# Optimal Switchable Load Sizing and Scheduling for Standalone Renewable   Energy Systems

**Authors:** Abdulelah H. Habib, Vahid R. Disfani, Jan Kleissl, Raymond A. de, Callafon

arXiv: 1702.00870 · 2017-02-06

## TL;DR

This paper presents analytical solutions and algorithms to optimize load sizing and switching schedules in off-grid renewable systems, maximizing solar energy utilization without costly storage, demonstrated with real solar data.

## Contribution

It introduces novel mixed-integer linear programming and constrained least squares algorithms for optimal load sizing and switching in off-grid systems, enhancing solar energy utilization.

## Key findings

- 73% solar energy utilization with two loads
- 98% utilization with six loads
- Algorithms outperform baseline scheduling methods

## Abstract

The variability of solar energy in off-grid systems dictates the sizing of energy storage systems along with the sizing and scheduling of loads present in the off-grid system. Unfortunately, energy storage may be costly, while frequent switching of loads in the absence of an energy storage system causes wear and tear and should be avoided. Yet, the amount of solar energy utilized should be maximized and the problem of finding the optimal static load size of a finite number of discrete electric loads on the basis of a load response optimization is considered in this paper. The objective of the optimization is to maximize solar energy utilization without the need for costly energy storage systems in an off-grid system. Conceptual and real data for solar photovoltaic power production is provided the input to the off-grid system. Given the number of units, the following analytical solutions and computational algorithms are proposed to compute the optimal load size of each unit: mixed-integer linear programming and constrained least squares. Based on the available solar power profile, the algorithms select the optimal on/off switch times and maximize solar energy utilization by computing the optimal static load sizes. The effectiveness of the algorithms is compared using one year of solar power data from San Diego, California and Thuwal, Saudi Arabia. It is shown that the annual system solar energy utilization is optimized to 73% when using two loads and can be boosted up to 98% using a six load configuration.

## Full text

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## Figures

18 figures with captions in the complete paper: https://tomesphere.com/paper/1702.00870/full.md

## References

45 references — full list in the complete paper: https://tomesphere.com/paper/1702.00870/full.md

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Source: https://tomesphere.com/paper/1702.00870