SGMDH-45A2B-YR13 Yaskawa 4500w AC Brushless Frameless Servo Motor

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SGMDH-45A2B-YR13 Yaskawa 4500w AC Brushless Frameless Servo Motor

Name: SGMDH-45A2B-YR13 Yaskawa 4500w AC Brushless Frameless Servo Motor
Brand: Yaskawa
SKU: SGMDH-45A2B-YR13
Price: 1.00 USD
Availability: InStock
Rating: 4.9 (141 reviews)
ISBN: 14033049

Large Image : SGMDH-45A2B-YR13 Yaskawa 4500w AC Brushless Frameless Servo Motor Get Best Price

Product Details:

Place of Origin:	Japan
Brand Name:	Yaskawa
Certification:	CE
Model Number:	SGMDH-45A2B-YR13

Payment & Shipping Terms:

Minimum Order Quantity:	1 pc
Price:	Contact us
Packaging Details:	New in original box
Delivery Time:	2-3 work days
Payment Terms:	T/T, , L/C
Supply Ability:	88

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Detailed Product Description

Package:	Original Package	Color:	Black/Red/White/Grey
Quality:	New And Original	Product Name:	AC Brushless Frameless Servo Motor

Brand:	Yaskawa	Model:	SGMDH-45A2B-YR13
Type:	Motors-AC Servo	Place Of Origin:	Japam
Voltage:	200V	Current:	32.4A
Power:	4500W	InS:	F
High Light:	ac servo motor , electric servo motor

Industrial Servo Motor Yaskawa AC Sigma II Servo Motor 30W 100V 6mm SGMDH-45A2B-YR13

QUICK DETAILS
Manufacturer: Yaskawa
Product number: SGMDH-45A2B-YR13
Description: SGMDH-45A2B-YR13 is an Motors-AC Servo manufactured by Yaskawa
Servomotor Type: SGMDH Sigma II
Rated Output: 4500W
Power Supply: 200V
Output speed:1500 rpm
Torque rating:28.4 Nm
Minimum operating temperature:0 °C
Maximum operating temperature:+40 °C
Encoder Specifications: 13-bit (2048 x 4) Incremental Encoder; Standard
Revision Level: F
Shaft Specifications: Straight shaft with keyway (not available with revision level N)
Accessories: Standard; without brake
Option: None
Type: none

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Where:
V1 = Stator Terminal Voltage
I1 = Stator Current
R1 = Stator Effective Resistance
X1 = Stator Leakage Reactance
Z1 = Stator Impedance (R1 + jX1)
IX = Exciting Current (this is comprised of the core loss component = Ig, and a
magnetizing current = Ib)
E2 = Counter EMF (generated by the air gap flux)
The counter EMF (E2) is equal to the stator terminal voltage less the voltage drop
caused by the stator leakage impedance.
4 E2 = V1 - I1 (Z1)
E2 = V1 - I1 (R1 + j X1 )
In an analysis of an induction motor, the equivalent circuit can be simplified further by
omitting the shunt reaction value, gx. The core losses associated with this value can be
subtracted from the motor Power and Torque when the friction, windage and stray
losses are deducted. The simplified circuit for the stator then becomes:

Let's discuss why one might want to introduce an Integral factor into the gain (A) of the control. The Bode diagram shows A approaching infinity as the frequency approaches zero. Theoretically, it does go to infinity at DC because if one put a small error into an open loop drive/motor combination to cause it to move, it would continue to move forever (the position would get larger and larger). This is why a motor is classified as an integrator itself - it integrates the small position error. If one closes the loop, this has the effect of driving the error to zero since any error will eventually cause motion in the proper direction to bring F into coincidence with C. The system will only come to rest when the error is precisely zero! The theory sounds great, but in actual practice the error does not go to zero. In order to cause the motor to move, the error is amplified and generates a torque in the motor. When friction is present, that torque must be large enough to overcome that friction. The motor stops acting as an integrator at the point where the error is just below the point required to induce sufficient torque to break friction. The system will sit there with that error and torque, but will not move.