Power Infrastructure

Power-first infrastructure for AI scale.

Wolverine controls 52+ MW of contracted utility capacity distributed across a portfolio of utility-connected industrial sites, structured for phased build-out toward a 180 MW portfolio ceiling. Power is engineered first across every deployment — compute follows the energization curve, not the other way around.

Capacity at a Glance

Contracted, deployable, and energizable.

Contracted Capacity 52+ MW Contracted across the Wolverine portfolio, secured through executed utility agreements.
Portfolio Build-Out 180MW Portfolio-wide build-out potential at full deployment across all sites.
Substation Interconnects 3 Substation interconnect points across the portfolio.
Dispatchable Profile 24/7 Continuous load with optional grid-balancing flexibility.

Contracted capacity refers to executed utility agreements across the Wolverine portfolio, not speculative interconnection requests. This is energizable power — deliverable on the platform's deployment timeline rather than on multi-year utility queues.

Why Power Matters

Utility access is the new scarcity.

The modern AI economy is rate-limited by power, not chips. Compute demand has outpaced the rate at which utilities can energize new load — a gap that hyperscale buildouts cannot close on demand-side timelines alone.

Tenants moving capacity in this cycle face multi-year interconnection studies, generation queues, and substation upgrades that arrive long after contracted commitments. Every new entrant pulls forward demand the grid cannot deliver.

Wolverine's position is contracted, not speculative. The platform's 52+ MW of executed capacity is distributed across the portfolio and sits ahead of the queue — available for customer deployment within months rather than years.

  • Multi-year interconnection queues
  • Generation capacity limits
  • Hyperscale demand growth
  • Tenant deployment timelines

Capacity Timeline

180 MW portfolio build-out across a 36-month horizon.

Cumulative power capacity across a 36-month deployment horizon Stacked area chart showing megawatts energized over time. Phase I reaches 52 megawatts by month 12. Phase II expands to 115 megawatts by month 24. Phase III stabilizes at 180 megawatts by month 36. 200 150 100 50 0 MW 0 6 12 18 24 30 36 MONTHS FROM PHASE I START 52 MW 115 MW 180 MW PHASE I PHASE II PHASE III
Portfolio-wide cumulative capacity energized across a 36-month deployment horizon. Phase I energizes the contracted 52+ MW across the portfolio; Phase II expands to 115 MW through multi-site onboarding; Phase III stabilizes at the full 180 MW portfolio build-out potential.

Infrastructure Stack

Built on institutional electrical infrastructure.

Utility Interconnect

Three substation feeds providing redundant utility access to the campus, contracted ahead of tenant onboarding.

Multi-feed, N+1 redundant

Substation Yard

On-site substation infrastructure with transformer and switchgear capacity for phased build-out toward the portfolio's 180 MW ceiling.

Sized for phased build-out toward portfolio ceiling

Distribution

Medium-voltage distribution to modular compute pods, architected for hyperscale rack densities at full build-out.

Medium-voltage distribution to modular compute pods

Backup Generation

Natural gas-fueled standby generation for continuous tenant uptime through utility interruption events.

Sized for continuous tenant uptime during utility interruption events

Battery Storage

On-site BESS for load balancing, peak management, and optional grid-response services.

Sized for load balancing, peak management, and grid-response participation

Redundancy & Resilience

Resilience engineered at every layer.

Backup Generation

Natural gas generation standing by for utility interruption events, sized to maintain tenant compute uptime through grid disturbances. Capacity scales with deployment phase.

Capacity scales with deployment phase.

Battery Energy Storage

On-site BESS for load balancing and peak management. Capable of dispatching against utility demand signals as a grid-response service alongside tenant resilience.

Sized for load balancing and tenant resilience.

Redundant Utility Feeds

Three substation interconnects across multiple utility partners. Single-feed failure does not interrupt operations — redundancy is engineered at the interconnect layer, not only at the generator.

3 substation feeds · N+1 redundancy

Sustainability

Integrated with the grid, not against it.

Wolverine's flexible compute load creates dispatchable demand that utilities can use as a balancing resource — a value the campus delivers in addition to occupying contracted capacity. The platform is structured to participate in utility programs where regulations and economics support it.

Future build-out optionality includes co-located renewable generation and battery storage expansion. The platform's posture is institutional pragmatism: prioritize grid integration and reliability first; layer in renewables as utility relationships and project economics support it.

Power Documentation

Detailed capacity documentation, available under NDA.

Full power capacity documentation, interconnection details, and infrastructure specifications are available for qualified tenant and capital inquiries.

Request Power Capacity Documentation