Industrial 200V Yaskawa Made In JapanS ervo Motor 1500rpm 32.4a 200v-ac 4500w 28.4nm SGMDH-45A2B-YR12

Yasakawa Motor, Driver SG-	Mitsubishi Motor HC-,HA-
Westinghouse Modules 1C-,5X-	Emerson VE-,KJ-
Honeywell TC-,TK-	GE Modules IC -
Fanuc motor A0-	Yokogawa transmitter EJA-

 

 

 

 

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

 

 

 

The excitation sequences for the above drive modes are summarized in Table 1.
In Microstepping Drive the currents in the windings are continuously varying to be able to break up one full step into many smaller discrete steps. More information on microstepping can be
found in the microstepping chapter. Torque vs, Angle Characteristics

The torque vs angle characteristics of a stepper motor are the relationship between the displacement of the rotor and the torque which applied to the  rotor shaft when the stepper motor is energized at its rated voltage. An ideal stepper motor has a sinusoidal torque vs displacement characteristic as shown in figure 8.

Positions A and C represent stable equilibrium points when no external force or load is applied to the rotor
shaft. When you apply an external force Ta to the motor shaft you in essence create an angular displacement, Θa

. This angular displacement, Θa , is referred to as a lead or lag angle depending on wether the motor is actively accelerating or decelerating. When the rotor stops with an applied load it will come to rest at the position defined by this displacement angle. The motor develops a torque, Ta , in opposition to the applied external force in order to balance the load. As the load is increased the displacement angle also increases until it reaches the maximum holding torque, Th, of the motor. Once Th is exceeded the motor enters an unstable region. In this region a torque is the opposite direction is created and the rotor jumps over the unstable point to the next stable point.

 

 

 

MOTOR SLIP
The rotor in an induction motor can not turn at the synchronous speed. In order to
induce an EMF in the rotor, the rotor must move slower than the SS. If the rotor were to
somehow turn at SS, the EMF could not be induced in the rotor and therefore the rotor
would stop. However, if the rotor stopped or even if it slowed significantly, an EMF
would once again be induced in the rotor bars and it would begin rotating at a speed less
than the SS.
The relationship between the rotor speed and the SS is called the Slip. Typically, the
Slip is expressed as a percentage of the SS. The equation for the motor Slip is:
2 % S = (SS – RS) X100
SS
Where:
%S = Percent Slip
SS = Synchronous Speed (RPM)
RS = Rotor Speed (RPM)