“smart Grid Innovations: Enhancing Efficiency And Reliability In Electricity Distribution” – The Keppel Infrastructure-NUS Low Carbon Living Laboratory will leverage the NUS Kent Ridge campus to build, testbed and scale commercially viable innovations in energy management and decarbonisation.

Keppel Infrastructure Holdings Pte Ltd (Keppel Infrastructure), has entered into a Master Research Collaboration Agreement with the National University of Singapore (NUS). This strategic partnership will strengthen Keppel Infrastructure’s low-carbon energy innovation and translational research and development of solutions in smart grid, renewable and clean energy as well as decarbonization technologies.

“smart Grid Innovations: Enhancing Efficiency And Reliability In Electricity Distribution”

As part of the collaboration, Keppel Infrastructure and NUS will leverage the NUS Kent Ridge Campus for the “Keppel Infrastructure-NUS Low Carbon Living Laboratory” by deploying, test-bedding, and scaling commercially viable innovations in distributed energy management, integration. . of solar photovoltaics (PV), thermal energy storage, electrical microgrids, as well as charging stations for electric vehicles (EV) and vehicle-to-grid (V2G) trials. The partnership will provide educational and training opportunities for NUS students, as well as open collaboration opportunities with other ecosystem players such as start-ups, SMEs and researchers.

Energy Management In The Smart Grid: State Of The Art And Future Trends

To jumpstart this strategic collaboration, Keppel Infrastructure and NUS have developed test beds in live environments, performance and optimization and system/subsystem integration in various technologies for data collection, analysis and performance validation with the intention of accelerating commercial application. Jointly identified technologically proven innovations. Selected projects are:

Keppel Infrastructure CEO Ms. Cindy Lim said, “We are redoubling our efforts in sustainable innovation and technology development to sharpen Keppel Infrastructure’s competitive advantage in the low-carbon economy and partner and add value to industries and our customers. Their green variation. To this end, we are excited to forge this important partnership with NUS to accelerate the commercial deployment of innovative energy technologies, leveraging digitization and decentralization for speed and scale. This is in line with Keppel’s Vision 2030 which places sustainability firmly at the core of the company’s strategy.”

Professor Chen Suhan, NUS Vice President (Research and Technology), said, “NUS leverages our strong capabilities in energy and sustainability research in this collaboration with Keppel Infrastructure to create commercially viable solutions for a seamless green transition. Very excited to use. The NUS Kent Ridge campus will serve as a vibrant living laboratory, where innovative solutions are tested in a realistic operational environment before being deployed on a large scale. These technological capabilities will in turn help increase the climate resilience of our campuses.

In addition, Keppel Infrastructure and NUS will explore collaboration in other energy and sustainability related areas, such as decarbonisation of industrial emissions, innovative solar projects as well as carbon capture technologies and applications including the use of nature-based solutions.

Smart Grid Program

The parent company of Keppel Infrastructure, Keppel Corporation Limited, does not expect the above developments to have any material impact on earnings per share and net tangible assets for the current financial year.

[1] The solution was jointly designed and developed by NUS and Keppel DHCS Pte Ltd (KDHCS), a wholly owned subsidiary of Keppel Infrastructure. The project was funded by the Energy Market Authority under its Energy Resilience Grants call in 2018.

This site uses cookies. By clicking Accept or continuing to use this site, you consent to our use of cookies. For more details about cookies and how to manage them, please see our privacy notice. Globally, the use of electric vehicles (EV), a key component in achieving overall sustainable urban mobility, is seeing strong growth and reaching record-breaking levels. Level of sales. In anticipation of growing challenges resulting from climate change and fossil fuel depletion, utilities are faced with the challenges of decarbonizing power generation and meeting growing energy demand. EVs can play a major role in providing energy-efficient and sustainable solutions for utilities, cities and countries. The smart grid, an electricity supply network that uses digital communication technology to detect and react to local changes in usage, is the foundation that will enable market adoption of EVs.

The availability of charging stations in all smart cities, on the road, in off-street parking and garages, and in buildings, is critical to the adoption of EVs.

Tnb Smart Grid Initiatives

In cities across the United States, many organizations are building charging stations. Currently, many municipalities and private companies offer free recharges to EV owners as an incentive to use these clean vehicles. However, as EVs grow in popularity, these free recharges are likely to end, and charging station owners will be looking for a convenient way to charge EV owners.

Smart grid technologies offer a potential solution to this problem, allowing EVs to identify themselves to a charging station when they are plugged in and to automatically bill the owner for the electricity used.

Along with a smart grid recharging infrastructure, EVs can also help reduce pressure on the smart grid, as EVs can both draw power from the grid when charging, and return power when demand is high. This is a concept called “vehicle to grid”. By drawing a number of batteries plugged into the smart grid in its service area, a utility can potentially inject additional power into the grid during critical peak periods.

The Internet of Things is an important component for upcoming smart grid technologies. New to IoT? Get started with the IEEE Guide to the Internet of Things.

Advancing Convergence Research: Renewable Energy Solutions For Off Grid Communities

Ready to expand your skills? Explore our library of hundreds of hours of online learning designed to help you advance in your career. As the traditional grid system is aging and can barely keep up with the increasing demand for electricity, governments around the world focus on adopting and integrating smart grid technology.

It has been in focus in the European Union for years as a system to efficiently provide “sustainable, economic and secure electricity supply”. In the United States, efforts to move toward smart and clean energy began a decade ago when the country established the first policy in this direction. From this point on, investment, technology research and development for smart grids are officially in the US. was supported by the Govt.

In this article, we will explore what makes the smart grid important both nationally and globally, how it works and how IoT is used in smart grid system development.

It is an electricity network that includes a system of infrastructure, hardware and software solutions that enable two-way communication between all system components and participants and provide efficient power generation and distribution across the supply chain.

Era Net Smart Energy Systems: Focus Initiative Smart Grids Plus

A smart grid is often described as a self-sustaining distribution system. It can provide energy from a variety of power sources, including renewables and storage. In addition, implementing this system empowers suppliers and users with unparalleled control and management capabilities.

Unlike a traditional grid with one-way communication, a smart grid is a complex network that represents multiple two-way interactions between equipment and participants in the supply chain. This structure enables different scenarios of how the generated power can be moved and managed. Here is the most basic step-by-step view.

By switching to a smart grid, power generated from various and often distributed sources can be used. This includes conventional power plants, renewable solar and wind as well as plug-in electric vehicles and energy storage.

Using a network of transmission lines, substations and automated distribution systems, power is converted to the correct voltage range when needed (in the case of solar or wind) and distributed to end users.

How Secure Is Our Smart Grid?

End-users get comprehensive power management capabilities and visibility for smart grids, sensor-enabled devices, smart sockets, plugs, etc. By using these tools, consumers become active participants in managing their electricity consumption — use mobile or web apps to monitor and control power usage remotely, configure automated systems, respond to load changes, and manage power consumption in real time. to control their expenditure and emissions.

People in the energy industry, utility companies and other professionals extend their control and management capabilities to a smart grid. Connected homes, communities and entire cities use electricity and generate data on consumption and load. This data can be used by any authorized participant in the supply chain. Thanks to data analysis and visualization tools, energy consumption data is transformed into insights that form the basis of future decisions.

For example, energy companies can manage grid assets and perform predictive maintenance, utility companies can create demand response programs, residents can dynamically respond to differences in load and when energy is most expensive. So can reduce the consumption.

Households not only practice greater energy use, but also store enough power to provide homes in an off-grid scenario. By using storage, households save excess energy, choose the loads they need to back up and use this energy in the event of an outage, for example. In addition to providing management benefits, storage becomes one of the innovative smart grid technologies essential for independent residential grids that rely entirely on renewables and generate large surpluses.

How Ai Accelerates The Energy Transition

Traditional grids are aging and are no longer effective in relation to the growing electricity demand. The figure below proves that it shows the basic differences and benefits of a smart grid over a conventional one. Apart from these advantages, there are three basic reasons why we need smart

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