Product Description
The MSK101D-0450-NN-S2-AG2-RNNN is an industrial synchronous motor designed by Rexroth Indramat to operate as a reliable source of kinetic energy for industrial production and processing devices. This industrial motor is manufactured under ideal industrial conditions; it features a compact design and a very durable housing unit that provides it with protection according to the IP65 protection class. Under normal operating conditions, the MSK101D-0450-NN-S2-AG2-RNNN industrial motor can maintain operational efficiency of about 95 percent for more than five years without the risk of sudden machine breakdown or dangerous motor movements. The high degree of protection provided to this motor by its housing unit makes it possible for the industrial operator to apply the motor in industrial conditions considered too harsh for convectional industrial machines.
The MSK101D-0450-NN-S2-AG2-RNNN industrial motor regulates its internal operational temperature via natural convection; although this temperature regulation process is often sufficient for the regular operation of the motor, additional air blowers can be attached to the motor to aid the temperature regulation process via surface cooling. This industrial motor also features a plain steel output shaft through which it supplies industrial machines with the kinetic energy required for operation; these output shafts are fitted with special sealing rings to prevent the lubricating fluid in the motor from escaping.
The MSK101D-0450-NN-S2-AG2-RNNN industrial motor is designed with an internal single turn encoder which aids the accurate operation of the motor by initiating a motor feedback mechanism. The internal encoder converts the physical operation of the motor into digital signals and then sends these signals to the drive controller through the motor feedback cable. The drive controller completes the motor feedback process by comparing the signals it receives from the single turn encoder to predetermined configuration parameters; it then corrects for any deviation.