Smart Microgrids
Microgrids are smaller-scale versions of a local centralised electricity system - a.k.a. a macrogrid - and are equipped with control capabilities that allow them to operate in tandem with the local macrogrid, or autonomously on a stand-alone basis. As such, microgrids have existed for decades powering industrial sites, military bases, campuses and critical facilities such as hospitals, primarily using fossil-fuel-fired Combined Heat and Power (CHP) and reciprocating engine generators. However, many cities are now interested in microgrid systems that can better integrate renewable generation resources and various energy loads, serve multiple users and/or meet environmental or emergency responses. Microgrids can bring several benefits to the environment, utility operators and customers; benefits that are especially important for cities as they strive to create smart, safe, and liveable communities with thriving economies. Considering local priorities and challenges, municipalities have three good reasons to pursue microgrids: Microgrids contribute to reducing GHG emissions and help cities meet their climate goals by: Fostering the integration and aggregation of renewable energy sources, thanks to their ability to balance energy production and usage within the microgrid through distributed, controllable generation and storage (e.g. CHP, thermal storage or fuel cells). Harnessing energy that would otherwise be wasted (e.g. electricity transmission losses or waste heat from energy production), thanks to the proximity of where energy is generated and where it is needed. Microgrids can strengthen and increase the resilience of the central grid by: Increasing the system-wide reliability and efficiency, as they help reduce or manage energy demand whilst alleviating grid congestion, thanks to their ability to isolate and take over local energy demand autonomously. Reducing grid vulnerability by coping with impending power outages and safeguarding against potential cyberattacks on energy infrastructure. Sustaining energy service during emergencies or natural disasters, especially for critical public services, and helping the macrogrid recover from system outages. Microgrids can better serve the community and enhance the local economy by: Keeping electricity tariffs under control thanks to more efficient and cost-effective grid management, greater use of valuable wasted energy and/or reduced investments in additional energy capacity or transmission infrastructure. Favouring the competitiveness of municipalities, as these can offer low energy costs and elevated levels of reliability that may attract new business and jobs, especially industries highly sensitive to power outages (e.g. data centres, research facilities, etc.). Ensuring power reliability for isolated or hard-to-serve communities by providing clean, reliable, and resilient energy cost-effectively. Constituting an ideal way to integrate renewable resources on the community level and allow for customer participation in the electricity enterprise. Problems to be solved Energy costs Carbon emissions Energy losses Unreliable energy supply Increasing energy demand Ageing, weak and absent infrastructure