motion sensors displacement, velocity and acceleration
DESCRIPTION
Motion Sensors Displacement, velocity and acceleration. Dimensional measurement. Micrometers. Vernier caliper. One complete revolution = 0.5 mm (usually) With 50 divisions, each division movement corresponds to 0.01 mm - PowerPoint PPT PresentationTRANSCRIPT
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Motion SensorsDisplacement, velocity and acceleration
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Dimensional measurement
• One complete revolution = 0.5 mm (usually)• With 50 divisions, each division movement
corresponds to 0.01 mm• If user can control every one-fifth of a
division, a resolution of 0.002 mm is possible
MicrometersVernier caliper
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Height & depth measurement
Gauge blocks
Dial gauge: typical resolution 0.01 mm Height & depth gauges
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Types: wire-wound, carbon-film and plastic-film (according to resistance element)
Linear potentiometer Rotary potentiometer (a) circular; (b) helical
Resistive potentiometer
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Primary Secondary
Linear Variable Differential Transformer (LVDT)
• Inductive displacement sensor.• Transformer with 1 primary & 2 secondary coils, connected in series opposition• Output voltage (difference between induced voltages) is proportional to core
displacement• Zero reading when core is centered
Rotary differential transformer
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Eddy current sensor• Inductive displacement sensor.• Coil is excited at high frequency (typically 1 MHz)• This induces eddy current in the target• Eddy current alters the inductance of the probe coil• This change can be translated into a voltage proportional to the air gap
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Piezoelectric transducers
• A piezoelectric material generates charge when deformed• Induced charge leaks away with time• Piezoelectric transducers are not suitable for static or slowly-varying dispalcements
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Optical encoders (incremental)• Measure instantaneous angular position of a shaft• Output is in the form of pulses to be counted
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Optical encoders (coded-disc)
• Output is in the form binary numbers to give absolute measure of shaft position
Float encoder
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Other rotational motion sensors• Gyroscopes• Tachometers • Mechanical flyball
Gyroscope
Photoelectric tachometer
Mechanical flyball
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Vibration Measurement
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Energy Harvesting
Source: J.K. Ward and S. Behrens, “Adaptive learning algorithms for vibration energy harvesting”, Smart Materials & Structures 17 (2008) 035025 1-9.
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Vibration-based Energy Harvesting
Source: B.P. Mann and N.D.Sims, “Energy harvesting from the nonlinear oscillations of magentic levitation”, Journal of Sound and Vibration (2008) in press.
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