Internet of Things-aided Smart Grid: Technologies, Architectures, Applications, Prototypes, and Future Research Directions

Traditional power grids are being transformed into Smart Grids (SGs) to address the issues in existing power system due to uni-directional information flow, energy wastage, growing energy demand, reliability and security. SGs offer bi-directional energy flow between service providers and consumers, involving power generation, transmission, distribution and utilization systems. SGs employ various devices for the monitoring, analysis and control of the grid, deployed at power plants, distribution centers and in consumers' premises in a very large number. Hence, an SG requires connectivity, automation and the tracking of such devices. This is achieved with the help of Internet of Things (IoT). IoT helps SG systems to support various network functions throughout the generation, transmission, distribution and consumption of energy by incorporating IoT devices (such as sensors, actuators and smart meters), as well as by providing the connectivity, automation and tracking for such devices. In this paper, we provide a comprehensive survey on IoT-aided SG systems, which includes the existing architectures, applications and prototypes of IoT-aided SG systems. This survey also highlights the open issues, challenges and future research directions for IoT-aided SG systems

Smart grid technology deployment and impact assessment at eThekwini electricity.

M. Sc. Eng. University of KwaZulu-Natal, Durban 2014.The world‟s population is increasing rapidly and is projected to reach 8 billion within the next few decades. Urban migration is also on the rise and it is estimated that there would be significant growth in Africa and more Africans will reside in urban rather than rural areas by 2030. eThekwini, as a leading city in Africa has to establish practices to enable that it utilizes its current resources optimally and sustainably to cater for its future energy and resource requirements. The role of Smart Grid (SG) systems as an electricity industry enabler has been recognized throughout the developed world. The effective introduction and implementation of SGs is also regarded as a major enabler to realize some of the key objectives at local, provincial and national government levels. Significant investment has gone into modernizing the existing electricity grid infrastructure at eThekwini to make it smarter, albeit with varying degrees of success. The term “SG” refers to optimizing, automating and modernizing of the electrical network so that it monitors, protects and automatically optimizes the operation of its interconnected elements. In the eThekwini context, this would include the electricity purchase points from Eskom; distributed generation injection points; the high-, medium- and low voltage networks as well as the industrial, commercial and domestic consumers and their applications and devices. The SG is characterized by a two way flow of electricity and information to create an optimized and automated network that has self-healing properties. It would incorporate the benefits of distributed computing and modern communication systems to deliver information in real-time which enables the almost instantaneous balance of supply and demand. SGs will be designed to ensure high levels of reliability, security, quality, availability and will also aim to improve economic productivity, minimize environmental impact, maximize safety and improve quality of life. The aim, objective and research question of this study will address as to how eThekwini‟s SG maturity levels compare to local and international peers, whether the SG technology deployment is aligned with its objectives, to ascertain the impact of SG implementation and whether the anticipated benefits are being realized. The concept of SG has only been recently formalized at eThekwini and very little research has been conducted in this area which this study aims to address

Effect of hot-arid climatic solar energy on monocrystallinephotovoltaic performance in Pakistan

The domestic dwellings in Pakistan have predominantly implemented low-carbon strategies by harvesting solar energy using photo-voltaic (PV) panels as a long-term vision of low-carbon economy. Most of the urban areas in Pakistan stay hot and humid in an entire year. Consistent solar irradiation at higher temperatures is one of the major factors that affect the power generation performance of monocrystalline PV systems pose challenges to performance and degradation issues. Monocrystalline PV module efficiencies are declining and damaging under the continuous exposure to higher surface day-time temperatures in the different parts of the country. MATLAB simulations were performed based on the validated mathematical approach. This paper investigates the hot arid surface temperature impacts on the performance of PV modules during the summer and winter seasons in Pakistan. The investigations are performed examining the comparative output power generating performance of the PV system. This paper also investigates the influence of installations of PV-system in the North, South, East and West regions of Pakistan. It was examined that the northern areas of Pakistan are more suitable for maintaining the long-term durability of the PV system. Investigations are performed for the peak summer and peak winter days. During summer months, cooling strategies have to be implemented to overcome the heating effects whilst reducing degradation effect on installed PV-system

Ensemble-based network edge processing

Estimating energy costs for an industrial process can be computationally intensive and time consuming, especially as it can involve data collection from different (distributed) monitoring sensors. Industrial processes have an implicit complexity involving the use of multiple appliances (devices/ sub-systems) attached to operation schedules, electrical capacity and optimisation setpoints which need to be determined for achieving operational cost objectives. Addressing the complexity associated with an industrial workflow (i.e. range and type of tasks) leads to increased requirements on the computing infrastructure. Such requirements can include achieving execution performance targets per processing unit within a particular size of infrastructure i.e. processing & data storage nodes to complete a computational analysis task within a specific deadline. The use of ensemblebased edge processing is identifed to meet these Quality of Service targets, whereby edge nodes can be used to distribute the computational load across a distributed infrastructure. Rather than relying on a single edge node, we propose the combined use of an ensemble of such nodes to overcome processing, data privacy/ security and reliability constraints. We propose an ensemble-based network processing model to facilitate distributed execution of energy simulations tasks within an industrial process. A scenario based on energy profiling within a fisheries plant is used to illustrate the use of an edge ensemble. The suggested approach is however general in scope and can be used in other similar application domains

Energy Power, Digital Infrastructure and Elearning Platforms: Afrrican Experience.

Information and communication technologies are one of the most pervasive technologies in the world, second only to 'human intelligence' or the human brain. Thus, understanding the factors that determine the diffusion of new technologies across african countries is important to understanding the process of economic development. And whereas, energy is linked with the capacity to perform, the rate at which energy is consumed for the acceleration of the pace of socio-economic activities is regarded as power. Consequently, it will be obvious that the magnitude of the standard of living in any society; the growth and development of such an economy; and its ability to affect the course of events(such as ICT revolution)will be a function of the extent to which its energy(power) resources are developed and utilised. This paper therefore argued for the need to provide assistance in reducing vulnerability and building the capacity of african countries to more widely reap the benefits of the clean development mechanism in areas such as the development of cleaner and renewable energies. Inevitably, this is the critical condition for the sustainability of the emergent e-learning platforms and digital networks in africa.ICT, learning, elearning, development, energy, power, information, communication, solar, electricity, wind, governance, africa, electronics, telecommunications, internet, digital, satellite, renewable energy, gas turbine, power plants, bandwidth, coal, hydro, biomass, steam, transmission, distribution, utilisation

Smart grids: smart meters and non intrusive load monitoring

El objetivo de este proyecto consiste en sintetizar los conceptos generales de las redes inteligentes (Smart Grids), los cambios que se prevén en la red eléctrica y las principales tecnologías que apoyaran el desarrollo de las mismas. Una Smart Grid es una sistema que permite la comunicación bidireccional entre el consumidor final y las compañías eléctricas, de forma que la información proporcionada por los consumidores pueda ser utilizada por las compañías eléctricas para permitir una operación mas eficiente de las red eléctrica, así como ofrecer nuevos servicios a los clientes. El desarrollo de las Smart Grids es esencial si la comunidad global quiere alcanzar objetivos comunes de seguridad energética, desarrollo económico y mitigación del cambio climático. Para ello, se están desarrollando e implementando nuevas tecnologías como los medidores inteligentes (Smart Meters) y nuevas técnicas de medida de consumo eléctrico como la monitorización no intrusiva (Non Intrusive Load Monitoring). Los Smart Meters son medidores de electricidad, agua o gas que recopilan de forma automática los datos de medida y los envían a las compañías eléctricas permitiendo a estas tener una mejor visión de la distribución eléctrica y proporcionan a sus clientes un mayor conocimiento de su propio consumo. La monitorización no intrusiva es una técnica que detecta los eventos de aparatos eléctricos analizando la demanda total de la carga. Esto es posible debido a que los aparatos presentan características especiales en los momentos de conexión y desconexión consistentes en cambios tanto positivos como negativos en las potencias activa y reactiva. Como dichas características son únicas en cada dispositivo, es posible reconocer el perfil de cada uno de ellos pudiendo saber que dispositivos se están encendiendo o apagando, así como el consumo eléctrico de cada uno de ellos. Esto es lo que ofrece la tecnología Plugwise, que mediante el uso de sus dispositivos permite monitorizar y controlar el consumo eléctrico de una vivienda, oficina o empresa y poder ver los resultados en nuestro propio Smartphone o PC. El uso de tecnología Plugwise en combinación con un Smart Meter permite que tanto clientes como compañías eléctricas sean conscientes de cuanto, como y donde se consume la electricidad

Smart Metering Technology and Services

Global energy context has become more and more complex in the last decades; the raising prices of fuels together with economic crisis, new international environmental and energy policies that are forcing companies. Nowadays, as we approach the problem of global warming and climate changes, smart metering technology has an effective use and is crucial for reaching the 2020 energy efficiency and renewable energy targets as a future for smart grids. The environmental targets are modifying the shape of the electricity sectors in the next century. The smart technologies and demand side management are the key features of the future of the electricity sectors. The target challenges are coupling the innovative smart metering services with the smart meters technologies, and the consumers' behaviour should interact with new technologies and polices. The book looks for the future of the electricity demand and the challenges posed by climate changes by using the smart meters technologies and smart meters services. The book is written by leaders from academia and industry experts who are handling the smart meters technologies, infrastructure, protocols, economics, policies and regulations. It provides a promising aspect of the future of the electricity demand. This book is intended for academics and engineers who are working in universities, research institutes, utilities and industry sectors wishing to enhance their idea and get new information about the smart meters

The Key to Unlocking the Power of Small Scale Renewable Energy: Local Land Use Regulation

Myriad federal and state programs have been promoted to incentivize the research and development of renewable energy as a means of achieving sustainability and producing more affordable alternative energy systems, and these programs could potentially have a profound impact on the way that electricity is produced and consumed in the United States. Small-scale renewable energy generation from sources such as solar and wind, that can be used at the consumer level as a source of power for homes and small businesses, is an important part of this paradigm shift. However, regardless of the fiscal incentives offered to clean-tech companies to design and market these products, as well as the fiscal incentives to homeowners and business owners to purchase and install these technologies, state and local laws can inadvertently impede their installation. These barriers may be caused by outdated statutes and municipal codes or by historic district and aesthetic regulations. Restrictive covenants and deed restrictions in homeowners association communities may further impede the goal of siting small scale renewable energy sources. In response to these problems, many state and local governments have sought to promote small-scale renewable energy development through amendments to comprehensive planning and zoning laws, as well as through utility regulations and various financial incentives. This article provides an overview of some of the strategies that have been used to increase the use of small-scale renewables, focusing on non-commercial renewable energy systems installed at the home or business level. The article begins in Part II with a discussion of various renewable energy incentives offered by the federal and state governments to promote the use of these alternative sources of electricity, including financial and permit-ting incentives. Part III continues with a detailed examination of how the land use regulatory system can be used to promote small-scale renewable energy by employing traditional zoning techniques, asserting that without an appropriate local land use regime, the incentives reviewed in Part II cannot be effectively utilized. Part IV concludes with a warning to local governments that if they fail to accommodate the emerging federal and state policies supporting the siting of renewable energy sources, they may face preemptive statutory measures in the area of land use regulation. This creates perhaps the greatest incentive for local governments to plan and regulate responsibly for promoting the appropriate use of small-scale renewable energy

The Key to Unlocking the Power of Small Scale Renewable Energy: Local Land Use Regulation

Myriad federal and state programs have been promoted to incentivize the research and development of renewable energy as a means of achieving sustainability and producing more affordable alternative energy systems, and these programs could potentially have a profound impact on the way that electricity is produced and consumed in the United States. Small-scale renewable energy generation from sources such as solar and wind, that can be used at the consumer level as a source of power for homes and small businesses, is an important part of this paradigm shift. However, regardless of the fiscal incentives offered to clean-tech companies to design and market these products, as well as the fiscal incentives to homeowners and business owners to purchase and install these technologies, state and local laws can inadvertently impede their installation. These barriers may be caused by outdated statutes and municipal codes or by historic district and aesthetic regulations. Restrictive covenants and deed restrictions in homeowners association communities may further impede the goal of siting small scale renewable energy sources. In response to these problems, many state and local governments have sought to promote small-scale renewable energy development through amendments to comprehensive planning and zoning laws, as well as through utility regulations and various financial incentives. This article provides an overview of some of the strategies that have been used to increase the use of small-scale renewables, focusing on non-commercial renewable energy systems installed at the home or business level. The article begins in Part II with a discussion of various renewable energy incentives offered by the federal and state governments to promote the use of these alternative sources of electricity, including financial and permit-ting incentives. Part III continues with a detailed examination of how the land use regulatory system can be used to promote small-scale renewable energy by employing traditional zoning techniques, asserting that without an appropriate local land use regime, the incentives reviewed in Part II cannot be effectively utilized. Part IV concludes with a warning to local governments that if they fail to accommodate the emerging federal and state policies supporting the siting of renewable energy sources, they may face preemptive statutory measures in the area of land use regulation. This creates perhaps the greatest incentive for local governments to plan and regulate responsibly for promoting the appropriate use of small-scale renewable energy