MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN
Wake Industrial LLC is not an authorized distributor of this product.
MPN: R911396566
No Tariffs On US Orders- Straightforward Pricing: No Rush Fees, No Credit Card Fees
The MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN is a synchronous servo motor with a motor size of MS2N05 and a rated power of 0.5 kW. Created by Bosch Rexroth Indramat as part of their MS2N Synchronous Servo Motors series, it features natural cooling and an IP65 protection class. Its 24-bit multi-turn absolute encoder ensures precision.
To contact sales for pricing and lead time:
Payment Methods
Shipping Methods
Our Credentials
Product Description:
The MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN Servo Motor features dual rotatable M17 connectors for flexible wiring, ideal for compact installations and its windings are optimized for 4500 RPM which delivers responsive performance in dynamic applications. Created by Bosch it has a winding inductance of 11.18 mH which helps to ensure smooth current control and supports precise torque and speed regulation.
The MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN motor rotor is engineered with a minimized moment of inertia which contributes to tighter control, reduced cycle times and improved performance in dynamic operating environments. It utilizes the passive thermal dissipation approach by releasing heat through natural convection and surface radiation which is especially advantageous in compact or resource-constrained installations, where active cooling is impractical. It follows the B5 flange mounting specification also referred to as IM3001 and it is equipped with an integrated PT1000 temperature sensor which is a high-accuracy platinum resistance element useful for real-time thermal monitoring. It takes 18.5 minutes as a whole to achieve roughly 63% of its total temperature rise following a thermal load which can provide a buffer against short-duration thermal spikes. When the winding temperature increases by 100°C, it requires 7.2 amperes of current while remaining stationary to produce holding torque which is crucial for evaluating electrical demand during non-rotational operation.
With a thermal load resulting in a 100°C increase in winding temperature this MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN Servo Motor can continuously output 1.74 kilowatts of mechanical power which defines its long-term operating capability. The thermal response rate of the motor’s internal windings is very high and it takes 45.8 seconds only to attain approximately 63% of their total temperature rise within that period following a sudden thermal load. It comes with deep groove ball bearings which are reliable and widely used in common servo tasks because of its durability, lower cost and low friction operation.
Frequently Asked Questions about MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN:
Q: Why is low rotor inertia important in the MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN servo motor?
A: Low rotor inertia enables faster acceleration and deceleration, enhancing system responsiveness. It is especially beneficial in high-speed positioning and dynamic load changes.
Q: How does the PT1000 sensor contribute to motor protection?
A: The PT1000 sensor provides precise thermal monitoring, allowing real-time feedback to prevent overheating. This helps extend motor lifespan under continuous or varying load conditions.
Q: Why are dual M17 connectors rotatable in the MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN motor?
A: Rotatable connectors improve cable management in space-limited installations. They also simplify servicing and reduce cable stress during motion or reinstallation.
Q: What role does the 11.18 mH winding inductance play in motor performance?
A: Higher inductance helps stabilize current flow, improving control during dynamic speed or torque changes. It also reduces electromagnetic interference in sensitive environments.
Q: Why is a 100°C winding temperature used as a reference in the MS2N05-D0BRN-BSDH0-NNNNN-GM100N1005BN-NN?
A: A 100°C rise standardizes motor ratings for thermal capacity. It ensures safe operation within the thermal limits of insulation and winding materials.
