himg-1
Power Systems > Data Centers

Power Conversion Simplified

800 VDC LVDC custom solutioned power systems designed for the future of energy throughput

Speak to an Expert
logo-odca_white 1 opencomputeproject_logo_white 1 current-OS_logo_white 1
Traditional Power Architecture Wastes Energy, Money, and Time.
Spoc 800 VDC
Power Architecture Built for AI
AI workloads expose the limits of AC systems—unstable loads, grid bottlenecks, and unprecedented power density.


Legacy power paths were never built for synchronized GPU domains, multi-megawatt clusters, or millisecond load swings. These are the cracks that show first.
Rectangle 38 (1)
LOAD STABILITY
AI workloads spike instantly. AC can’t keep up.
800 VDC delivers
  • <5 ms solid-state protection
  • Single-stage rectification
  • Integrated energy storage
  • Lower losses for smoother GPU behavior
Stability for your racks. Confidence for your team.
POWER AVAILABILITY
Grid constraints slow deployment and threaten uptime.
800 VDC delivers
  • Grid-forming & ride-through support
  • Utilities and hybrid energy integration
  • Reduced component count
  • Predictable load behavior for interconnect approval
Always on. Always resilient.
POWER DENSITY
GPU racks now exceed 350–600 kW. AC can’t scale.
800 VDC delivers
  • Smaller, lighter cabling
  • Higher rack density with fewer feeds
  • A ready path to 800–1500 VDC
More power. Less complexity. Built for AI.
Simplicity. Efficiency.
Resiliency. At Scale.
Traditional AC Architecture 
VS. SPOC DC GRID
SPOC-GRID-800VDC-4
Traditional AC Power Architecture: Complex. Inefficient. Hard to Scale.
The problems:
  • Multiple conversion stages → 6–10% energy loss
  • More hardware → larger footprint & higher cost
  • More components → more failure points
  • Slower deployment & harder maintenance
  • Struggles to support 350–600 kW AI racks
Result: A heavy, fragile power path not built for AI-driven loads.
SPOC 800 VDC Grid:
Simple. Efficient. Resilient.
The advantages:
  • Single-stage rectification → higher efficiency (>95%)
  • Fewer components → lower cost & smaller footprint
  • <5 ms solid-state protection for safer operation
  • Installs faster with lighter cabling
  • Scales cleanly to 600 kW+ AI racks and future 1500 VDC

Result: A lean, stable, scalable architecture built for AI.
Connect with our data center experts
Let’s Engineer Your 800 VDC Power Strategy Together.
AI-era power demands are rewriting the rules. Our engineers bring deep expertise in load stability, high-density GPU racks, DC grid design, and solid-state protection—all essential for building resilient 800 VDC systems.

Tell us about your project, and we’ll help you design a power architecture that’s efficient, scalable, and ready for AI.
Clayton Gibbons, Head of Power Systems

Clayton leads SPOC’s development of 800 VDC power systems, specializing in DC grid design, high-efficiency rectification, fast solid-state protection, and AI-ready power architectures for hyperscale facilities.
clayton_cutout_bw_web
LVDC / 800 VDC POWER SYSTEMS DESIGNED FOR NEXT-GEN DATA CENTERS
Our DC-based architectures deliver higher efficiency and dramatically simpler deployment for AI and high-density compute environments. Built on decades of inverter, DC grid, and energy storage expertise, our systems reduce complexity while improving uptime at scale.

We’ve engineered and deployed LVDC and hybrid DC power systems across critical industries and now bring that proven technology to hyperscale AI, HPC, and next-gen data centers.
SPOC 800 VDC Power Systems — Engineered to simplify complexity, reduce cost, and power the future of AI.
Find your 800 VDC Solution
Rectangle 37 (4)
DESIGNED TO PERFORM
01. Modular, DC-native architecture for uninterrupted uptime
02. Purpose-built for AI, HPC, and large-scale compute loads
03. Hybrid redundancy with multiple DC sources
04. Seamless integration across diesel, battery, and renewable inputs
05. High-efficiency charging & energy storage for peak-demand smoothing
06. Engineered to reduce harmonics, heat, and fault propagation
07. Supports GPU rack densities of 350–600 kW+
Rectangle 37 (5)
COST SAVINGS & EFFICIENCY
CapEX (Upfront Cost Savings)
01. Fewer conversion stages = fewer devices to purchase and maintain
02. Smaller cable gauge & lighter infrastructure
03. Reduced footprint (as low as 0.5 m² per 10 racks)
04. Modular deployment reduces construction time and cost
Rectangle 37 (6)
FLEXIBLE & SCALABLE
01. End-to-end DC grid architecture (MVAC → 800 VDC → rack)
02. Rapid deployment with fewer components and smaller cable gauge
03. Scales cleanly toward 800–1500 VDC as standards evolve
04. Compatible with long- and short-duration BESS
05. Works with new builds or brownfield retrofits
06. DC passive redundancy for uninterrupted operation
07. Ideal for operators seeking predictable interconnection profiles
Rectangle 37 (7)
OpEx (Ongoing Operational Savings)
01. Higher system efficiency (95%+) lowers energy waste
02. Lower thermal loads reduce cooling demands
03. Fewer failure points = fewer outages, fewer emergency interventions
04. Longer MTBF and simplified maintenance
05. Energy storage integration reduces grid charges and peak-demand costs