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# 5.4: Dynamics of Rotating Objects

## Rolling Without Slipping and Pulleys

A very large number of the mechanical energy conservation problems we will do involve the relation we discussed previously that relates rotational motion to linear motion. Specifically we will apply this to what is referred to as rolling without slipping, or perfect rolling. There are two reasons this is an important condition to understand:

• When two surfaces slip across each other, thermal energy is the result. So when an object rolls without slipping, there may be static friction present, but there is no kinetic friction, which means that no thermal energy is produced and mechanical energy is conserved.
• When a round object rolls perfectly, the distance it travels in a straight line is directly related to the angle through which it rotates.

We’ll keep the first observation in mind for later, but right now let’s focus on the second condition:

Figure 5.4.1 – Perfect Rolling The linear distance traveled equals the arclength of the shaded region if the wheel is rolling without slipping, so we have:

$x = arclength = R\theta \;\;\; \Rightarrow \;\;\; v = \dfrac{dx}{dt} = R\dfrac{d\theta}{dt} = R\omega$

Imagine now that instead of this being a wheel, it is a spool that is unwinding. Then the blue line represents string that is coming off the spool. We can therefore conclude also that the relation $$v = R\omega$$ also applies to the linear speed of a rope that is either unraveling from a rotating spool or passing over a turning pulley.

## Total Kinetic Energy as a Sum of Linear and Rotational

It’s time we considered the case of an object whose center of mass is moving while it rotates. Let’s start with a simple case of two rocks of different masses attached by a string:

Figure 5.4.2 – Unbalanced Dumbell Spinning as It Moves This system is rotating as its center of mass moves in a straight line (assume there is no gravity present). We are given its rotational speed $$\omega$$ and the velocity of its center of mass, and wish to answer the question, "How much kinetic energy does this system possess at the moment depicted in the diagram?"

We could easily answer this question if we knew the speeds of the two rocks, but we are not given those numbers. We have to extract them from what is given, and this requires some thought. We know three things that get us to this answer:

• The velocity of a rock relative to us equals its velocity relative to the center of mass, plus the velocity of the center of mass (see Section 1.8 for a refresher).
• The center of mass lies at the point two-thirds of the distance from $$m$$ to $$2m$$.
• The rotational velocities of both rocks are the same, but the linear velocities relative to the center of mass depend upon their distances from the center of mass according to the usual $$v=r\omega$$.

Let us label the bottom rock as #1, and the top rock as #2. Putting the first and third conditions together first gives us:

$v_1=v_{cm}-r_1\omega \;\;\;\;\;\;\;\;\;\; v_2=v_{cm}+r_2\omega$

The sign of the second term in each equation is determined by whether the rotational motion adds to or takes away from the linear motion of the center of mass. Next we invoke the second condition. The fact that the center of mass is two-thirds of the distance from $$m$$ to $$2m$$ means:

$r_1 = \frac{2}{3}L \;\;\;\;\;\;\;\;\;\; r_2 = \frac{1}{3}L$

Putting all of the above into the kinetic energy of the system gives an expression for the total kinetic energy in terms of the values given. Collecting terms proportional to the squares of center of mass velocity and angular velocity gives:

$\begin{array}{l} KE_{tot} & = KE_1+KE_2 \\ & = \frac{1}{2}mv_1^2 + \frac{1}{2}\left(2m\right)v_2^2 \\ & = \frac{1}{2}m\left[v_{cm}-r_1\omega\right]^2 + \frac{1}{2}\left(2m\right)\left[v_{cm}+r_2\omega\right]^2 \\ & = \frac{1}{2}m\left[v_{cm}-\left( \frac{2}{3}L \right)\omega\right]^2 + \frac{1}{2}\left(2m\right)\left[v_{cm}+\left( \frac{1}{3}L\right)\omega\right]^2 \\ & = \frac{1}{2} \left(3m\right)v_{cm}^2 + \frac{1}{2} \left(\frac{2}{3}mL^2\right)\omega^2 \end{array}$

The $$3m$$ in the first term is the total mass of the system, so the first term is the kinetic energy of system if was not spinning. That means that the second term is the amount of kinetic energy added to the system by virtue of its spinning. The part of the second term in parentheses looks suspiciously like a rotational inertia, and in fact it equals the rotational inertia of the system about its center of mass:

$I_{cm} = m_1r_1^2 + m_2r_2^2 = \left(m\right)\left(\frac{2}{3}L\right)^2 + \left(2m\right)\left(\frac{1}{3}L\right)^2 = \frac{2}{3}mL^2$

This turns out to be a completely general rule for the kinetic energy of an object that is rotating as its center of mass moves:

$KE_{tot} = KE_{lin} + KE_{rot} = \frac{1}{2}mv_{cm}^2 + \frac{1}{2}I_{cm}\omega^2$

Example $$\PageIndex{1}$$

Show the same result (Equation 5.4.6) for two general point masses $$m_1$$ and $$m_2$$ separated by an unknown distance (call their distances from the center of mass $$r_1$$ and $$r_2$$), this time using the moment in time when $$m_1$$ is directly in front of $$m_2$$ (i.e. the line joining them is horizontal).

Solution

At the moment when the two masses form a horizontal line, their linear motions due to rotation are perpendicular to the center of mass motion. Determining their total speeds is therefore a simple application of the Pythagorean theorem, and the result follows surprisingly quickly:

$\begin{array}{l} v_1^2 = v_{cm}^2 + \left(r_1\omega\right)^2 \\ v_2^2 = v_{cm}^2 + \left(r_2 \omega \right)^2 \end{array} \nonumber$

Now plug this into the kinetic energy for the system as the sum of the kinetic energies of the two masses:

$\begin{array}{l} KE_{tot} & = \frac{1}{2} m_1 v_1^2 + \frac{1}{2} m_2 v_2^2 \\ & = \frac{1}{2} m_1 \left(v_cm^2 + r_1^2 \omega^2 \right) + \frac{1}{2} m_2 \left(v_{cm}^2 + r_2^2 \omega^2 \right) \\ & = \frac{1}{2} \left(m_1 + m_2 \right) v_{cm}^2 + \frac{1}{2} \left(m_1r_1^2 + m_2 r_2^2 \right) \omega^2 \end{array} \nonumber$

While the above equation is generally true for any object, if the object is rotating about a fixed point, the expression for total KE can be simpler to write. Specifically, it is what we have written before, in terms of the rotational inertia about the fixed point:

$KE_{tot} = \frac{1}{2}I_{fixed \; point}\omega^2$

It's not hard to show that this is equivalent to Equation 5.4.6. Assuming the fixed point is not the center of mass (or the assertion is proved trivially), then let’s call the distance from the center of mass to the fixed point “$$d$$.” The center of mass is following a circular path of radius $$d$$ around the fixed point, which means we can relate the linear velocity of the center of mass to its angular velocity around the fixed point:

$v_{cm} = \omega d$

Putting this into our center-of-mass energy equation gives:

$KE_{tot} = \frac{1}{2}mv^2_{cm} + \frac{1}{2}I_{cm}\omega^2 = \frac{1}{2}m \left(\omega d \right)^2 + \frac{1}{2}I_{cm} \omega^2 = \frac{1}{2} \underbrace{ \left( md^2 + I_{cm} \right) }_{I_{fixed \; point}}\omega^2$

Where in the final step we employed the parallel-axis theorem.

## Mechanical Energy Conservation with Perfect Rolling

Let's put together what we have concluded so far in this section. We begin by noting that two cylinders with equal masses do not possess the same rotational inertia about their central axes if one is hollow and the other is solid. Now imagine rolling both of these cylinders (without slipping) down an inclined plane. Can you guess which one would reach the bottom of the incline with the greater speed? The main point to be made here is that the energy that comes from gravitational PE goes into KE, but now the KE has two different forms: linear and rotational. The linear and angular speeds are directly related through the "no slipping" condition, so the energy will convert into the two forms of kinetic energy in a fixed ratio. We will soon see how the rotational inertia affects the ratio, but it seems clear that the hollow cylinder puts more of its energy into rotation (for the same velocity) than the solid cylinder. This would seem to indicate that the hollow will have the same kinetic energy as the solid cylinder only if it is turning (and therefore moving) more slowly.

It's easy to trick oneself in such situations, so let's solve the math carefully to be sure.

Figure 5.4.3 – Comparing Hollow and Solid Cylinder Rolling Dynamics We will work both problems in parallel, to make the difference more evident. Start with mechanical energy conservation from the top of the plane to the bottom. We can invoke this because without slipping there is no rubbing, which means no mechanical energy is converted to thermal energy.

$\Delta KE + \Delta PE_{grav} =0 \;\;\; \Rightarrow \;\;\; KE_o + PE_o = KE_f + PE_f$

If we choose the zero point of potential energy to be the bottom of the incline, the initial and final potential energies in both cases are $$mgh$$ and zero, respectively. The initial kinetic energy is zero in both cases, and the final kinetic energy is the sum of the linear and rotational kinetic energies (Equation 5.4.6):

$\begin{array}{rlll} & hollow\;cylinder & & solid\;cylinder \\ \\ energy\:conservation: & m_1gh = \frac{1}{2}m_1v_{1f}^2 + \frac{1}{2}I_1\omega_{1f}^2 & & m_2gh = \frac{1}{2}m_2v_{2f}^2 + \frac{1}{2}I_2\omega_{2f}^2 \\ perfect\;rolling \left(v=R\omega\right): & m_1gh = \frac{1}{2}m_1v_{1f}^2 + \frac{1}{2}I_1\left(\dfrac{v_{1f}}{R_1}\right)^2 & & m_2gh = \frac{1}{2}m_2v_{2f}^2 + \frac{1}{2}I_2\left(\dfrac{v_{2f}}{R_2}\right)^2 \\ rotational\;inertia\;of\;cylinders: & m_1gh = \frac{1}{2}m_1v_{1f}^2 + \frac{1}{2}\left(m_1R_1^2\right)\left(\dfrac{v_{1f}}{R_1}\right)^2 & & m_1gh = \frac{1}{2}m_2v_{2f}^2 + \frac{1}{2}\left(\frac{1}{2}m_2R_2^2\right)\left(\dfrac{v_{2f}}{R_2}\right)^2 \\ algebra: & v_{1f} = \sqrt{gh} & & v_{2f} = \sqrt{\dfrac{4gh}{3}} \end{array}$

So in fact the solid cylinder is moving faster than the hollow one, as we predicted. What is especially interesting is that with the perfect rolling condition in place, the masses and radii of the cylinders are irrelevant! We are used to final speeds of objects accelerated by gravity being independent of the mass, but here we see that when we impose perfect rolling, the radius also plays no role, but the distribution of the mass within the cylinder is all that matters.

As we are discussing mechanical energy conservation again, it is a good time to remind ourselves that our conclusions only tell us how to compare speeds before and after – what goes on between these two moments and direction of motion are lost bits of information. This is as true now that rotation is involved as it was when it wasn't. For example, if we were to race the two cylinders down identical ramps, then naturally the solid cylinder would get to the bottom first, since they both start at rest and accelerate at constant rates. The object with the faster final speed must have taken less time to get to the bottom because it had a greater average velocity. The math shown above doesn't take into account the paths the two cylinders take, so if the ramps are not identical (but still result in the same height change), the conclusion about speeds at the bottom is the same as before, but the winner of the race may not be the solid cylinder!

Example $$\PageIndex{2}$$

A solid uniform sphere starts from rest and rolls without slipping down a slope to a horizontal surface an elevation that is 3.6m below its starting point. It takes 6.6s for it to get down the slope. Find the angle the slope makes with the horizontal.

Solution

We can use energy conservation to most easily determine the final velocity of the sphere, but it is independent of the angle of the incline and the time elapsed. Still, it turns out to be a good starting point, so here is our before/after picture: The starting KE is zero, and the starting PE is $$mgh$$, while the final KE has both a translational and a rotational part, and the final PE is zero, giving the following conservation equation:

$mgh = \frac{1}{2} mv^2 + \frac{1}{2} I\omega^2 \nonumber$

We are given that it is a uniform solid sphere, which gives us its rotational inertia in terms of its mass, and we are told that it rolls without slipping, which gives us a relationship between its linear velocity and its rotational velocity. Putting all this together gives us the final velocity:

$\left. \begin{array}{l} I_{solid\;sphere} = \frac{2}{5}mR^2 \\ \omega = \dfrac{v}{R} \end{array} \right\} \;\;\; \Rightarrow \;\;\; mgh = \frac{1}{2} mv^2 + \frac{1}{2} \left(\frac{2}{5}mR^2\right)\left(\dfrac{v}{R}\right)^2 \;\;\; \Rightarrow \;\;\; v=\sqrt{\dfrac{10gh}{7}} \nonumber$

Okay, so how can we use this to find the angle? We are given the time it takes to accelerate from rest to this final speed, and the forces remain constant throughout, so the acceleration is also constant. We can therefore use kinematics to determine the distance the sphere travels down the incline. With constant acceleration starting from rest, the average velocity is just half the final velocity, and the distance covered is the average velocity multiplied by the time, so the distance the sphere rolls is:

$\Delta x = v_{ave}t = \left(\dfrac{0+v}{2}\right)t = \frac{1}{2}\sqrt{\dfrac{10gh}{7}}t \nonumber$

With the starting height and the distance along the plane known, we can use trigonometry to find the angle of the plane:

$\theta = \sin^{-1}\left(\dfrac{h}{\Delta x}\right) = \sin^{-1}\left(\dfrac{2}{t}\sqrt{\dfrac{7h}{10g}}\right) = \boxed{8.8^o} \nonumber$

Another example that falls into this same category of mechanical energy conservation with perfect rolling is a falling mass unwinding a massive spool. Let's assume the spool is frictionless and is a uniform disk, and determine the speed of the falling block after it has dropped a known distance. We are also assuming – as always – that the string is massless, but we should also point out that it is very thin, so that its departure from the spool does not reduce the radius of the spool.

Figure 5.4.4 – Falling Block Unwinds Spool Once again, we can solve this using mechanical energy conservation, as there are no non-conservative forces present. What is new here is that some of the potential energy lost by the block as it drops goes into the rotational kinetic energy of the spool. The math is strikingly similar to the rolling cylinder case above:

$\begin{array}{rl} energy\:conservation: & mgh = \frac{1}{2} mv^2 + \frac{1}{2} I \omega^2 \\ perfect\;rolling \left( v=R \omega \right): & mgh = \frac{1}{2}mv^2 + \frac{1}{2} I \left( \dfrac{v}{R} \right)^2 \\ rotational\;inertia\;of\;spool: & mgh = \frac{1}{2}mv^2 + \frac{1}{2} \left( \frac{1}{2} MR^2 \right) \left(\dfrac{v}{R} \right)^2 \\ algebra: & v = \sqrt{ \dfrac{4mgh}{2m+M} } \end{array}$

Example $$\PageIndex{3}$$

One end of a massless rope is wound around a uniform solid cylinder, while the other end passes over a massless, frictionless pulley and is attached to a hanging block with the same mass, as in the diagram below. The block is released from rest, pulling the cylinder along the horizontal surface such that it rolls without slipping. Find the speed of the block and the linear speed of the cylinder after the block has fallen a distance $$h$$. Solution

The amount that the block falls equals the distance traveled by the cylinder plus the length of rope that unwinds from it. Since the cylinder rolls without slipping, the amount that unwinds is also equal to the distance it travels, so the sum of the distance traveled by the cylinder and the rope unwound is just double the distance that the cylinder travels. Therefore, the speed of the block is at all times twice the linear speed of the cylinder.

With no non-conservative forces present, the mechanical energy of the system is conserved, so:

$mgh = \frac{1}{2}mv_{block}^2 + \frac{1}{2}mv_{cylinder}^2 + \frac{1}{2}I\omega^2 \nonumber$

We know the rotational inertia of the cylinder in terms of its mass and radius, that the block moves twice as fast as the cylinder, and that the cylinder rolls without slipping. Putting all of these constraints into the equation above gives us our answer:

$\left. \begin{array}{l} I = mR^2 \\ v_{block} = 2v_{cylinder} \\ R\omega = v_{cylinder} \end{array} \right\} \;\;\; \Rightarrow \;\;\; mgh = \frac{1}{2}m \left( 2v_{cylinder} \right)^2 + \frac{1}{2}mv_{cylinder}^2 + \frac{1}{2}\left( \frac{1}{2} mR^2 \right) \omega^2 = \dfrac{11}{4}mv_{cylinder}^2 \;\;\; \Rightarrow \;\;\; \boxed{v_{cylinder} = \sqrt{\dfrac{4gh}{11}}} \nonumber$

The speed of the block is twice this much:

$\boxed{v_{block} = \sqrt{\dfrac{16gh}{11}}} \nonumber$

## Massive Pulleys

The result for this example may remind you of an assumption we made long ago regarding pulleys. We have always assumed that they were frictionless and massless. We said that the result of these assumptions was that the tension for the rope was the same everywhere (namely on both sides of the pulley). We are now equipped to look at what happens if the pulley has mass. We'll do so with a simple model physical system. In Figure 5.4.5, the hanging block accelerates as it falls, linearly accelerating the block on the frictionless horizontal surface and rotationally accelerating the pulley in the process.

Figure 5.4.5 – Effect of a Massive Pulley on Rope Tension We are interested in comparing the tension force by the rope on both sides of this pulley, so let's use the work-energy theorem, which takes into account the forces. Treating each block as a separate system, on which the tension in each end of the rope performs work (and gravity does work on block #2 as well), and noting that both move at the same speed at all times, we have:

$\begin{array}{lcr} W_1 = \Delta KE_1 & \Rightarrow & T_1 \cdot x = \frac{1}{2} m_1v^2 \\ W_2 = \Delta KE_2 & \Rightarrow & \left(m_2g-T_2\right) \cdot x = \frac{1}{2} m_2v^2 \end{array}$

Let's compare the two tensions by computing the difference:

$\left(T_1 - T_2\right) \cdot x = \underbrace{\frac{1}{2}m_1v^2 + \frac{1}{2}m_2v^2}_{\Delta KE_{blocks}} \; \underbrace{- \; m_2gx}_{\Delta PE_{grav}}$

For the tensions to be equal, all of the gravitational potential energy lost by the falling block must go into the two blocks. But we now know that a massive pulley will have kinetic energy. Let's add the pulley's increase in kinetic energy to both sides of the equation, and invoke mechanical energy conservation:

$\left(T_1 - T_2\right) \cdot x + \left[\frac{1}{2}I\omega^2 \right]= \Delta KE_{blocks} + \left[\Delta KE_{pulley}\right] + \Delta PE_{grav} = 0 \;\;\; \Rightarrow \;\;\; T_2 - T_1 = \dfrac{\frac{1}{2}I\omega^2}{x}$

The tensions can only be equal when the rotational inertia of the pulley is zero, which means it must be massless.

Digression: Energy Storage

One of the big issues today with green energy like solar and wind-generated electricity, is storage. The advantage to fossil fuel production of electricity is that we can produce it whenever we like, but for solar and wind power, we are at the mercy of when the sun shines or the wind blows. So storing the energy generated from these green sources is of paramount importance. Batteries are coming along, but they have their own environmental issues (lithium mining, waste when they degrade, etc.), so other means of storage are sought.

There are many ideas that have been put forth, such as using spare electricity to pump water above a dam so that it can be released when needed; pressurizing tanks of air with spare electricity, then allowing the pressurized air to drive a generator later; and using spare electricity to desalinate water, followed by using the osmotic pressure between the new fresh water and the salty water to drive a generator. But possibly the best idea (which has been around a long time) is to simply store the energy in the form of kinetic energy – spin a flywheel. A flywheel is just a disk created for the sole purpose of spinning so that it holds kinetic energy until it can be used later. The idea is for the spare electricity to get this thing spinning (with as little friction as possible), so that later when we need the energy back, the flywheel can be connected to a generator and the kinetic energy can be converted back into electrical energy. The beauty of this idea is in its simplicity – it is inexpensive and scalable. And reducing the friction to a very low value is something we can do quite well with today’s technology (think maglev and evacuated chambers). In order to be as efficient with our use of space as possible, and so that we don’t reach rotational speeds that are insanely high, we will of course want flywheels with very large rotational inertias.

## Swinging Around Fixed Points

There is one other common physical situation involving mechanical energy conservation and rotation that needs to be addressed. If a rigid extended object is pivoted around a fixed point that is not the center of mass, and it is allowed to swing around that pivot under the influence of gravity, then how do we use mechanical energy conservation to describe its motion? Specifically, as the object swings, some points of the object may move upward (increasing gravitational potential energy), while others may swing downward (decreasing gravitational potential energy). How can we deal with the overall change in gravitational potential energy in such a case?

The answer will likely be unsurprising. Write the change of potential energy of the whole object as the sum of the potential energies of each tiny mass that makes up the object, and the result follows immediately:

$\begin{array}{l} \Delta U\left(whole\;object\right) & = \Delta U_1 + \Delta U_2 + \dots \\ & = m_1g\Delta y_1 + m_2g\Delta y_2 + \dots \\ & = \dfrac{Mg}{M}\left(m_1\Delta y_1 + m_2\Delta y_2 + \dots\right) \\ & = Mg\dfrac{m_1\Delta y_1 + m_2\Delta y_2 + \dots}{M}=Mg\Delta y_{cm} \end{array}$

where $$M = m_1 + m_2\ + \dots$$ is the mass of the whole object and $$\Delta y_{cm}$$ is the change in height of the center of mass of the object.

Example $$\PageIndex{4}$$

A uniform rod of length 0.70m is pivoted around a point that is one-fourth of its length from one end, and is released from rest in a horizontal orientation. Find how fast the bottom end of the rod is moving when the rod reaches a vertical orientation. Solution

The rod is uniform, so its center of mass is at its center, which means that during this swing it drops a distance of one fourth the length of the rod. All of the potential energy lost becomes kinetic energy, and all of the kinetic energy can be written as rotational if we use the rotational inertia around the fixed point, so:

$Mg\left(\dfrac{L}{4}\right)=\frac{1}{2}I\omega^2\nonumber$

Now we need the rotational inertia of the rod about the fixed point. We can get this from the parallel axis theorem:

$I_{pivot} = I_{cm} + Md^2 = \dfrac{1}{12}ML^2 + M\left(\dfrac{L}{4}\right)^2 = \frac{7}{48}ML^2 \nonumber$

Plugging this in above gives us $$\omega$$:

$\dfrac{MgL}{4}=\frac{1}{2}\left(\frac{7}{48}ML^2\right)\omega^2 \;\;\; \Rightarrow \;\;\; \omega = \sqrt{\dfrac{24g}{7L}}\nonumber$

Now all we need to do is relate the rotational speed to the linear speed of the bottom end of the rod:

$v = r\omega = \left(\frac{3}{4}L\right)\sqrt{\dfrac{24g}{7L}}=\sqrt{\dfrac{27}{14}gL} = \boxed{3.6\dfrac{m}{s}} \nonumber$