HDS04.1-W200N-HS92-01-FW
The HDS04.1-W200N-HS92-01-FW belongs to the HDS Drive Controllers series produced by Bosch Rexroth Indramat. This unit functions as a drive controller within multi-axis DIAX systems, supplying regulated DC bus power and drive logic to servo modules used in industrial automation. By coordinating feedback, power delivery, and safety interlocks, it supports motion platforms that require tightly synchronized torque and position control across several connected axes. Typical roles include gantry, packaging, and material-handling applications where fast response, predictable communication, and integrated fault handling help keep axis behavior stable during continuous production. Because it links command handling with the power stage, the controller supports orderly interaction between the machine control and the connected servo axes.
A continuous output capability of 200 A is the maximum motor current the controller can deliver without derating, which allows it to support large torque servo drives in demanding axis groups. Command and diagnostic data reach the unit over SERCOS fiber-optic communication, so loop timing remains deterministic and communication stays resistant to electrical noise inside drive cabinets. Inside the housing, a built-in air blower directs airflow across the power electronics and moves heat away without external ducting. The controller is part of the DIAX04 family and is Version 1 in this product line. That arrangement supports cabinet layouts where several coordinated axes share supply modules and must respond to commands at the same time.
Within the designation structure, Line 04 indicates the design line used for this controller. That designation corresponds to mechanical dimensions suited to four-slot supply assemblies, which helps the unit fit into larger multi-axis layouts with matching supply and axis modules. In operation, the controller combines power delivery, feedback processing, and protective shutdown behavior so connected motion axes can respond consistently during synchronized running, speed changes, and fault conditions. This behavior is useful in systems where several axes must stop, recover, and return to motion in an orderly sequence.
