Large Data Analytics helps energy utility area by streamlining power age and arranging. Force age arranging and financial burden dispatch are the two most significant dynamic cycles in power age. Financial burden dispatch in basic terms is coordinating with power supply with the interest for energy from the framework throughout a brief timeframe at the most minimal conceivable expense subject to transmission and conveyance requirements.
Coordinating with energy organic market on the organization has consistently been a tight difficult exercise, and information investigation has a huge task to carry out by exploiting gathered energy information and progressed large information examination procedures.
Importance of Stationary Energy Storage Technologies:
Last year, solar deployments across the world were over 100 GW. Similarly, the deployment of on-shore and off-shore wind turbines is accelerating. In a given geographical area, newly deployed solar and wind capacity will be producing energy at the same time as the existing solar potential.
This can result in excess power from renewable sources, and no power is produced when the sun isn’t shining, and the wind isn’t blowing. So, the issue becomes how to capture and store this excess energy for future use. This is where energy storage technologies come to play and become a vital component of the future of power infrastructure. Learn more here.
The pattern of when and how much electricity firm produce differs from when and how electricity people consume. Renewable power sources are not flexible, meaning they cannot be dispatched when required to meet energy consumers’ ever-changing needs. While conventional power plants and interconnections will continue to be critical levers to address this challenge, energy storage systems are vital in solving this flexibility challenge. Innovations in battery technologies and reducing costs are the enablers behind the rise of stationary power storage technologies.
An energy storage system can store energy and release it in the form of power when it is needed. In most instances, a stationary energy storage system will comprise an array of batteries, an electronic control system, an inverter, and a thermal management system within an enclosure. Unlike a fuel cell that creates electricity without charging, energy storage systems require to be charged to offer electricity when needed.
Batteries and electronic control systems are at the core of how stationary energy storage systems function. Batteries are where the power is stored within the system in chemical energy, and lithium is the popular element used to store the chemical energy within batteries. Economic feasibility is one of the vital drivers of where stationary storage offerings will be adopted more quickly.
Management Of Big Data To Drive Utility Transformation:
The utility industry had been in a slow evolutionary mode since the middle of the 20th century. However, over the last 10–15 years, the pace of change has dramatically changed and much of this happening through the implementation of technology. New technologies are flowing into utilities at unprecedented rates in a variety of different ways.
The first set is the increasing presence of electric vehicles, distributed generation like wind and solar PV, and electric storage. These technologies, in addition to creating new system requirements, continue to increase the stress on already loaded feeders and low-voltage transformers. Some of these stresses are also hitting the transmission infrastructure as large wind farms with reduced capacity factors are setting new expectations in terms of transmission availability.
To combat these new stresses, a new set of technological changes is coming in the form of utility automation levels that have been rising steadily over the last few years. There are several examples of these including substation automation and distribution automation; measurement units, smart meters, Volt/ VAR control, demand response and others.
Many of the changes covered in the two sets of technologies above go under the mysterious moniker of Smart Grid. This term Smart Grid means so many different things to everyone — if you ask 3 people, it is possible to get 4 or more definitions. Regardless of what the definitions are, it represents the biggest change that is being faced by the utility industry and has the potential to change everything that we have faced in our industry. These changes are causing utility CIOs to have nightmares about the impacts to the stability and resiliency of the grid and the potential for these problems to show up on the evening news.
Not to worry, but the utility CIO does have tools available for them
This brings to us the third set — operational and semi-operational systems. Over the last 30 years, System Operations have evolved from the EMS to new systems like OMS , DMS , MDMS and the more recent movement towards Distributed Energy Management Systems (DEMS). These new technologies are also invading non-operational areas like field force automation, customer services, and online asset management — the latter in the form of condition-based inspection and maintenance.
Should we stop worrying!!! — Well, a new set of problems are now being created
While utilities always have had to deal with data, nothing could prepare them for the new onslaught of data from PMU s in transmission and the new sensors, controls and smart meters in distribution. As an example, just Smart Meters alone have moved the amount of data per residence from 12 data points per year (one per month) to multiple data points per premise every 15-minute. These incredibly large quantities of data are all sitting in their individual silos. The problem is that there is a lot of intelligence in the data and utilities are not yet taking advantage of it. Utilities are just beginning to start taking advantage of this data and drive insight to improve their own operations, provide better service to customers and deliver improved returns to shareholders — leading to the 4th set — Big data
Can we stop now??
Moving any further as if these challenges were not enough — could cause any person looking at you to act as if you just dropped in from Mars. While each area is distinct and challenging in itself, the combination has incredible potential but to deliver real value, it must also be supported by a combination of business process changes and change management. Looking at it totality, also allows the utility to prioritize their investments both from answering the question (1) WHAT — technological changes to make (2) WHERE — to make them and (3) HOW MUCH — to spend on it?
Let us look at some examples
• Asset Management: Technologies like electric vehicles and solar PV are putting hither to unknown amounts of increased stresses on the system by utilizing it in very different ways. Utilities are adding new sensors to get a better view into how these components are being used and new systems like DMS and DEMS to operate the systems, all resulting in a tremendous amount of new data that is coming into the utility all of which contains a lot of insight. A good asset manager needs to be able to tap into this information and the operational insight to drive new value out of the asset management processes specifically focused on asset health and its impact on maintenance schedules and priorities.
• Improved Outage Management and Restoration: Outages will happen but now we have sensors like smart meters which tell where they are and who is affected. Systems like OMS and DMS will allow us to understand the extent of the outage and the controls available to reroute power quickly. Distributed energy sources can allow us to identify new sources of supply that can be commandeered during storm conditions and the analysis of the data can allow us to plan systems and assets in such a way that we can reduce the outages the next time around.
• Improved Customer Service: Utility customer service for the most part was about customer billing. Now, for the first time, utilities have access to data (in this case mostly smart meter data) that can give them tremendous amount of insight on customer use of energy. Proper analysis of this data can provide insight both for better customer service but also better rate design in the future.
Utility transformation cannot happen without technology infusion of the right kind — but at the same time, technology infusion alone cannot deliver value without the utility transforming itself. For this to happen in an effective manner, IT and OT will need to work together — meaning the CIO needs to work effectively and closely with the business leads across traditional silos and the regulator also has a role to play in this. Focusing on transformation will result in better operations at the utility and improved service beyond what can be achieved through technology alone.
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