- Power plants generate electricity and send it into power lines that distribute energy to nodes where it can be used.
- But if the electricity load is more than the system's capacity, transmission can fail, leading to a cascade of failures throughout the electric grid.
- Researchers show demand side control may be an effective solution to stabilizing the reliability of power grids that use a mix of energy generation sources.
Power plants generate electricity and send it into power lines that distribute energy to nodes, or sites, where it can be used. But if the electricity load is more than the system’s capacity, transmission can fail, leading to a cascade of failures throughout the electric grid.
This domino effect was responsible for the largest blackout in U.S. history in 2003, which left 55 million Americans and Canadians without power at an estimated cost of $6 billion. An even larger blackout in 2015 affected 57 million people in Italy. Blackouts cause ripple effects throughout the economies they affect, and they can be dangerous for people depending on electronics in hospitals.
In a paper published in Chaos, from AIP Publishing, the authors show demand side control may be an effective solution to stabilizing the reliability of power grids that use a mix of energy generation sources.
Pere Colet and colleagues factored the effects of demand-side management into power grids using a model to simulate the rapid fluctuations involved and tested the system under different demand loads.
The authors extended a model for the complex dynamics of blackouts in power grids to include three important factors: intraday variability (peaks in electricity demand when people wake up or come home from work), power bursts caused by simultaneous switching on of many electric devices (either by chance or by large factories), and the effect of managing demand (using devices that delay switching on until the grid is more clear) on the power grid.
“With a growing fraction of electric energy generated from wind and solar power plants, which are subject to weather changes, fluctuations will increase, and we have to consider different control approaches to balance the system,” Colet said. “Devices that are smart enough to postpone certain tasks can help. This is what is known as demand side management.”
The authors plan to continue to investigate more advanced forms of demand control, such as communication between nodes. They are also exploring models that can assess the amount of solar and wind power that can be included in grids without increasing the risk of blackouts due to fluctuations.
“The implementation of demand side management techniques may be quite helpful in preventing blackouts,” Colet said. “One important aspect is that the customers will need to be trained to respond with social responsibility to the situations of the demand and learn to adapt to the situation. That will be particularly important when renewable energy sources are in use.”
Project: “Technology of modulation of electric charges”. This device is a passive generator of alternating and direct current – an EMF element LINK. An element that converts reactive power into additional generation of direct and alternating voltage. This element completely eliminates overloading of power supply systems and reduces the coefficient of electricity costs. Non-induction electric current transformers. Elements of technical decay – a technology for the destruction of industrial and household waste (elite, “smart homes”, ecology). An element of phase transitions of jet and automobile fuel in real time liquid – gas – liquid (the element significantly reduces the aggregate kinematics of known engines, a demonstration is possible).