Basics of encoders DynAPAR..........................
KrishnaPYadav1
23 views
17 slides
Aug 07, 2024
Slide 1 of 17
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
About This Presentation
Basics of encoders DynAPAR
Slide Content
08/07/24 p 1
Encoder Basics #1
Encoder Basics #1
Confidential
p 2
Encoder Basics
We will be covering:
•Common names & definitions
•Types
•Technology
•Mechanical designs
•Output
•Applications
p 2
Encoder Basics
We will be covering:
•Common names & definitions
•Types
•Technology
•Mechanical designs
•Output
•Applications
Confidential
p 3
Different Names for Encoders
•Rotopulser
•Pulse Generator
•Digital Tachometer
•Tach
•Pulse Tach
•Shaft Encoder
A lot of names…..
p 3
Different Names for Encoders
•Rotopulser
•Pulse Generator
•Digital Tachometer
•Tach
•Pulse Tach
•Shaft Encoder
A lot of names…..
Confidential
p 4
Definitions
•Tachometer – Analog device that produces a voltage
proportional to speed.
•Encoder – Digital device that produces pulses based on
rotational position
p 4
Definitions
•Tachometer – Analog device that produces a voltage
proportional to speed.
•Encoder – Digital device that produces pulses based on
rotational position
Confidential
p 5
Encoder Basics
Encoder Types:
•Incremental
–Provides identical electronic pulses at each division of shaft
rotation.
–Used for speed or velocity control of motors
•Absolute
–Provides a unique electronic piece of information at each
division of shaft position.
–Used for positioning systems
•Resolver
–Provides sine wave and cosine wave to provide both velocity
and position feedback.
p 5
Encoder Basics
Encoder Types:
•Incremental
–Provides identical electronic pulses at each division of shaft
rotation.
–Used for speed or velocity control of motors
•Absolute
–Provides a unique electronic piece of information at each
division of shaft position.
–Used for positioning systems
•Resolver
–Provides sine wave and cosine wave to provide both velocity
and position feedback.
Confidential
p 6
Encoder Basics
Sensing Technologies:
•Magnetic (Magneto-resistive)
–Tough and simple
–Heavy Duty enough for Mills
–No Optics (no glass breakage)
–Limited to 2048 PPR
•Optical
–Higher Resolution (up to 10,000 PPR)
–Better signal quality
–Shafted and Hollow shaft designs
NORTHSTAR
DYNAPAR
&
NORTHSTAR HD OPTICAL
p 6
Encoder Basics
Sensing Technologies:
•Magnetic (Magneto-resistive)
–Tough and simple
–Heavy Duty enough for Mills
–No Optics (no glass breakage)
–Limited to 2048 PPR
•Optical
–Higher Resolution (up to 10,000 PPR)
–Better signal quality
–Shafted and Hollow shaft designs
NORTHSTAR
DYNAPAR
&
NORTHSTAR HD OPTICAL
Confidential
p 7
Magneto-Resistive Technology
•Features a magnetic pulse wheel
that is imprinted with numerous,
small magnetic poles.
•Rotation of the magnetic pulse wheel
creates an alternating pattern of
north-south magnetic fields for the
pick-up head.
•The electrical circuit in the sensor
produces digital pulses proportional
to motor speed.
p 7
Magneto-Resistive Technology
•Features a magnetic pulse wheel
that is imprinted with numerous,
small magnetic poles.
•Rotation of the magnetic pulse wheel
creates an alternating pattern of
north-south magnetic fields for the
pick-up head.
•The electrical circuit in the sensor
produces digital pulses proportional
to motor speed.
Confidential
p 8
Optical Technology
•Utilizes a glass, plastic or metal rotating disc that operates in an
light path between a photoelectric transmitter (LED) and
receiver.
p 8
Optical Technology
•Utilizes a glass, plastic or metal rotating disc that operates in an
light path between a photoelectric transmitter (LED) and
receiver.
08/07/24 p 9
Encoder Mounting Styles
Encoder Mounting Styles
Confidential
p 10
Encoder Basics
Mechanical Designs:
•Hollow Shaft
–Encoder mounting on shaft
extension with bearings and
torque arm.
•Coupled
–Machined face, bracket, stub
shaft and a flexible coupling.
•Bearingless
–Frame of encoder bolts to
motor, pulse wheel mounts on
shaft extension or stub shaft.
NorthStar: HSD35,
HSD37, Slim Tach HS56
Dynapar:
HS20 & HS35
NorthStar: RIM 6200, HSD44
Dynapar: H56 Rotopulser
NorthStar:
SLIM Tach:
SL56, SL85, RL67
RIM Tach:
RIM8500, RIM1250
p 10
Encoder Basics
Mechanical Designs:
•Hollow Shaft
–Encoder mounting on shaft
extension with bearings and
torque arm.
•Coupled
–Machined face, bracket, stub
shaft and a flexible coupling.
•Bearingless
–Frame of encoder bolts to
motor, pulse wheel mounts on
shaft extension or stub shaft.
NorthStar: HSD35,
HSD37, Slim Tach HS56
Dynapar:
HS20 & HS35
NorthStar: RIM 6200, HSD44
Dynapar: H56 Rotopulser
NorthStar:
SLIM Tach:
SL56, SL85, RL67
RIM Tach:
RIM8500, RIM1250
Confidential
p 11
Hollow Shaft Encoders
•The lowest cost encoder to install
–No couplings to align or isolate
–No adapter (flower pot)
–No machined fan cover required on TEFC motors
•Flexible torque arm
–Allow encoder to ride freely on shaft extension
–If too rigid, provide stress on encoder bearings
–Arm must be isolated from motor to avoid motor shaft
currents from damaging encoder bearings
•Ideal for Reliance TEFC V*S Master motors
–Good for all motor enclosures
p 11
Hollow Shaft Encoders
•The lowest cost encoder to install
–No couplings to align or isolate
–No adapter (flower pot)
–No machined fan cover required on TEFC motors
•Flexible torque arm
–Allow encoder to ride freely on shaft extension
–If too rigid, provide stress on encoder bearings
–Arm must be isolated from motor to avoid motor shaft
currents from damaging encoder bearings
•Ideal for Reliance TEFC V*S Master motors
–Good for all motor enclosures
Confidential
p 12
Coupled Encoders
•Highest installation cost.
–Requires a expensive, flexible coupling
–Requires adapter (flower pot) between encoder and motor
–On larger motors, an expensive insulated coupling may be required to
protect Coupled Encoder bearings
–V*S Master TEFC motors requires a special cast iron machined fan
cover
Flexible Coupling Machined Adapter Bracket
p 12
Coupled Encoders
•Highest installation cost.
–Requires a expensive, flexible coupling
–Requires adapter (flower pot) between encoder and motor
–On larger motors, an expensive insulated coupling may be required to
protect Coupled Encoder bearings
–V*S Master TEFC motors requires a special cast iron machined fan
cover
Flexible Coupling Machined Adapter Bracket
Confidential
p 13
Bearingless Encoders
•Less space required
–No couplings to align or isolate
–Can have a thru shaft
–Can be mounted between brake and motor
–Can be mounted on drive or non-drive end
•No bearings to fail!
–Pulse wheel mounted directly on shaft extension
–Encoder housing bolted to motor bracket
–No concerns with motor currents damaging bearings
•Ideal for Reliance RPM-AC and DC motors
–Good to mount between brake and motor bracket on TENV, DPFV
and TEBC-PB enclosures
–Not recommended for V*S Master motors
p 13
Bearingless Encoders
•Less space required
–No couplings to align or isolate
–Can have a thru shaft
–Can be mounted between brake and motor
–Can be mounted on drive or non-drive end
•No bearings to fail!
–Pulse wheel mounted directly on shaft extension
–Encoder housing bolted to motor bracket
–No concerns with motor currents damaging bearings
•Ideal for Reliance RPM-AC and DC motors
–Good to mount between brake and motor bracket on TENV, DPFV
and TEBC-PB enclosures
–Not recommended for V*S Master motors
08/07/24 p 14
Incremental Outputs
Magnetic & Optical
Incremental Outputs
Magnetic & Optical
Confidential
p 15
•Incremental encoders are usually supplied with two channels (A &
B) that are offset by 90 degrees.
•If complements are included (A, B ), the signal is “quadrature”,
providing speed of rotation AND direction of rotation.
Encoder Outputs
A
A
Encoder
B
B
p 15
•Incremental encoders are usually supplied with two channels (A &
B) that are offset by 90 degrees.
•If complements are included (A, B ), the signal is “quadrature”,
providing speed of rotation AND direction of rotation.
Encoder Outputs
A
A
Encoder
B
B
Confidential
p 16
Single Output, Quadrature Signal with Complements
•Signal A leads B in one direction, B leads A in the reverse
direction
•Complement pulses, A and B are used to provide electrical
noise immunity for the signal as it travels through the cable.
A
A
Encoder
B
B
p 16
Single Output, Quadrature Signal with Complements
•Signal A leads B in one direction, B leads A in the reverse
direction
•Complement pulses, A and B are used to provide electrical
noise immunity for the signal as it travels through the cable.
A
A
Encoder
B
B
Confidential
p 17
Marker Pulse
B
A
Z
Marker
Although a “Marker” pulse is standard on some encoders, it is
additional feature (charge) on many encoders. Ask for one, if you
need one.
A marker pulse (reference, index or Z pulse) is a once per
revolution pulse that occurs at precisely the same mechanical
point in a 360º revolution of the encoder shaft.
p 17
Marker Pulse
B
A
Z
Marker
Although a “Marker” pulse is standard on some encoders, it is
additional feature (charge) on many encoders. Ask for one, if you
need one.
A marker pulse (reference, index or Z pulse) is a once per
revolution pulse that occurs at precisely the same mechanical
point in a 360º revolution of the encoder shaft.
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 23
- Slides 17
- Age 482 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
32 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
33 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
31 views
14
Fertility awareness methods for women in the society
Isaiah47
30 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
27 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
29 views