Associate Professor Hemanshu Pota from UNSW Canberra is leading cutting-edge research to transform renewable energy and electric vehicle integration into the power grid, using advanced tools and real-time data for enhanced stability and efficiency.
What is a smart grid and why is it important for Australia?
Life for an electricity supplier would be a lot easier if a consumer called the power company and said, “I am going to turn on my clothes dryer, may I do so?”. This would make spinning reserves - supply that is online but not in the grid - unnecessary and prevent wasteful operations.
Smart grids are a way to achieve this with advanced metering, data analysis, and artificial intelligence. Australia’s electricity network is the longest in the world, and perhaps with the least number of users. Smart grids can reduce transmission losses and achieve a high level of renewable integration, especially suited to Australia with abundant sunshine and coastal wind.
Can you briefly explain your research on renewable energy integration for smart grids?
My research is focused on the finer aspects of renewable energy integration for smart grids. Most media reports and research are based on bulk analysis that considers only the total amount of electrical load and renewable generation.
In our finer analysis, two issues are important:
- We look at where and when energy is produced and consumed, not just the total amount.
- We study the dynamics of generation and load, like doing traffic analysis and considering the mathematics of how the cars accelerate and decelerate as compared to moving at a constant speed.
These aspects enable us to ensure that the electricity network meets all the regulatory constraints.
To continue with the traffic analogy, the bulk analysis means that we ensure enough parking spaces for all the cars in the city without considering if the roads have the capacity for those cars to go from residences to the city. Our analysis ensures that the network has enough capacity, i.e. roads, to transport power and remain stable, i.e. move traffic smoothly without increasing the risks of accidents that bring the traffic to a standstill.
Our research has found that there is a substantial difference between the bulk and finer analysis when predicting generation or electric vehicle operating or hosting capacity. The inclusion of dynamics enables us to analyse system stability and design controllers to enhance system stability for abnormal operating conditions. We have designed and demonstrated high-performance controllers that extend the operating range of generation resources for abnormal operating conditions.
How does your work contribute to the current state of renewable energy and smart grid technology?
Our work improves how renewable energy and electric vehicles are integrated into the power grid by providing advanced tools for enhancing network capacity. We develop algorithms that use data from a few key network locations to accurately predict the grid's capacity in real-time. These predictions help with smart scheduling, ensuring the grid stays stable and uses its capacity to the fullest.
Our approach is different from the traditional bulk analysis, which looks at overall data and often leads to limitations. Instead, our research uses detailed, real-time data to create more accurate and effective solutions for designing and operating smart grids. This leads to better performance and a more reliable and efficient power system.
What policy changes or regulatory frameworks do you think are necessary to support wider adoption of smart grids with integrated renewable energy?
The most important required policy changes are:
- Customer-centric solar generation export limits. This means allowing customers to export excess solar energy back to the grid without facing restrictive limits, which would encourage more households and businesses to install solar panels and contribute to the renewable energy supply.
- Flexible energy export for consumers. Enable consumers to “export” their rooftop solar to their workplace as they charge their electric vehicle. For example, if a consumer has solar panels at home and drives an electric vehicle to where they work, they should be able to use their home-generated solar power to charge their EV at their place of work. This would maximise the use of renewable energy and provide greater flexibility and convenience for consumers.
- The availability of voltage measurements from across the network and the frequency to the consumers. This would allow individual customers to participate in the ancillary service market, where they can help maintain grid stability by adjusting their energy consumption or production based on real-time grid conditions.
Would looking into the finer aspects of renewable energy integration for smart grids bring down the cost of an energy bill?
Potentially yes, a finer analysis of renewable energy integration for smart grids could help bring down the cost of an energy bill. By analysing and optimising the integration of renewable energy sources, electricity companies can improve the efficiency and capacity of the energy network. This means that the grid can handle higher amounts of renewable energy without requiring expensive upgrades or expansions, resulting in cost savings that can be passed on to consumers in the form of lower energy bills.
With a well-integrated smart grid, consumers who generate their own renewable energy, such as through rooftop solar panels, can export excess power back to the grid more efficiently.
This not only provides them with compensation from electricity companies but also reduces their dependence on grid imports, significantly lowering their energy bills. Additionally, reduced demand on the grid can lead to lower overall energy costs for all users.
What are the main challenges you have encountered in efficiently integrating renewable energy into smart grids?
The main challenge is getting sufficient information about network topology, i.e., the road map, and the mathematical models for the dynamics of the interconnection of multiple generators and loads. One way of looking at it is like the dynamics of the acceleration and deceleration of traffic as lanes merge and roads intersect.
How does your research integrate with advancements in other fields, such as energy storage, cybersecurity, or Internet of Things (IoT)?
We are developing artificial intelligence-based fine analysis with multiple scenarios of spatiotemporal distribution for hosting capacity and safe network operation. We are also developing controllers for generation devices that will result in performance much superior to synchronous generator-based systems.
Our research will maximise the use of energy storage thus minimising the capacity required for the desired smoothing of the intermittent renewable energy resources. A mix of centralised and decentralised control would minimise the risk of cyber-attacks and enable a stable operation for many different types of cyber-attacks. This approach would increase cybersecurity.