Hyperscale Power Infrastructure Design
Enabled deployment of large-scale compute facilities with 100 MW–1 GW power capacity, achieving ultra-high availability through redundant utility integration and on-site backup systems.
Situation
A technology client required new hyperscale data center campuses capable of supporting extremely high-density compute workloads. The primary constraint was delivering massive, reliable power capacity while maintaining near-continuous uptime.
Solution
Designed end-to-end electrical infrastructure prioritizing redundancy, fault isolation, and rapid failover across all power layers.
OUTCOMES
Challenges
Capacity
- •Gigawatt-scale power demands
- •Rapid expansion pressure
Reliability
- •Uptime guarantee pressure
- •Fault isolation gaps
Redundancy
- •Failover architecture gaps
Solutions
Dual Utility Redundancy
Dual independent utility feeds from geographically separated substations.
- Connected geographically separated substations for resilience
- Eliminated single points of grid dependency
High-Voltage Distribution
High-capacity medium- and high-voltage distribution systems.
- Engineered scalable medium- and high-voltage pathways
- Supported hyperscale campus load growth
- Maintained stable delivery under peak demand
On-Site Backup Generation
On-site backup generation using a combination of gas and diesel systems.
- Deployed hybrid gas and diesel backup systems
- Ensured extended outage survivability
- Enabled layered emergency response coverage
UPS Bridging Architecture
UPS systems with dedicated battery rooms for outage bridging.
- Implemented facility-scale UPS battery environments
- Bridged transitions during generator activation
- Maintained uninterrupted compute continuity
Segmented Power Isolation
Segmented power distribution architecture to isolate faults and maintain service continuity.
- Partitioned distribution into isolated segments
- Prevented cascading infrastructure failures
- Maintained localized service continuity