# The 2017 ISO New England System Operational Analysis and Renewable   Energy Integration Study (SOARES)

**Authors:** Aramazd Muzhikyan, Steffi O. Muhanji, Galen Moynihan, Dakota J., Thompson, Zachary M. Berzolla, Amro M. Farid

arXiv: 1812.04787 · 2018-12-14

## TL;DR

This study analyzes how increasing renewable energy sources like wind and solar impact New England's power grid operations, highlighting the need for more reserves and the role of curtailment in balancing the system.

## Contribution

It introduces a comprehensive simulation methodology for assessing renewable integration effects on grid reserves and operational strategies in New England.

## Key findings

- High renewable penetration can exhaust operating reserves.
- Curtailment is used to balance and mitigate system limitations.
- Higher operating reserves are necessary for reliable renewable integration.

## Abstract

The bulk electric power system in New England is fundamentally changing. The representation of nuclear, coal and oil generation facilities is set to dramatically fall, and natural gas, wind and solar facilities will come to fill their place. The introduction of variable energy resources (VERs) like solar and wind, however, necessitates fundamental changes in the power grid's dynamic operation. VER forecasts are uncertain and their profiles are intermittent thus requiring greater quantities of operating reserves. This paper describes the methodology and the key findings of the 2017 ISO New England System Operational Analysis and Renewable Energy Integration Study (SOARES). This study was commissioned by the ISO New England stakeholders to investigate the effect of several scenarios of varying generation mix on normal operating reserves. The project was conducted using the holistic assessment approach called the Electric Power Enterprise Control System (EPECS) simulator.The EPECS characterizes a power system in terms of the physical power grid and its multiple layers of control including commitment decisions, economic dispatch, and regulation services. This paper provides precise definitions of how variable energy resources and operating reserves are modeled. It also includes detailed models of the day-ahead resource scheduling, the same-day resource scheduling, the real-time balancing operations and the regulation service. Among the key findings, the reports shows that scenarios with high penetrations of VERs exhaust their operating reserves for part of the year and all scenarios curtail semi-dispatchable resources both to complement operating reserves and to mitigate some of the topological limitations of the system. Overall, curtailment emerges as a key balancing performance control lever and there is a clear need for higher amounts of operating reserves.

## Full text

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## Figures

55 figures with captions in the complete paper: https://tomesphere.com/paper/1812.04787/full.md

## References

97 references — full list in the complete paper: https://tomesphere.com/paper/1812.04787/full.md

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Source: https://tomesphere.com/paper/1812.04787