Creation of CERID: Challenge, Education, Research, Innovation, and Deployment “In the Context of Smart MicroGrid” (original) (raw)

Related papers

Experience to Electrical Engineering Students the Principles of Smart Grid Platform

World Energy Consumption relies heavily on coal, oil, and natural gas. Fossil fuels are non-renewable, that is, they rely on finite resources that will eventually dwindle, becoming too expensive or too environmentally damaging to retrieve. In contrast, renewable energy resources, such as wind and solar energy, are constantly replenished and will never run out. Due to the rising need for professionals and academics with a background and understanding in the Smart Grid and Renewable Energy fields, Holon Institute of Technology ("HIT") developed a new program at the Faculty of Electrical Engineering. The Renewable Energy program gives the students technical and practical aspects of energy use (technology and methodology of the study) and energy efficiency. The program also deals with minimizing the environmental impacts of energy use, as well as with energy economy and environmental policy. HIT offers its students a well-equipped laboratory, containing state of the art equipment in various fields such as: photovoltaic energy systems, a smart grid telecommunications and information security platform, wind and water energy work stations, and power electronics equipment. This article presents the latest teaching and conclusions obtained in experiments conducted on the system platform.

Student Design of a Sustainable Microgrid for Rural Kenya

2015 ASEE Annual Conference and Exposition Proceedings

for the Electrical and Computer Engineering department advising senior design projects, including humanitarian projects for which he co-authored several papers with Dr. Henry Louie. He has installed several off grid systems in Africa and is member of the IEEE Community Solutions Initiative, finding appropriate energy solutions for impoverished communities off the power grid.

Contribution to the knowledge of a microgrid. Smart Campus

Renewable Energy and Power Quality, 2016

From an analysis of electric energy consumption of different buildings of the University of Vigo, it has been designed the integration of a microgrid and its elements, distributed generation, energy storage, security and control systems and applications of a Smart Campus. Distributed generation of electricity is based on the integration of renewable energy sources, especially solar photovoltaic and wind energies, aided by the installation of a hydrogen fuel cell, which is produced out of energetic overproduction of the aforementioned sources by two electrolyzers. In order to avoid the consequences of randomness of wind and solar sources, an energy storage system has been installed. It stores hydrogen produced when overproduction takes place, in order to be able to transform it into electricity when power needs of the microgrid demand it, through a hydrogen fuel cell. Generation and energy storage will be regulated by a security and control system, which will also be responsible for the management and integration of several apps of the Smart Campus. Besides, the implementation in the microgrid of these different apps of the Smart campus, charging spots for electrical cars, parking management, and replacement of conventional lighting by an intelligent and independent system based on renewable energy will be taken into consideration in this study.

Smart Microgrid Educational Laboratory: An Integrated Electric and Communications Infrastructures Platform

Scientia Iranica

Microgrids as the local area power systems are changing the power system landscape due to their potential of offering a viable solution for integrating renewable energy resources into the main grid. From the operational point of view, microgrids should have the appropriate power electronic interfaces, control schemes, as well as monitoring and automation infrastructures to provide the required flexibility and meet the related IEEE 1547 standard requirements. This paper describes some of the efforts made in the smart microgrid educational laboratory to provide these facilities and create a real-world conditions needed to conduct researches and teach the related courses. Laboratory works not only increase the practical skills of the students but also can motivate them to pursue theoretical courses with more passion. The introduced facilities are somehow unique for the integration of both electric and communication infrastructures which overcome the shortcomings of not considering data transfer challenges in the studies. Complete hardware design of power plant components, and incorporation of solar photovoltaic (PV) and two types of wind turbine generations are some of the efforts made to bring the real-world conditions in the laboratory. In the load-related side, dynamic behaviors of the various types of motors are modeled. To demonstrate some of the laboratory applications, some experimental studies have been carried out. The results show that this laboratory model is useful to provide insightful perspectives about the microgrid future.

A methodology for community engagement in the introduction of renewable based smart microgrid

Energy for Sustainable Development, 2011

Introduction of new technologies is necessarily a social and cultural transformation that implies adaptation to a new context, co-created by the interaction between those intervened and interveners. Sustainable technologies should be aimed to preserve basic functions of socio-ecological systems while limiting evolution of unsustainable practices, as it is the case of non-conventional renewable energy sources. In this research we propose a methodology of intervention for the introduction of smart microgrid system in a rural community. The introduction of new energy technologies in a rural setting is a challenge, since it generates changes in patters of energy use that affect the demand of the system. Smart microgrid systems have the advantage of being more resilient than conventional approaches to renewable energy, as they can adapt to changes in the demand and through time. The proposed methodology is based on the concept of a community as a socio-ecological system approach affected by a technological intervention, aimed to move towards a stage of more sustainable use of resources. The method is divided in three stages, each one focused on enhancing elements of the socio-ecological systems and integration among stakeholders: trust, diversity, boundaries of the system, territoriality, adaptability and reflexivity. This methodology is validated in a case study on smart microgrids development in a rural community in the north of Chile. The application of this methodology highlights the importance of learning processes among stakeholders, specially the development of reflexivity within developers. Adoption and adaptation to new technologies depends on the characteristics of each community, but it can be enhanced when participation shapes the evolution of the technological intervention, opening up to a diversity of expectations associated to the complexity of the system.

Towards designing and developing curriculum for the challenges of the smart grid education

2014 IEEE Frontiers in Education Conference (FIE) Proceedings, 2014

At the tipping of a paradigm shift in the way energy is produced, transmitted and delivered, the research efforts have not been paralleled by the curricular development. With rapid pace of changes in the field of Smart Grid (SG), the traditional research and educational efforts have been a major domain for electrical engineers. As a mode of discovery and education, interdisciplinarity facilitates broadened perspectives, ability to synthesize, analyze, integrate, and apply knowledge, and outof-the-box thinking. The major contributions of this paper are discussion of requirements of the educational efforts in SG with special emphasis on multidisciplinarity, survey of the related work, which is the first in the literature to the best of our knowledge, and a discussion of the content for such an effort. A mixed team of power engineers and computer scientists are developing a layered curriculum starting from the introductory material from a variety of SG topics. A distinguishing advantage is the availability of many software tools and the state-of-the-art testbed as a result of years of research.

A Case Study of Implementing a Localized Smart Grid in Developing Countries

2016

ahmedomer27 at gmail dot com fahadjaved at lums dot edu dot pk naveedarshad at lums dot edu dot pk Phone:+92-42-35722670 Fax: +92-42-35898315 Smart grids and its related applications can potentially provide us with a fascinating ways to improve existing electric distribution networks. However, to realize most of the applications envi-sioned in smart grid a large scale infra-structural transformation is needed in the current electric distribution network. This requires considerable resources as well as time. For developing coun-tries this problems becomes even more problem-atic for two reasons: First, they have fewer fi-nancial resources to invest in smart grid technol-ogy, second most of these countries already have an energy crisis and need for better management is needed urgently. This study examines various technologies that are already available in devel-oping countries which can be used for smart grid applications. The technologies in this study can provide a scalable communica...

Feasibility study of microgrid application for Murdoch University

2019

In this modern era, technology continues to develop and improve, experiencing a signification transformation from the traditional concept and centralized power generation to an incorporated system with distributed energy resources (DER) which is then located closer to the local loads. A sustainable solution with this future concept would be the Microgrid application, and it is a growing system in recent days. This system consists of an integration of the generation from different renewable energy sources that contain energy storage systems. Microgrid also acts as a backup source to failure of the main power supply allowing the network to operate independently. This technology has provided a high reliance on the economy and the growing demand of the technologies such as the energy generated from wind and solar. The growth in several Microgrid utilization has also decreased the reliance on the usage of fossil fuels. The idea of the Microgrid application and implementing it into the ne...

Ac 2011-554: Electric Energy and Power Educational Pro- Grams Development Symposium

2011

There has been much discussion recently regarding the issues involved in education and research programs in the area of electric power and energy. This discussion has included the topics of reforming electric energy systems curricula both at undergraduate and graduate levels. The Electrical and Computer Engineering Department Heads Association (ECEDHA) and other interested government and industry groups are developing workshops and special sessions at key conference venues to focus on topics that include: sustainable and renewable energy sources, smart grids, energy storage, efficiency, plug-in hybrid electric vehicles, and climate change. ECEDHA with the support of the National Science Foundation is establishing a workshop series on these issues aimed at department chairs and faculty members who are interested in developing educational and research programs in this critical area within Electrical and Computer Engineering (ECE). Without question a safe, dependable, secure, reliable ...