Westinghouse WDPF Modules: 3A99164G50,

Technical Dossier

Product Details And Specifications

Westinghouse WDPF Series: Comprehensive Module Range and Technical Overview

The Westinghouse WDPF (Westinghouse Distributed Processing Family) is one of the most widely deployed legacy DCS platforms in global heavy industry. Installed across coal-fired and nuclear power stations, petroleum refineries, chemical processing plants, and pulp & paper mills from the 1980s through the early 2000s, WDPF systems remain operational in facilities where the cost and risk of full platform migration are prohibitive. The installed base spans North America, Europe, and Asia-Pacific, with many sites running continuous processes that cannot tolerate the downtime associated with a control system overhaul.

The 3A99164G50 is a control board within this architecture, designed to handle supervisory control and data acquisition functions within the WDPF backplane environment. Its continued operation is directly tied to the stability of the broader WDPF node infrastructure.

The Evolution of WDPF Architecture

The WDPF platform was introduced by Westinghouse Electric Corporation in the early 1980s as a response to the industry's shift from centralized analog control panels to distributed digital control. The architecture was built around a proprietary data highway — the WDPF Data Highway — which used a token-passing protocol to coordinate communication between processing nodes.

Over its lifecycle, the WDPF platform evolved through several hardware generations:

• WDPF I (early 1980s): Initial release. Single-board processor nodes with limited I/O density. Relied on parallel backplane communication.
• WDPF II (late 1980s): Expanded I/O capacity, introduction of redundant data highway configurations, and improved power supply modules. This generation saw widespread adoption in nuclear and fossil fuel power generation.
• WDPF II+ / Enhanced (1990s): Incremental improvements to processor speed and memory. Introduction of Ethernet gateway modules for SCADA integration. Many 3A99xxx-series boards originate from this generation.
• Ovation Transition (2000s): Emerson Electric acquired the Westinghouse Process Control division and rebranded the successor platform as Ovation. WDPF hardware was officially discontinued, though Emerson continued to offer limited support. Sites that did not migrate to Ovation entered a self-managed lifecycle extension phase.

Today, WDPF hardware is fully discontinued. Emerson no longer manufactures or provides factory support for WDPF modules. Facilities still operating WDPF systems depend entirely on third-party spare parts suppliers and refurbished inventory to maintain uptime.

WDPF Full Catalog & Functionalities (SKU List)

The following represents a cross-section of commonly referenced WDPF module part numbers, organized by functional category. All models listed are genuine Westinghouse WDPF hardware.

Processor & Controller Modules

• 3A99164G50: WDPF control board; supervisory processing and backplane coordination module.
• 3A99164G01: WDPF processor card, early-generation node controller for WDPF I architecture.
• 3A99164G02: Processor module variant with expanded onboard RAM for WDPF II nodes.
• 3A99164G10: Enhanced controller board with dual-port memory interface for redundant configurations.
• 3A99164G20: Control processor with integrated diagnostics output for maintenance terminals.

Analog Input (AI) Modules

• 3A99168G01: 16-channel analog input module, 4–20 mA, for process variable acquisition.
• 3A99168G02: Analog input card with high-resolution A/D conversion, used in precision measurement loops.
• 3A99170G01: Thermocouple input module, multi-type (J, K, T, E), cold junction compensated.
• 3A99170G02: RTD input module, 3-wire Pt100 configuration, for temperature-critical process loops.

Digital Input (DI) / Digital Output (DO) Modules

• 3A99172G01: 32-channel digital input module, 24 VDC, for discrete field device status monitoring.
• 3A99172G02: Digital input card with optical isolation, for high-noise industrial environments.
• 3A99174G01: 16-channel digital output module, relay contact type, for actuator and valve control.
• 3A99174G02: Solid-state digital output module, 24 VDC sourcing, for high-cycle switching applications.

Communication & Network Modules

• 3A99180G01: WDPF Data Highway interface card; primary node communication adapter.
• 3A99180G02: Redundant data highway module for fault-tolerant node configurations.
• 3A99182G01: Ethernet gateway module for SCADA and historian integration (WDPF II+ generation).

Power Supply Modules

• 3A99190G01: WDPF backplane power supply, 24 VDC regulated output, single-rail configuration.
• 3A99190G02: Redundant power supply module for critical node applications.

Sourcing Hard-to-Find & Obsolete WDPF Parts

The discontinuation of the WDPF platform by Emerson created a structural supply gap that the OEM channel cannot fill. Facilities operating WDPF systems face a binary choice: migrate to a modern DCS at capital costs that routinely exceed USD 5–15 million per unit, or maintain the existing system through third-party spare parts procurement.

DriveKNMS maintains a dedicated inventory of WDPF hardware, including processor boards, I/O modules, communication cards, and power supplies. Our sourcing network covers decommissioned plant equipment, controlled surplus from system integrators, and tested refurbished units from verified industrial sources.

For facilities managing long-term WDPF lifecycle extension, we recommend a structured spare parts strategy:

• Identify single points of failure within the WDPF node architecture — typically processor boards and data highway interface cards.
• Maintain a minimum of two spare units per critical module type, stored in anti-static, climate-controlled conditions.
• Establish a scheduled inspection cycle for electrolytic capacitor degradation on boards older than 15 years.
• Document firmware versions across all nodes to ensure replacement boards are compatible without requiring re-engineering.

This approach has enabled facilities to extend WDPF system operational life by 8–12 years beyond the OEM end-of-support date, deferring capital expenditure while maintaining process safety and regulatory compliance.

Quality Control for the WDPF Range

WDPF modules present specific reliability challenges due to component age and the complexity of the backplane bus communication protocol. DriveKNMS applies a structured inspection and testing process to all WDPF hardware prior to shipment:

• Visual and mechanical inspection: Board-level examination for physical damage, corrosion on edge connectors, solder joint integrity, and component displacement.
• Electrolytic capacitor assessment: Capacitors on boards manufactured prior to 2000 are individually tested for ESR (Equivalent Series Resistance) and capacitance drift. Units showing degradation beyond tolerance are flagged for recapping before release.
• Firmware version verification: Where applicable, onboard firmware is read and documented. Boards are matched to compatible firmware revisions to prevent node communication failures post-installation.
• Backplane connector integrity test: Edge connectors are cleaned and tested for contact resistance. Oxidized or worn connectors are treated or the unit is rejected.
• Functional bench test: Modules are powered and tested in a WDPF-compatible test environment to verify correct initialization, communication response, and I/O channel operation.

Units that do not pass all five stages are not released for sale. Test records are retained and available upon request for critical applications.

For WDPF spare parts inquiries, availability checks, or bulk procurement:

• Email: sale@driveknms.com
• WhatsApp: +86 18359293191
• Web: driveknms.com

© 2026 DriveKNMS. All trademarks belong to their respective owners. Specifications are for reference only and subject to change without notice. Verify all parameters against official documentation before installation.