Watts vs. Bytes: Turning Data Centers into Grid Assets via Storage Compute Co-Optimization

TL;DR

This paper presents a co-optimization framework for data centers with co-located batteries, enhancing grid services and operational efficiency under interconnection constraints using workload scheduling and DVFS.

Contribution

It introduces a robust day-ahead co-optimization model integrating workload management and battery dispatch, considering grid constraints and market participation.

Findings

Coordinated compute-storage flexibility significantly increases grid value under constraints.

BESS value doubles under peak-load and ramping limits due to workload management.

Processor-level DVFS provides substantial flexibility under tight load conditions.

Abstract

Enabling continued data-center growth under increasing grid stress motivates closer coordination between flexible computing demand and co-located battery energy storage systems (BESS) to improve site operations and provide grid services. This paper develops a robust co-optimization framework for day-ahead operation of data centers with co-located BESS under utility-imposed interconnection limits on peak load and ramping. The model jointly considers deadline-constrained computing workloads, managed through workload scheduling and dynamic voltage and frequency scaling (DVFS), together with degradation-aware BESS dispatch to enable cost optimization and participation in ancillary-service markets. Case studies based on real-world market and workload data show that the proposed framework yields feasible day-ahead schedules across a range of operating conditions, with substantially larger benefits when interconnection constraints become binding. Under baseline conditions, BESS value is derived from both ancillary-service participation and improved workload and energy management. Under stressed peak-load and ramping limits, however, the daily value of BESS increases by a factor of two or more, driven primarily \revise{by BESS actions to reduce the potential incompletion in the schedulable workload while complying with interconnection constraints}. Under tight peak-load caps, workload composition also matters where a higher share of non-schedulable jobs can increase operating cost by more than 25\% relative to more flexible workload mixes. \revise{Additionally, DVFS studies further show that processor-level control is a material flexibility lever under tight load limits.} These results demonstrate that coordinated compute-storage flexibility can materially expand the operational headroom and grid value of data centers, especially under increasingly scarce grid capacity.