Industrial Automation Suppliers: Look for websites of industrial automation suppliers who might carry GE Multilin products. These suppliers might have technical specifications or manuals available for download, although they might not have the specific ML1600HIXXA4A6H variant.
Additional Notes:
The information provided here is based on general conventions used in GE Multilin product naming and might not be entirely accurate for the specific ML1600HIXXA4A6H model. Refer to GE Multilin’s official resources for the most accurate details.
If you have any context about where you encountered this model number (e.g., a specific application or industry), it might help narrow down the type of protective relay it is.
GE Multilin Website: Search the GE Multilin website for product catalogs, datasheets, or manuals. You can try searching for “ML1600” or browsing their product categories for protective relays. Their product information section can be found here:
Contact GE Multilin: If the online search is unsuccessful, you can try contacting GE Multilin directly through their website or regional offices. Their contact information can likely be found on their website. Provide them with the model number ML1600HIXXA4A6H for assistance.
Industrial Automation Suppliers: Look for websites of industrial automation suppliers who might carry GE Multilin products. These suppliers might have technical specifications or manuals available for download, although they might not have the specific ML1600HIXXA4A6H variant.
Additional Notes:
The information provided here is based on general conventions used in GE Multilin product naming and might not be entirely accurate for the specific ML1600HIXXA4A6H model. Refer to GE Multilin’s official resources for the most accurate details.
If you have any context about where you encountered this model number (e.g., a specific application or industry), it might help narrow down the type of protective relay it is.
While the specific application depends on the overall turbine control system design, the 5466-316 could be involved in various control functions within a turbine system, such as:
Speed Control: Processing sensor signals to monitor turbine speed and sending control signals to adjust turbine operation for maintaining desired speed.
Temperature Control: Monitoring exhaust gas temperatures or other critical temperature points within the turbine and adjusting control parameters to prevent overheating.
Vibration Monitoring: Interfacing with vibration sensors to detect potential issues and enabling preventative maintenance actions.
Fuel Control: Processing signals related to fuel flow or pressure to regulate fuel delivery for efficient and safe combustion.
Speed Control: Processing sensor signals to monitor turbine speed and sending control signals to adjust turbine operation for maintaining desired speed.
Temperature Control: Monitoring exhaust gas temperatures or other critical temperature points within the turbine and adjusting control parameters to prevent overheating.
Vibration Monitoring: Interfacing with vibration sensors to detect potential issues and enabling preventative maintenance actions.
Fuel Control: Processing signals related to fuel flow or pressure to regulate fuel delivery for efficient and safe combustion.
Additional Notes:
For precise details on functionalities and specifications, consulting the Woodward datasheet for the 5466-316 is recommended. You might be able to find it through a web search using “Woodward 5466-316 datasheet”.
Since this is a component within a complex turbine control system, installation, configuration, and maintenance should only be performed by qualified technicians with expertise in turbine control systems and industrial automation practices.
I hope this information is helpful! Let me know if you have any further questions about the Woodward 5466-316, turbine control systems, or industrial automation.
The specific functionalities, communication protocols, and compatibility details of the DS200LDCCH1AGA might vary depending on the exact model variant and configuration. Consulting the GE datasheet is essential for obtaining precise details.
Since this is a component within a complex gas turbine control system, installation, configuration, and maintenance should only be performed by qualified technicians with expertise in turbine control systems, industrial automation, and GE Mark V technology.
I hope this information is helpful! Let me know if you have any further questions about the GE DS200LDCCH1AGA, turbine control systems, or industrial automation.
While the MVME 162-01 is an older product, you might find additional details and specifications from the following sources:
Online Marketplaces: Websites like eBay or specialized electronics marketplaces might have listings for this board, which could include detailed descriptions and photos.
Industrial Automation Suppliers: Some industrial automation suppliers might still have information or support for older VMEbus equipment.
VMEbus User Groups or Forums: Online communities focused on VMEbus technology could be a valuable resource for information and troubleshooting.
Contacting Motorola (or its successor, ON Semiconductor): They might have archived documentation or support for older products.
Searching online forums or communities: There might be specialized forums or communities dedicated to VMEbus or industrial automation where someone might have experience with this specific model.
Checking used equipment marketplaces: Sometimes, listings for old equipment include detailed descriptions or specifications.
If you can provide additional details about the board’s function or any other information you have, I might be able to assist you further.
Would you like to try providing more details about the board or its application?
Please let me know if you have any other questions.
Limited Functionality: The 10 Mbps Ethernet speed is significantly slower than modern Ethernet standards.
Driver Compatibility: Driver availability for newer operating systems might be an issue.
Legacy Use: The MVME-376 is likely more suitable for maintaining legacy VMEbus systems than for new projects.
If you’re looking for an Ethernet connectivity solution for a modern system, using a PCI Express network adapter or a more recent Ethernet standard would be a better choice.
Industrial Automation Systems: Enabling communication between VMEbus-based controllers and Ethernet devices in industrial settings.
Embedded Systems: Providing Ethernet connectivity for data transfer or remote access in embedded VMEbus systems.
Availability and Use Today:
The MVME-376 is likely an older product and might be difficult to find new.
VMEbus itself is a legacy standard. While some legacy systems might still be in operation, newer industrial systems typically use modern communication standards like PCI Express.
Machine Tools: Precise positioning and control of cutting tools in CNC machines, lathes, milling machines, etc.
Robotics: Joint actuation in robots for various industrial tasks like assembly, welding, material handling, and pick-and-place operations requiring medium to high torque.
Indexing Applications: Precise positioning of components or materials in assembly lines, packaging machines, and other industrial processes.
Material Handling Systems: Controlled movement of materials in conveyor systems, sorting machines, and automated guided vehicles (AGVs), particularly for applications involving lifting or moving heavier loads.
Low Inertia: Enables fast acceleration and deceleration for applications needing high responsiveness and precise positioning, especially with frequent starts and stops.
Permanent Magnet Design: Offers several advantages over DC brushed motors, including:
Higher efficiency and lower maintenance due to the absence of brushes.
Smoother operation and reduced torque ripple for improved control.
Multi-Turn Absolute Encoder (Possible): May integrate a high-resolution absolute encoder that provides the motor’s exact position information at any time. This eliminates the need for homing procedures during startup.
SpeedTEC DIN Connector: Offers a quick-connect and easy-to-assemble power connection.
Keyed Shaft: Provides a secure connection between the motor shaft and the driven load (e.g., gearboxes, couplings).
24V DC Brake (Possible): Some variations might include a built-in DC brake that helps hold the motor shaft stationary when power is removed, improving safety and machine control. Availability depends on the specific variant within the MPL-A320P-MJ74AA series.
Rockwell Automation Website: The Rockwell Automation website, which owns Allen-Bradley, should have a product page for the MPL-A320P-MJ24AA with detailed specifications, manuals, and downloads:
Industrial Automation Distributors: Look for websites of distributors who sell Allen-Bradley products. They might have additional resources or downloadable documents for the specific motor model.
Additional Notes:
The MPL-A320P-MJ24AA is likely part of a broader series of MPL motors offered by Allen-Bradley with variations in voltage, speed, brake configurations, and potentially inertia values.
When selecting a servo motor for your application, consider factors like required speed, torque, positioning accuracy, inertia (for acceleration needs), and environmental conditions. Consulting the Allen-Bradley product information or an automation specialist can help ensure you choose the most suitable model for your needs.
Low Inertia: Enables rapid acceleration and deceleration for applications needing high responsiveness and precise positioning.
Permanent Magnet Design: Offers several advantages over DC brushed motors, including:
Higher efficiency and lower maintenance due to the absence of brushes.
Smoother operation and reduced torque ripple for improved control.
Single-turn Absolute Encoder (Likely): Integrates a high-resolution encoder that provides the motor’s absolute position information at any given time. This eliminates the need for homing procedures during startup.
24V DC Brake (Possible): May include a built-in DC brake that helps hold the motor shaft stationary when power is removed, improving safety and machine control.
Circular DIN Connector: Offers a quick-connect and easy-to-assemble power connection.
Keyed Shaft: Provides a secure connection between the motor shaft and the driven load (e.g., gearboxes, couplings).
