Microgrids In Boston: Enhancing Energy Resilience And Profitability – Enel’s innovation team has developed a first-of-its-kind gas station microgrid in Ayer, Massachusetts, paving the way for commercial deployment of integrated microgrids and energy-resilient gas stations across the state.
David Rodriguez, Chief Innovation Officer, and his team at Enel always knew that microgrids would be critical to the future of energy resilience. Microgrids are self-sufficient energy systems that can operate independently of the central power grid, even in the event of power outages. However, for many years, microgrid applications were largely theoretical and not yet commercially viable – energy technology and infrastructure still had some catching up to do.
- 1 Microgrids In Boston: Enhancing Energy Resilience And Profitability
- 2 Microgrids: An Energy Solution For Small Towns With Big Aspirations
- 3 Ever Heard Of Microgrids? They’re Awesome—here’s Why
Microgrids In Boston: Enhancing Energy Resilience And Profitability
So when the Massachusetts Clean Energy Center (MassCEC) launched the Resilient Service Stations Challenge in response to intensifying storms in the Northeast, David and the innovation team jumped at the opportunity to make future energy market concepts a reality. They have developed the first micro-network of gas stations of this type, which will be fully operational from 2022.
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Gas stations, especially those located along emergency routes, must ensure that their lights remain on during power outages. They provide refueling, water, food, Wi-Fi connections and other essential resources, including critical support to emergency services and utility crews during emergencies. However, these stations experience the same network failures as other buildings and are often ill-equipped to maintain even the most basic critical functions.
In the wake of Hurricane Sandy and the increasing frequency and impact of extreme weather events, the need for continuous power at gas stations has become a top priority for Massachusetts leaders.
The MassCEC Resilient Service Stations Challenge sought to pioneer solutions that provide service stations with measurable energy resiliency while increasing the adoption of clean energy across the state. Because Massachusetts is home to Enel’s North American headquarters, David and his team have a first-hand understanding of what the community needs most and the importance of contributing to the local clean energy economy in a way that helps partners achieve their sustainability and decarbonization goals .
So with the concept in hand, David and his team presented a microgrid solution that was both modular and scalable – and it was approved. Enel X worked with Global Partners LP, one of the largest independent owners, suppliers and operators of gas stations and convenience stores in the Northeast, to deploy a microgrid at Alltown Fresh in Ayer, Massachusetts.
Microgrids: An Energy Solution For Small Towns With Big Aspirations
Incorporating Enel meter. Now Alltown Fresh can attract electric vehicle drivers who want to power their vehicles with renewable energy, while supporting the local grid by reducing overall demand and reducing emissions.
Sustainability is always the basis of Enel’s innovative projects. In the case of the Alltown Fresh microgrid, the commitment to sustainability was shared by gas station owners Global Partners LP, the government agency MassCEC and the Enel team, making it a win-win opportunity.
Global Partners LP has a unique vision for the future of fuel stations, and the project supports their commitment to the energy resilience of their community, embracing drivers’ transition to electric mobility and contributing to a sustainable future. For MassCEC, this was an opportunity to take the first step toward increasing the use of clean energy across the state and advancing solutions that lead to energy security, reliability and resilient energy infrastructure. For Enel, this was an opportunity to continue to innovate and create a new microgrid solution that is modular and scalable, enabling enterprises to sustainably electrify infrastructure while saving energy costs. By collaborating between teams and aiming to build the network of tomorrow, Enel can now offer flexible financial solutions that will enable enterprises to become more energy resilient.
At Enel, innovating and co-creating with customers, partners, utilities, governments, suppliers and a whole host of others is the way to make breakthrough ideas like the Alltown Fresh microgrid a reality. But enabling a solution is only the beginning of the fight against the climate crisis. The next logical question was: How could a first-of-its-kind microgrid be scaled and deployed in the future?
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With this in mind, David’s team formed a cross-functional working group for over six months to focus on product development and go-to-market strategy to sell resilient, sustainable and scalable microgrids. This passionate Enel team set out to create commercial solutions in places that many previously considered impossible. The results of these efforts include Enel X projects such as the Eaton microgrid in Puerto Rico and the solar infrastructure and electric vehicle storage and charging infrastructure at UMass Boston.
“With the proliferation of microgrid projects, we can create much more resilient regions across the United States,” David said, reflecting on what this project means for the future of clean energy. “It is also important to see these solar panels at the gas station, fast chargers, because it shows that something is happening. The transformation is happening.” A look at integrating distributed energy resources and energy storage systems with smart distribution networks using demand management
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Microgrids To Improve Energy Efficiency
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Ever Heard Of Microgrids? They’re Awesome—here’s Why
Department of Computer Science and Network Systems, School of Computer and Information Science, University of Pittsburgh, Pittsburgh, PA 15213, USA
Received: August 21, 2022 / Revised: September 21, 2022 / Accepted: September 26, 2022 / Published: September 28, 2022
Microgrids have the potential to provide reliable electricity to key smart city critical infrastructure components after a disaster, thereby increasing the resilience of the microgrid power system. Policymakers and electric grid operators are increasingly concerned about the appropriate configuration and siting of microgrids to keep critical infrastructure operating after a disaster in smart cities. In this context, this paper presents a novel method to solve the microgrid allocation problem, which takes into account several technical and economic factors of the infrastructure, such as critical infrastructure elements, geospatial location of the infrastructure, energy requirements, and microgrid cost. Specifically, the geographic allocation of microgrids is presented as an optimization problem that aims to optimize a weighted combination of the relative importance of nodes across all key infrastructures and associated costs. Moreover, the simulation results of the formulated optimization problem were compared with a modified version of the heuristic method based on the identification of critical nodes of interdependent infrastructure for positioning microgrids in terms of the resilience of multiple smart critical infrastructures. Numerical results using the infrastructure of the city of Pittsburgh, USA are presented as a practical case study illustrating the methodology and trade-offs. The proposed method is an effective method for locating renewable energy resources based on infrastructure requirements.
The percentage of the world’s population living in urban environments has increased from approximately 33% to 55% over the past decade . This growth has created enormous demand and strain on the infrastructure and systems that provide essential city services, resulting in significant interest in the development of smart cities. The main goal of smart city programs is to create smart infrastructure for cities by using innovations in cyber-physical systems, data analytics and information and communication technologies (ICT). Moreover, the proper functioning of smart infrastructures depends more on information and communication technologies and electricity. This increased dependency may result in new security vulnerabilities and lower infrastructure resilience . In particular, severe weather (e.g. snow/ice storms, typhoons, tornadoes, drought-induced wildfires, etc.) is an increasing vulnerability issue as the frequency, intensity and geographic scope of severe weather events are expected to increase with climate change . Currently, severe weather events  are the leading cause of power outages in the United States, which in turn are the leading cause of ICT service interruptions. To this end, smart infrastructures provide more consistent and reliable system performance, new features/features, and
The Implementation Framework Of A Microgrid: A Review
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