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Industrial Servo Motor Yaskawa Electric 4500 W 1500 RPM SERVO MOTOR
SGMDH-45A2B-YR14
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OTHER SUPERIOR PRODUCTS
SIMILAR PRODUCTS
SGMDH | description | manufacturer |
SGMDH-056A2A-YR25 | SGMDH056A2AYR25 SERVO MOTOR | yaskawa |
SGMDH-06A2 | SGMDH06A2 SERVO MOTOR | yaskawa |
SGMDH-06A2A-TR25 | SGMDH06A2ATR25 SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR | SGMDH06A2AYR SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR11 | SGMDH06A2AYR11 SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR12 | SGMDH06A2AYR12 SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR13 | SGMDH06A2AYR13 SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR14 | SGMDH06A2AYR14 SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR24 | SGMDH06A2AYR24 SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR25 | SGMDH06A2AYR25 SERVO MOTOR | yaskawa |
SGMDH-06A2A-YR26 | SGMDH06A2AYR26 2.63NM 550W 4AMP 2000RPM 200V | yaskawa |
SGMDH-12A2 | SGMDH12A2 SERVO MOTOR | yaskawa |
SGMDH-12A2A-YA14 | SGMDH12A2AYA14 SERVO MOTOR | yaskawa |
SGMDH-12A2A-YR | SGMDH12A2AYR SERVO MOTOR | yaskawa |
SGMDH-12A2A-YR12 | SGMDH12A2AYR12 SERVO MOTOR | yaskawa |
SGMDH-12A2A-YR13 | SGMDH12A2AYR13 AC 2000RPM 1150W 200V 7.3AMP 5.49NM | yaskawa |
SGMDH-12A2A-YR14 | SGMDH12A2AYR14 SERVO MOTOR | yaskawa |
SGMDH-12A2A-YR15 | SGMDH12A2AYR15 SERVO MOTOR | yaskawa |
SGMDH-12A2A-YR21 | SGMDH12A2AYR21 SERVO MOTOR | yaskawa |
SGMDH-12A2A-YRA1 | SGMDH12A2AYRA1 SERVO MOTOR | yaskawa |
SGMDH-13A2A-YR23 | SGMDH13A2AYR23 SERVO MOTOR | yaskawa |
SGMDH-20A2A21 | SGMDH20A2A21 SERVO MOTOR | yaskawa |
SGMDH-22A2 | SGMDH22A2 SERVO MOTOR | yaskawa |
SGMDH-22A2A-YR11 | SGMDH22A2AYR11 SIGMA II 2.2KW L/U AXIS SK45X | yaskawa |
SGMDH-22A2A-YR12 | SGMDH22A2AYR12 SERVO MOTOR | yaskawa |
SGMDH-22A2A-YR13 | SGMDH22A2AYR13 SERVO MOTOR | yaskawa |
SGMDH-22A2A-YR13YA | SGMDH22A2AYR13YA SERVO MOTOR | yaskawa |
SGMDH-22A2A-YR14 | SGMDH22A2AYR14 SERVO MOTOR | yaskawa |
SGMDH-22A2A-YR32 | SGMDH22A2AYR32 SERVO MOTOR | yaskawa |
SGMDH-22ACA61 | SGMDH22ACA61 SERVO MOTOR | yaskawa |
SGMDH-30A2A-YR31 | SGMDH30A2AYR31 SERVO MOTOR | yaskawa |
SGMDH-30A2A-YR32 | SGMDH30A2AYR32 SERVO MOTOR | yaskawa |
SGMDH-32A2 | SGMDH32A2 SERVO MOTOR | yaskawa |
SGMDH-32A2A | SGMDH32A2A SERVO MOTOR | yaskawa |
SGMDH-32A2A-YA14 | SGMDH32A2AYA14 SERVO MOTOR | yaskawa |
SGMDH-32A2A-YR11 | SGMDH32A2AYR11 SERVO MOTOR | yaskawa |
SGMDH-32A2A-YR12 | SGMDH32A2AYR12 SERVO MOTOR | yaskawa |
SGMDH-32A2A-YR13 | SGMDH32A2AYR13 AC 3.2KW SIGMA 2 S-AXIS | yaskawa |
SGMDH-32A2A-YR14 | SGMDH32A2AYR14 SERVO MOTOR | yaskawa |
SGMDH-32A2A-YR51 | SGMDH32A2AYR51 SERVO MOTOR | yaskawa |
SGMDH-32A2A-YRA1 | SGMDH32A2AYRA1 SERVO MOTOR | yaskawa |
SGMDH-32ACA-MK11 | SGMDH32ACAMK11 SERVO MOTOR | yaskawa |
SGMDH-32P5A | SGMDH32P5A SERVO MOTOR | yaskawa |
SGMDH-40A2 | SGMDH40A2 SERVO MOTOR | yaskawa |
SGMDH-40A2A | SGMDH40A2A SERVO MOTOR | yaskawa |
SGMDH-40ACA21 | SGMDH40ACA21 SERVO MOTOR | yaskawa |
SGMDH-44A2A-YR14 | SGMDH44A2AYR14 SERVO MOTOR | yaskawa |
SGMDH-44A2A-YR15 | SGMDH44A2AYR15 SERVO MOTOR | yaskawa |
SGMDH-45A2A6C | SGMDH45A2A6C SERVO MOTOR | yaskawa |
SGMDH-45A2B61 | SGMDH45A2B61 SERVO MOTOR | yaskawa |
SGMDH-45A2BYR | SGMDH45A2BYR SERVO MOTOR | yaskawa |
SGMDH-45A2B-YR13 | SGMDH45A2BYR13 SERVO MOTOR | yaskawa |
SGMDH-45A2BYR14 | SGMDH45A2BYR14 SERVO MOTOR | yaskawa |
SGMDH-45A2B-YR14 | SGMDH45A2BYR14 SERVO MOTOR | yaskawa |
SGMDH-45A2BYR15 | SGMDH45A2BYR15 SERVO MOTOR | yaskawa |
SGMDH-45A2B-YR15 | SGMDH45A2BYR15 SERVO MOTOR | yaskawa |
SGMDH-6A2A-YR13 | SGMDH6A2AYR13 SERVO MOTOR | yaskawa |
SGMDH-6A2A-YR25 | SGMDH6A2AYR25 SERVO MOTOR | yaskawa |
SGMDH-A2 | SGMDHA2 SERVO MOTOR | yaskawa |
SGMDH-A2A | SGMDHA2A SERVO MOTOR | yaskawa |
• By closing the velocity loop as well as the position loop in the
computer, a single feedback device can be used for both. The
computer per axis approach is beneficial if very high update rates
are chosen for the velocity loop. With multiple axes, the burden on
a central computer may too great with high update velocity loops.
• If much coordinated motion is anticipated, a central computer
would have direct access to each axis. With the computer per axis
approach, the computer-to-computer communication links result in
delays that limit close coordination. The velocity loops may remain
analog with the central computer approach to ease this.
A Bode diagram, like the one shown below, helps to quantify how
well the output, or feedback (F), follows the command (C) by
showing the relationship between A and the frequency of excitation.
The frequency is normally expressed in radians/sec.(ω) rather than
cycles per second (f). Since ω = 2πf ≈ 6.28 f, it is easy to
convert from one to the other. Also, 1/ω, in seconds, is the time
constant of a low pass filter with a bandwidth of f. Once we know
the bandwidth (ω) of a servo, we know the time constant of the
equivalent filter (1/ω) and can thus predict its response to a step
input.
What are stepper motors good for?
Positioning – Since steppers move in precise repeatable steps, they
excel in applications requiring precise
positioning such as 3D printers, CNC, Camera platforms and X,Y
Plotters. Some disk drives also use stepper motors to position the
read/write head.
Speed Control – Precise increments of movement also allow for
excellent control of rotational speed for
process automation and robotics.
Low Speed Torque - Normal DC motors don't have very much torque at
low speeds. A Stepper motor has
maximum torque at low speeds, so they are a good choice for
applications requiring low speed with high
precision.
Many users of motion control have heard vendors try to explain
certain servo features by using Bode diagrams. A basic
understanding of them is necessary in dealing with motion. To begin
with, the proper pronunciation is "Bo-dee". Just think of Bo Derek
(which isn't hard to do). You'll find other similarities between
the two (who am I kidding?) like the number 10, as will be seen.