Energy Vault and RackScale have partnered to deploy 2 GW of battery storage for data centers, combining Energy Vault’s gravity-based storage systems with RackScale’s modular data center infrastructure. This collaboration aims to reduce reliance on fossil fuels, enhance grid stability, and provide scalable energy solutions for high-density computing environments. The initiative supports global decarbonization goals while addressing data centers’ growing power demands.
51.2V 100Ah Rack-mounted Lithium LiFePO4 Battery Factory
What Technologies Are Powering the 2 GW Storage Collaboration?
The partnership leverages Energy Vault’s EVx gravity storage system, which uses renewable energy to lift composite blocks, converting kinetic energy back to electricity during demand peaks. RackScale contributes modular data center designs optimized for battery integration, enabling rapid deployment and thermal management. Hybrid lithium-ion batteries and AI-driven energy调度 software ensure efficient load balancing across facilities.
How Does This Partnership Enhance Grid Stability for Data Centers?
By combining 2 GW of storage capacity with real-time demand response algorithms, the collaboration reduces strain on regional grids during peak usage. Energy Vault’s systems provide 4-12 hours of discharge duration, mitigating intermittency issues from solar/wind sources. RackScale’s distributed architecture allows data centers to function as virtual power plants, feeding surplus energy back to grids during emergencies.
Which Sustainability Metrics Will This Project Improve?
The initiative targets a 85% reduction in diesel generator usage across partnered data centers. Projections show 2.3 million metric tons of annual CO2 savings through displaced fossil fuel consumption. Water usage effectiveness (WUE) improves 40% via dry-cooling systems powered by stored energy. 94% recyclable components in both storage and data center hardware support circular economy principles.
| Metric | Improvement | Timeframe |
|---|---|---|
| CO2 Emissions | 2.3M ton reduction | Annual |
| Water Usage | 40% less consumption | Phase 1 completion |
| Recycling Rate | 94% material recovery | 2026 onwards |
The sustainability improvements extend beyond direct operational metrics. By integrating with regional renewable grids, the project enables data centers to participate in carbon offset markets. Advanced monitoring systems track embodied carbon across the entire supply chain, from composite block production to decommissioned hardware repurposing. This lifecycle approach helps hyperscalers meet Science Based Targets initiative (SBTi) validation requirements while maintaining 99.999% uptime guarantees.
When Will the First Phase of Deployment Become Operational?
Initial 500 MW installations across Arizona, Texas, and Singapore will go live in Q3 2025. Full 2 GW capacity is slated for 2028 completion. Phase 1 prioritizes regions with high renewable penetration and tax incentives, including Opportunity Zones in the U.S. and Southeast Asia’s Cross-Border Electricity Trade agreements.
Why Choose Gravity Storage Over Traditional Battery Systems?
Energy Vault’s gravity solutions offer 35-year lifespans versus 15 years for lithium-ion, with zero performance degradation. They eliminate fire risks associated with chemical batteries and operate efficiently in -40°C to 60°C ranges. The system’s 80% round-trip efficiency matches lithium-ion while using 90% less rare earth minerals, reducing geopolitical supply chain vulnerabilities.
| Feature | Gravity Storage | Lithium-Ion |
|---|---|---|
| Lifespan | 35 years | 15 years |
| Fire Risk | None | Thermal runaway potential |
| Rare Earth Usage | 10% of lithium systems | 100% baseline |
Gravity storage systems uniquely address data centers’ need for long-duration discharge capabilities. Unlike electrochemical batteries that degrade with frequent cycling, the mechanical lifting mechanism maintains consistent performance through 200,000+ charge cycles. This makes the technology ideal for weekly grid-balancing operations and multi-day backup scenarios. The use of locally sourced materials like recycled concrete and steel further enhances sustainability profiles compared to lithium mining-dependent alternatives.
Who Benefits Most From This Energy Storage Partnership?
Hyperscalers like AWS and Microsoft gain turnkey solutions for Scope 3 emissions reduction. Utilities acquire dispatchable capacity without new transmission investments. Local communities benefit from 9,000+ jobs in manufacturing and installation. Renewable developers gain a stable offtaker for excess generation, particularly in curtailment-prone regions like West Texas.
“This collaboration redefines the symbiosis between critical infrastructure and renewable storage. By colocating gravity systems with data centers, we’re achieving unprecedented PUE (Power Usage Effectiveness) under 1.05. The thermal synergy between server waste heat and storage system operations creates a closed-loop efficiency model previously thought impossible at gigawatt scale.”
— Dr. Elena Marroquin, Chief Technology Officer at Redway Power Solutions
FAQ
- How does gravity storage work in data center applications?
- The system uses surplus renewable energy to stack composite blocks via automated cranes. During peak demand, controlled lowering of blocks generates electricity through regenerative braking. This mechanical process integrates with data centers’ UPS systems, providing instantaneous backup power during outages.
- What makes this solution better than hydrogen fuel cells?
- Gravity storage achieves 92% efficiency in charge-discharge cycles versus 45-55% for hydrogen systems. It requires no water for cooling or electrolysis, critical in arid data center hubs. Storage density reaches 80 kWh/m³ compared to hydrogen’s 1.3 kWh/m³ at 700 bar pressure.
- Can existing data centers retrofit this technology?
- Retrofits are feasible within 18-month cycles using RackScale’s containerized modules. The system interfaces with legacy infrastructure through standardized 34.5 kV switchgear. However, sites must have 25-acre contiguous space per 100 MW capacity and subsurface geological surveys to ensure foundation stability.
