The four-year project aims to put together a roadmap for developing a sustainable and commercially viable offshore wind industry in India. This report addresses the critical issue of how to prepare the state power systems to connect offshore wind projects in Gujarat and Tamil Nadu. The report assesses the elements that are needed in the future design of offshore wind farms to ensure grid integration along with a preliminary evaluation of existing grid infrastructure across the two states. FOWIND is largely focused on early projects and the possibility for providing easy grid access without any significant need for upgrades for the regional or local grids. The study provides the first of its kind overview of the existing grid infrastructure in Gujarat and Tamil Nadu. The study was prepared in collaboration with the state utilities (GETCO and TANGEDCO) with a focus on integrating offshore wind. India has the world’s 4th largest onshore wind market with a total installed capacity of over 32.6 GW. However, India does have an acute need for large-scale, clean and indigenous energy generation to fuel its rapidly growing economy. Offshore wind power could play a very important role here due to the large wind resources available near centres of high-energy demand. Globally, offshore wind power is becoming increasingly cost-effective with installations close to 14.5 GW at the end of 2016. “Offshore wind has taken dramatic steps forward in the past two years, particularly the major established market in Europe where tender prices have dropped by more than 50% in the last 18 months”, said Steve Sawyer, GWEC Secretary General. “It’s a rapidly maturing technology ready to go global and we expect India to be one of the major beneficiaries.””For the success of Renewables in general and Offshore Wind specifically it is important that it can be integrated into the grid. Otherwise curtailment will have a massive impact on the LCoE. A strong grid is the backbone of a high renewables generation future”, said Mathias Steck, Executive Vice President & Regional Manager Asia Pacific, DNV GL – Energy.Grid integration of renewables and transfer of energy from the generation points to the load centers has a major role to play in fulfilling current Indian Government’s vision of self reliance in the energy sector. Addition and viability of ‘offshore MWs’ will further add to the pace of achieving those set targets”, said Balram Mehta, President Wind & Asset Management at ReNew Power.This study forms the basis for upcoming offshore wind feasibility assessments being conducted by FOWIND, and gives a better understanding for companies and government institutions as to what is required for developing a successful offshore wind industry in India. The FOWIND consortium aims to complete the preliminary roadmap for offshore wind development in India in 2018.
Continue readingBattery Costs in Stationary Energy Could Fall by up to 66%, Grow 17-Fold by 2030, Says IRENA
The cost of battery storage for stationary applications could fall by up to 66 per cent by 2030, according to a new report published by the International Renewable Energy Agency (IRENA). The falling price of batteries could stimulate 17-fold growth of installed battery storage, opening up a number of new commercial and economic opportunities, the report highlights. Launched during the ‘Innovation for Cool Earth Forum’ in Tokyo, Japan, IRENA’s Electricity Storage and Renewables: Costs and Markets to 2030 assessment of electricity storage in stationary applications also found that global storage capacity could triple if countries double the share of renewables in the energy system. “As storage technology improves and prices decline, both utility-scale and small-scale, distributed applications could grow dramatically, accelerating renewable energy deployment” said IRENA Director-General Adnan Z. Amin. “In this dynamic, low-carbon energy environment, now is a crucial time for storage technology. “This research demonstrates that the business case for renewable energy continues to strengthen,” continued Mr. Amin, “positioning it firmly as a low-cost and secure source of energy supply.” The report, which is focused on stationary applications, highlights that while pumped-hydro systems currently dominate total installed power storage capacity, with 96% of the installed electricity storage power globally, economies of scale and technology breakthroughs will support the accelerated development and adoption of alternative storage technologies, such as lithium-ion (Li-ion) batteries and flow batteries. Stationary electricity storage can directly drive rapid decarbonisation in other key segments of energy use, such as in the transport sector where the viability of battery storage for electric vehicles (EVs) is improving fast. At the end of 2016, the cost of Li-ion batteries had fallen by as much as 73 per cent for transport applications from 2010. While Li-ion batteries in stationary applications have a higher installed cost than those used in EVs, in Germany, small-scale Li-ion battery systems have also seen their total installed costs fall by 60 per cent between the fourth quarter of 2014 and the second quarter of 2017. “The growth of lithium-ion battery use in electric vehicles and across the transport sector over the next 10 to 15 years is an important synergy that will help drive down battery costs for stationary storage applications,” said Dolf Gielen, Director of the IRENA Innovation and Technology Centre and an author of the report. “The trend towards electrified mobility will also open up opportunities for electric vehicles to provide vehicle-to-grid services, helping feed a virtuous circle of renewable energy and storage integration. “Storage technology will deliver service flexibility to the grid and electricity storage to small-scale rooftop solar applications in markets where commercial and residential electricity rates are high, and grid feed-in remuneration is declining,” concluded Mr. Gielen. By 2030, the calendar life of Li-ion batteries could also increase by approximately 50 per cent, while the number of full cycles possible could potentially increase by as much as 90 per cent. Other battery storage technologies also offer large cost reduction potential. High temperature “sodium sulphur” batteries could see their costs decline by up to 60%, while the total installed cost of flow batteries could potentially fall by two-thirds by 2030. Although they are subject to higher up-front costs compared to other technologies, flow batteries often exceed 10,000 full cycles, balancing the costs with very high lifetime energy throughputs.
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