)Afterward, what is the charge of B?

Two concentric spheres are shown in the figure below.

Two concentric spheres are shown in the figure below. The inner sphere is a solid conductor and carries a charge of +5.00 μC uniformly distributed over its outer surface. The outer sphere is a conducting shell that carries a net charge of -8.00 μC. No other charges are present. The radii shown in the figure have the values R1 = 10.0cm, R2 = 20.0cm, and R3 = 30.0 cm. (a) (10 points) Find the total excess charge on the inner and...

The thin uniform rod in the figure has length 5.0 m and can pivot about a...

The thin uniform rod in the figure has length 5.0 m and can pivot about a horizontal, frictionless pin through one end. It is released from rest at angle θ = 50° above the horizontal. Use the principle of conservation of energy to determine the angular speed of the rod as it passes through the horizontal position. Assume free-fall acceleration to be equal to 9.83 m/s2.

Two balls of mass 3.29 kg are attached to the ends of a thin rod of...

Two balls of mass 3.29 kg are attached to the ends of a thin rod of negligible mass and length 72 cm. The rod is free to rotate without friction about a horizontal axis through its center. A putty wad of mass 127 g drops onto one of the balls, with a speed 2.5 m/s, and sticks to it. What is the angular speed of the system just after the putty wad hits? 1.31×10-1 rad/s ¡Correcto! Su recibo es 160-8476...

Two 1.9 kg balls are attached to the ends of a thin rod of negligible mass,...

Two 1.9 kg balls are attached to the ends of a thin rod of negligible mass, 62 cm in length. The rod is free to rotate in a vertical plane about a horizontal axis through its center. With the rod initially horizontal as shown, a 0.42 kg wad of wet putty drops onto one of the balls with a speed of 3.2 m/sec and sticks to it. 1) What is the ratio of the magnitude of angular momentum of the...

In the figure shown, one end of a uniform beam that weighs 827. N is attached to a wall with a hinge.

In the figure shown, one end of a uniform beam that weighs 827. N is attached to a wall with a hinge. The other end is held up by a wire. So the beam is in static equilibrium. There is an unknown horizontal and an unknown vertical force on the hinge.(a) Find the tension in the wire.N(b) What is the horizontal component of the force of the hinge on the beam?N(c) What is the vertical component of the force of...

Two spheres, one solid, one a thin shell, each have a mass of 0.89 kg and...

Two spheres, one solid, one a thin shell, each have a mass of 0.89 kg and a radius of 11 cm. They are given the same torque of 0.13 mN acting for 7 s. Which sphere is rotating faster?

An object is formed by attaching a uniform, thin rod with a massof mr =...

An object is formed by attaching a uniform, thin rod with a mass of mr = 6.98 kg and length L = 5.04 m to a uniform sphere with mass ms = 34.9 kg and radius R = 1.26 m. Note ms = 5mr and L = 4R.1)What is the moment of inertia of the object about an axis at the left end of the rod? kg-m22)If the object is fixed at the left end of the rod, what is the...

Subjects