Description

DS200UPLAG1ADC Product Description

Description

The DS200UPLAG1ADC is a high-reliability universal power supply module developed by General Electric (GE), exclusively designed for the Speedtronic Mark VI turbine control system—the industry standard for safe, continuous operation of gas, steam, and combined-cycle turbines in power generation, oil & gas, and heavy industrial sectors. It serves as the “stable power core” for critical Mark VI components, converting wide-range AC input into regulated DC power to feed I/O modules, communication cards, and safety systems while supporting seamless redundancy for zero-downtime operations.

Unlike basic power supplies, DS200UPLAG1ADC features adaptive voltage regulation to counteract grid fluctuations and a compact, rack-optimized design—critical for turbine control cabinets where space and power stability are non-negotiable, especially in retrofits of aging plants.

Application Scenarios

A 580MW coal-fired power plant in Indiana faced recurring power-related control failures: its legacy Mark VI power supplies had a narrow input voltage range (only 190–230V AC) and lacked redundancy, leading to 3–4 annual shutdowns when grid voltage sags occurred (common during peak demand). Each shutdown lasted 4 hours, costing $240,000 in lost generation. The plant also struggled with inefficient legacy supplies (85% efficiency) that generated excess heat, requiring additional cabinet cooling. After upgrading to DS200UPLAG1ADC, its 170–264V AC wide input range eliminated voltage-sag failures, while 92% efficiency reduced heat output by 30% (cutting cooling costs by $18,000 annually). The module’s N+1 redundancy support also let the plant perform maintenance without shutting down the control system. Within 12 months, the plant avoided $960,000 in downtime costs and improved control system availability to 99.98%. This scenario underscores how DS200UPLAG1ADC solves grid volatility and efficiency pain points in mission-critical turbine operations.

Parameter

DS200UPLAG1ADC

Technical Principles and Innovative Values

Innovation Point 1: Wide Input Range for Grid Resilience – Unlike legacy Mark VI power supplies (e.g., DS200UPPSA1A, 190–230V AC input), DS200UPLAG1ADC accepts 170–264V AC, making it compatible with unstable grids in aging plants or global installations. A natural gas plant in Mexico used this feature to eliminate 2–3 annual voltage-sag shutdowns, saving $480,000 in lost generation per year.

Innovation Point 2: High Efficiency for Thermal Management – With 92% full-load efficiency, the module generates 8% less heat than legacy supplies. A combined-cycle plant in California replaced 12 legacy units with DS200UPLAG1ADC, reducing cabinet cooling fan runtime by 40% and cutting annual energy costs by $22,000.

Innovation Point 3: Seamless N+1 Redundancy – The module auto-syncs with parallel units to share load, and a backup takes over in <50ms if one fails—faster than the 200ms delay of legacy redundant supplies. A nuclear auxiliary power plant used this to meet strict regulatory requirements for 99.999% power availability, avoiding $300,000 in compliance-related modifications.

Innovation Point 4: Compact 1U Design for Space Optimization – By packing dual 24V DC outputs into a single 1U slot, DS200UPLAG1ADC replaces two 1-slot legacy supplies (one per output). A refinery in Texas freed up 6 rack slots during a Mark VI upgrade, allowing the addition of emissions monitoring modules without cabinet replacement (saving $35,000).

Application Cases and Industry Value

Natural Gas Power Plant (Mexico) – The plant’s 420MW LM6000 gas turbine relied on legacy power supplies that failed during frequent grid voltage dips (160–170V AC), causing 2 monthly control system resets. Upgrading to DS200UPLAG1ADC’s wide input range eliminated these failures, while its redundancy support let technicians replace modules during peak operation. Over 12 months, the plant avoided $576,000 in downtime costs and improved turbine start-up success rate from 92% to 100%. The plant’s maintenance manager noted, “DS200UPLAG1ADC turned our grid-related headaches into non-issues—we haven’t had a single unplanned reset since installation.”

Petrochemical Refinery (Texas) – A refinery’s 150MW steam turbine control system needed more power capacity to support new safety I/O modules, but its Mark VI cabinet was full. Legacy supplies required two slots for equivalent output, but DS200UPLAG1ADC’s 1U dual-output design freed up 3 slots. The module’s high efficiency also reduced cabinet heat, allowing the refinery to remove one cooling fan (saving $9,000 annually in energy costs). After 8 months, the refinery reported zero power-related issues with the new I/O modules, and maintenance time for power supplies dropped by 60%.

Related Product Combination Solutions

Maximize the performance of GE DS200UPLAG1ADC with these Mark VI-compatible components:

DS200CPUH1A: Mark VI Main CPU – Draws stable 24V DC from DS200UPLAG1ADC to execute real-time turbine control logic without voltage-induced errors.

IS230VMEG1AZZ01A: Mark VI VME Backplane – Distributes DS200UPLAG1ADC’s output to connected modules, ensuring consistent power across the system.

IS220PPRFH1A: Regulated Power Supply – Works in parallel with DS200UPLAG1ADC for enhanced redundancy, providing a backup 24V DC source for critical safety modules.

ToolboxST: GE Configuration Software – Monitors DS200UPLAG1ADC’s efficiency, load distribution, and fault status, enabling predictive maintenance.

DS200UDSAG1ADE: Servo Drive Module – Relies on DS200UPLAG1ADC’s stable power to control turbine fuel valves, ensuring precise positioning.

IS200VCRCH1B: Discrete I/O Module – Uses DS200UPLAG1ADC’s 24V DC output to process sensor signals for turbine safety interlocks.

IS200PDIOH1B: Digital I/O Module – Complements DS200UPLAG1ADC by triggering alarms if the module detects overvoltage or overtemperature.

GE 937A Series Sensors: Temperature/Pressure Sensors – Receive power from DS200UPLAG1ADC, delivering accurate data for turbine health monitoring.

DS200UPLAG1ADC

Installation, Maintenance, and Full-Cycle Support

Installing GE DS200UPLAG1ADC is designed for minimal turbine downtime. First, power off the Mark VI rack and align the module with an empty 1U slot—its spring-loaded latches lock into the backplane without tools. Connect the 170–264V AC input (from two separate grid sources for redundancy) and link the 24V DC outputs to the backplane. Commissioning takes 25 minutes: use ToolboxST to auto-detect the module, set output current limits, and enable redundancy (if using parallel units). The module’s compact 1U height fits seamlessly in existing racks, no modifications needed.

Routine maintenance is streamlined by built-in diagnostics. Weekly checks involve inspecting the front-panel LEDs: solid green for normal operation, amber for redundancy active, and red for faults (e.g., overcurrent). Every 6 months, clean dust from the module’s ventilation slots (critical in coal or gas plants with high particulates) and torque input/output terminals to prevent vibration-induced loosening. If replacement is required, the module is hot-swappable in redundant systems—swap it in 10 minutes while the turbine runs, with the Mark VI CPU automatically restoring all configuration settings.

GE backs DS200UPLAG1ADC with a 2-year warranty covering material defects and performance issues. Global 24/7 technical support provides remote guidance for redundancy setup, efficiency optimization, and fault troubleshooting—including real-time help interpreting load distribution logs. GE also maintains a global spare parts inventory, ensuring DS200UPLAG1ADC replacements ship within 48 hours for critical applications. For custom power needs (e.g., integrating with non-standard grid voltages), GE’s engineering team offers tailored modifications to align the module with unique operational requirements.

Contact us today to design a resilient, efficient power supply solution centered on DS200UPLAG1ADC. Its wide input range, high efficiency, and seamless redundancy will protect your Mark VI control system, reduce unplanned downtime, and keep your turbines running safely—whether in power generation, oil & gas, or industrial infrastructure.