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Volume: The Disk Method

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1 Volume: The Disk Method
7.2 Volume: The Disk Method

2 Example Suppose I start with this curve.
Rotate the curve about the x-axis to obtain a nose cone in this shape. How could we find the volume of this cone?

3 r = the y value of the function
One way would be to cut it into a series of thin slices (flat cylinders) and add their volumes. The volume of each flat cylinder (disk) is: r = the y value of the function thickness = dx If we add the volumes, we get:

4 Disk Method If y = f(x) is the equation of the curve whose area is being rotated about the x-axis, then the volume is a and b are the limits of the area being rotated dx shows that the area is being rotated about the x-axis

5 Example Find the volume of the solid obtained by rotating the region bounded by the given curves

6 Example Find the volume of a cone whose radius is 3 ft and height is 1ft.

7 Example y-axis is revolved about the y-axis. Find the volume.
The region between the curve , and the y-axis is revolved about the y-axis. Find the volume. y x We use a horizontal disk. The thickness is dy. The radius is the x value of the function volume of disk

8 Example Find the volume of the solid of revolution generated by rotating the curve y = x3 between y = 0 and y = 4 about the y-axis.

9 The natural draft cooling tower shown at left is about 500 feet high and its shape can be approximated by the graph of this equation revolved about the y-axis: The volume can be calculated using the disk method with a horizontal disk.

10 Example The region bounded by and is revolved about the y-axis.
Find the volume. If we use a horizontal slice: The “disk” now has a hole in it, making it a “washer”. The volume of the washer is: outer radius inner radius

11 Washer Method This application of the method of slicing is called the washer method. The shape of the slice is a circle with a hole in it, so we subtract the area of the inner circle from the area of the outer circle. The washer method formula is:

12 Example If the same region is rotated about the line x=2:
The outer radius is: The inner radius is: r R

13 Method of Slicing 1 Sketch the solid and a typical cross section.
Find a formula for V(x). 2 3 Find the limits of integration. 4 Integrate V(x) to find volume.

14 Example Find the volume of the pyramid:
3 Example Find the volume of the pyramid: Consider a horizontal slice through the pyramid. The volume of the slice is s2dh. If we put zero at the top of the pyramid and make down the positive direction, then s=h. h s This correlates with the formula: dh 3

15 Examples Find the volume of the solid of revolution generated by rotating the curve y = x2 , x = 0 and y = 4 about the given line. y-axis x-axis the line x = 3 the line y = - 2

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