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<< Click to Display Table of Contents >> Navigation: MotionDesigner Reference & User Interface > Motion-Law Coefficients / Characteristic Values |
You can use the Motion-Law Characteristic Values DE: Kennwert to compare Traditional Motion-Laws.
Label |
Normalized Characteristic Values |
Nominal Relevance |
|---|---|---|
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Velocity |
A measure of the maximum Pressure Angle. |
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Acceleration |
A measure of the maximum force on a follower from the inertia of the following-system. |
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Effective Acceleration |
A measure of RMS inertia load on a follower over a machine-cycle. |
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Jerk |
A measure of the risk of the motion exciting a vibration in the follower-system. |
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Torque (cam-system) |
A measure of the maximum torque to rotate a camshaft, when the following system is an inertia load. |
Power (servo-system) |
A measure of the maximum Power required from a Servomotor to directly drive a linear inertia load. |
The Normalized Characteristic Values are equal to the maximum motion-values when the motion has a:
•period: and
•displacement: (linear or angular).
To calculate the actual maximum motion-values you need to know the:
•motion-law
•maximum displacement,
•motion period,
Actual Maximum Velocity = |
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Note: If you reduce the motion-period, , by about 10% the : •maximum velocity increases by ~10%, •maximum acceleration increases by ~20% •maximum jerk increases by ~40% |
Actual Maximum Acceleration = |
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Actual Maximum Jerk = |
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Usually, it is desirable that the speed of the cam-shaft is constant. However, a force-closed follower system imposes three torque components on the cam-shaft, each of which tends to decrease or increase its speed.
Label |
Torque Factor |
Normalized Value |
Nominal Relevance |
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|---|---|---|---|---|
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Constant Load |
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The component of drive torque required to overcome a static or constant load of the follower-system, for example, due to gravity or friction. It is identical to the normalized Velocity, . Usually the least significant Torque Factor. |
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Inertia Load |
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The component of drive torque required to accelerate the inertia load of a follower-system. Usually the most dominant. It disregards Spring Force. It is also an indication of the Power required from a servo-system to drive an inertia load. |
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Spring Load |
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The component of drive torque required to overcome the linear increase in force as a spring is compressed in the follower-system. It disregards the inertia force. |
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where |
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= normalized displacement (0 1) |
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= non-dimensional velocity |
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= non-dimensional acceleration |
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Note on Input Torque
The maximum torque that is needed to drive a Cam is important. However, the rate-of-change of torque, especially at crossover, as it changes from positive to negative torque is also important, if not more important than the maximum torque. A positive input torque on the cam-shaft winds-up (twists) the cam-shaft. A negative torque winds-down (untwists) the cam-shaft. When the Torque changes from a positive to a negative value, at the crossover, backlash in the drive shaft system, and the following-system begins to be traversed, and the Torque at the input suddenly reduces to only the “friction torque”. The speed of the drive-motor and cam-shaft may increase rapidly. Therefore the impact shock after the backlash is traversed is also increased beyond the impact that would be the case had the speed remains constant. If the speed of the motor does increase, the motion-law of the cam is distorted and the maximum values of velocity and deceleration also increase, sometimes substantially. When percentage increase to the speed at crossover is called the percentage Overrun. |
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Power - constant Torque and constant Angular Velocity |
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Power - constant Force and constant Linear Velocity |
Of course, Torque and Angular Velocity at the Follower continuously change throughout the motion. Thus, the Power at the output shaft also changes continuously. We can use to indicate any step in the motion.
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Instantaneous Power - varying Torque and Angular Velocity |
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Instantaneous Power - varying Force and Linear-Velocity |
Torque and Force are found from the product of inertia and angular-acceleration, and from mass and linear-acceleration, respectively.
However, the:
•Acceleration continually changes throughout the motion - of course.
•Load Inertia and Mass, referred to the driven-shaft, can be constant (e.g. Dial-Plate) or can continually change (e.g. Toggle mechanism). In the general case, the reflected Load Inertia and Mass vary throughout the motion.
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Load Torque with changing Load Inertia and Angular Acceleration. |
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Load Force with changing Load Mass and Linear Acceleration |
Therefore, the instantaneous Power is:
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Power with changing Load Inertia, Angular Acceleration, and Angular Velocity. |
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Power with changing Load Mass, Linear Acceleration, and Linear Velocity. |
Motion-Law Name |
Velocity Coefficient
|
Acceleration Coefficient
|
Torque Coefficient
|
Power Coefficient
|
|---|---|---|---|---|
Constant Acc & Dec |
2 |
4 |
2 |
8 |
Simple Harmonic |
π/2 |
π2/2 |
0.785 |
3.8758 |
Cycloidal |
2 |
6.283185 |
1.298 |
8.1621 |
Modified Trapezoid |
2 |
4.888124 |
1.655 |
8.0894 |
Polynomial 3-4-5 |
1.875 |
5.773503 |
1.159 |
6.6925 |
Polynomial 4-5-6-7 |
2.1875 |
7.5132 |
1.431 |
10.750 |
Modified Sine |
1.759603 |
5.527957 |
0.987 |
5.4575 |
Edit the Segment Parameters (in the Segment Editor) of the Sine-Constant-Cosine Acceleration (SCCA) Motion-Law to give many of the popular motion cam-laws for industrial cams.
Motion-Law Name |
Characteristic Values |
SCCA Parameters (Factors) |
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|---|---|---|---|---|---|
Velocity Coefficient Cv |
Acceleration Coefficient Ca |
a |
b |
c |
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Modified-Sine CV 0% |
1.760 |
5.528 |
0.25 |
0 |
0.75 |
Modified-Sine |
1.528 |
5.999 |
0.2 |
0 |
0.6 |
Modified-Sine |
1.404 |
6.616 |
0.1667 |
0 |
0.5 |
Modified-Sine |
1.275 |
8.0127 |
0.125 |
0 |
0.375 |
Modified-Sine |
1.168 |
11.009 |
0.0833 |
0 |
0.25 |
Cycloidal |
1.333 |
8.378 |
0.25 |
0 |
0.25 |
Trapezoidal Velocity CV 33% |
1.5 |
4.5 |
0 |
0.6667 |
0 |
Edit the Segment Parameters (in the Segment Editor) of the Triple Harmonic Motion-Law to give alternatives to some of the popular motion-laws.
Motion-Law Name
|
Characteristic Values |
Harmonic (Segment Parameters) |
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|---|---|---|---|---|---|
Velocity Cv |
Acceleration Ca |
1st |
2nd |
3rd |
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3-Harmonic |
2.0 |
5.16 |
5.96 |
0 |
0.9696 |
3-Harmonic |
1.72 |
6.07 |
5.1968 |
1.7690 |
0.6057 |
3-Harmonic |
2.0 |
9.42 |
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0 |
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