6.3 Volumes of revolution: cylindrical shells (Page 4/6)

Calculus volume 1 Page 4 / 6

Define $R$ as the region bounded above by the graph of $f (x) = x^{2}$ and below by the $x -axis$ over the interval $[0, 1] .$ Find the volume of the solid of revolution formed by revolving $R$ around the line $x = −2 .$

$\frac{11 π}{6}$ units ³

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For our final example in this section, let’s look at the volume of a solid of revolution for which the region of revolution is bounded by the graphs of two functions.

A region of revolution bounded by the graphs of two functions

Define $R$ as the region bounded above by the graph of the function $f (x) = \sqrt{x}$ and below by the graph of the function $g (x) = 1 / x$ over the interval $[1, 4] .$ Find the volume of the solid of revolution generated by revolving $R$ around the $y -axis .$

First, graph the region $R$ and the associated solid of revolution, as shown in the following figure.

This figure has two graphs. The first graph is labeled “a” and has two curves. The curves are the graphs of f(x)=squareroot(x) and g(x)=1/x. In the first quadrant the curves intersect at (1,1). In between the curves in the first quadrant there is a shaded region labeled “R”, bounded to the right by the line x=4. The second graph is labeled “b” and is the same as the graphs in “a”. Also on this graph is a solid that has been formed by rotating the region “R” from the figure “a” about the y-axis. — (a) The region $R$ between the graph of $f (x)$ and the graph of $g (x)$ over the interval $[1, 4] .$ (b) The solid of revolution generated by revolving $R$ around the $y -axis .$

Note that the axis of revolution is the $y -axis,$ so the radius of a shell is given simply by $x .$ We don’t need to make any adjustments to the x -term of our integrand. The height of a shell, though, is given by $f (x) - g (x),$ so in this case we need to adjust the $f (x)$ term of the integrand. Then the volume of the solid is given by

\begin{matrix} V & = \int_{1}^{4} (2 π x (f (x) - g (x))) d x \\ = \int_{1}^{4} (2 π x (\sqrt{x} - \frac{1}{x})) d x = 2 π \int_{1}^{4} (x^{3 / 2} - 1) d x \\ = {2 π [\frac{2 x^{5 / 2}}{5} - x] |}_{1}^{4} = \frac{94 π}{5} {units}^{3} . \end{matrix}

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Define $R$ as the region bounded above by the graph of $f (x) = x$ and below by the graph of $g (x) = x^{2}$ over the interval $[0, 1] .$ Find the volume of the solid of revolution formed by revolving $R$ around the $y -axis .$

$\frac{π}{6}$ units ³

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Which method should we use?

We have studied several methods for finding the volume of a solid of revolution, but how do we know which method to use? It often comes down to a choice of which integral is easiest to evaluate. [link] describes the different approaches for solids of revolution around the $x -axis .$ It’s up to you to develop the analogous table for solids of revolution around the $y -axis .$

This figure is a table comparing the different methods for finding volumes of solids of revolution. The columns in the table are labeled “comparison”, “disk method”, “washer method”, and “shell method”. The rows are labeled “volume formula”, “solid”, “interval to partition”, “rectangles”, “typical region”, and “rectangle”. In the disk method column, the formula is given as the definite integral from a to b of pi times [f(x)]^2. The solid has no cavity in the center, the partition is [a,b], rectangles are vertical, and the typical region is a shaded region above the x-axis and below the curve of f(x). In the washer method column, the formula is given as the definite integral from a to b of pi times [f(x)]^2-[g(x)]^2. The solid has a cavity in the center, the partition is [a,b], rectangles are vertical, and the typical region is a shaded region above the curve of g(x) and below the curve of f(x). In the shell method column, the formula is given as the definite integral from c to d of 2pi times yg(y). The solid is with or without a cavity in the center, the partition is [c,d] rectangles are horizontal, and the typical region is a shaded region above the x-axis and below the curve of g(y).

Let’s take a look at a couple of additional problems and decide on the best approach to take for solving them.

Selecting the best method

For each of the following problems, select the best method to find the volume of a solid of revolution generated by revolving the given region around the $x -axis,$ and set up the integral to find the volume (do not evaluate the integral).

The region bounded by the graphs of $y = x,$ $y = 2 - x,$ and the $x -axis .$
The region bounded by the graphs of $y = 4 x - x^{2}$ and the $x -axis .$

First, sketch the region and the solid of revolution as shown.

(a) The region $R$ bounded by two lines and the $x -axis .$ (b) The solid of revolution generated by revolving $R$ about the $x -axis .$

Looking at the region, if we want to integrate with respect to $x,$ we would have to break the integral into two pieces, because we have different functions bounding the region over $[0, 1]$ and $[1, 2] .$ In this case, using the disk method, we would have

$V = \int_{0}^{1} (π x^{2}) d x + \int_{1}^{2} (π {(2 - x)}^{2}) d x .$

If we used the shell method instead, we would use functions of $y$ to represent the curves, producing

$\begin{matrix} V & = \int_{0}^{1} (2 π y [(2 - y) - y]) d y \\ = \int_{0}^{1} (2 π y [2 - 2 y]) d y . \end{matrix}$

Neither of these integrals is particularly onerous, but since the shell method requires only one integral, and the integrand requires less simplification, we should probably go with the shell method in this case.
First, sketch the region and the solid of revolution as shown.

(a) The region $R$ between the curve and the $x -axis .$ (b) The solid of revolution generated by revolving $R$ about the $x -axis .$

Looking at the region, it would be problematic to define a horizontal rectangle; the region is bounded on the left and right by the same function. Therefore, we can dismiss the method of shells. The solid has no cavity in the middle, so we can use the method of disks. Then

$V = \int_{0}^{4} π {(4 x - x^{2})}^{2} d x .$

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Source: OpenStax, Calculus volume 1. OpenStax CNX. Feb 05, 2016 Download for free at http://cnx.org/content/col11964/1.2

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