We can often describe a cam by drawing the displacement profile on a graph.
Consider possible displacement curves for,
The curve above can be broken into sections and described with a mathematical function,
Of these two functions, the parabolic will allow a greater level of control, but harmonic motion will permit smooth transitions between motions.
Some of the general design rules,
1. fulfil the basic motion requirements. (cam profiles are not exact and decisions are required.)
2. The displacement, velocity and acceleration curves must be continuous, but the jerk must not be infinite. This means that the positions and first and second derivatives must be equal at the segment ends.
3. Minimize the velocities and accelerations.
The first step in developing a cam is to develop a motion profile. Consider example 5-2 from Shigley and Uicker,
Now,
You may have recognized that the previous design assumed that the follower must have a point contact with the curve.
In actual practice we will have surfaces that are in contact, the surfaces can be identified using the equations developed previously.
Consider the flat-face follower.
We can develop the a modified cam profile based on the flat faced follower. (Note: the proof is done as if a milling cutter is used, but this turns out to be more a matter of convenience)
Using the derivation of the basic relationships, we can now develop a method to plot out a complete cam profile.
Now, develop a cam for example 3-52 from Shigley and Uicker,
Keep in mind that when designing cam-follower pairs that the radius of the follower is not zero. Therefore it may be necessary to compensate for this during the design.
Consider the effect of a round follower on a wedge cam.
Consider the effect of a round follower on a radial cam.
Other arrangements are possible, and some proofs are provided in the text.
