YOUNG SCIENTIST LECTURE
Speaker: MR. Han Li
Title: Energy Flexibility of Residential Buildings: A Systematic Review of Characterization and Quantification Methods and Applications
Speaker bio: Mr. Han Li is a senior Scientific Engineering Associate with the Building Technology and Urban Systems Division of Lawrence Berkeley National Laboratory, California, USA. His current research focuses on methods and metrics for building performance evaluation from various perspectives, including diverse occupant characteristics and demand flexibility, using both simulations and real measurements. Mr. Li received his MS in Building Performance and Diagnostics from Carnegie Mellon University in 2017.
Supporting institution: Building Technology and Urban Systems Division of Lawrence Berkeley National Laboratory, California, USA
ADAPEN paper link: https://doi.org/10.1016/j.adapen.2021.100054
Abstract: With building electric demand becoming increasingly dynamic, and a growing percentage of intermittent renewable power generation from solar photovoltaics and wind turbines, the power grid is facing increasing challenge to manage the real time balance between the supply and demand. With advancements in smart sensing and metering, smart appliances, electric vehicles, and energy storage technologies, demand side management of residential buildings can help the grid to improve stability by optimizing flexible loads. This paper reviews recent studies on residential building demand side management, with a focus on characterization and quantification of energy flexibility covering various types of flexible loads, metrics, methods, and applications. The reviewed studies showed four levels of applications: building level (45%), district or community level (29%), system level (19%), and building sector level (7%). Shifting loads is the dominant flexibility type in 60% of applications, followed by shedding (19%), generation (16%), and modulating (6%). Depending on the technology and application scope, flexible operations have a wide range of performance, with peak power reductions of 1%~65%, energy savings up to 60%, operational cost reduction of 1%~48%, and greenhouse gas emission reductions of up to29%. More than half (51%) of the studies employed control strategies to achieve flexibility; among those 72% used optimal controls, while 28% used rule-based controls. About 58% of the studies used mathematical formulation to quantify energy flexibility. Most studies were based on simulation, while less than 15% of the studies had measurements from experiments or field tests. The review reveals research opportunities to address significant gaps in the existing literature: (1) establishing a common definition and performance metrics for energy flexibility of buildings that are technology and application agnostic, (2) developing an ontology to standardize representation of flexibility resources for interoperability, (3) integrating occupant impacts into the quantification and optimization of energy flexibility, and (4) developing requirements and credits of energy flexibility in building energy codes and standards. Findings from the review can inform future research and development of energy flexible buildings which are essential to a reliable and resilient power grid.
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