No Renewable Systems without Millisecond Monitoring
By Phil Kreveld The brave new world of 50% power plus penetration of renewables in traditional AC grids requires reimagining legacy engineering and above all,
By Phil Kreveld The brave new world of 50% power plus penetration of renewables in traditional AC grids requires reimagining legacy engineering and above all,
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
the United States has not launched such a mission to counter the gravest threat of our time: climate change. Although a few clean-energy technologies, such as wind and solar power, have reached cost competitiveness with fossil fuels, many more urgently need advances if the world is to achieve net-zero carbon emissions—a herculean feat known as “deep decarbonization.”
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
The threat of chronic blackouts is sparking a rush to install battery backup systems as California homeowners try to avoid disruptive power cuts related to wildfires.
Given the divisions in ownerships of distribution, transmission and generation assets and the separate jurisdictions of the Energy Security Board, the Australian Energy Regulator, the Australian Energy Market Commission and the Australian Energy Market Operator there is urgent need for mandated, overall monitoring and control of the NEM.
Synchronised, GPS-based monitoring and the use of Big Data analysis is the way towards flexible AC transmission as renewable penetration continues on its seemingly unstoppable growth.
Given the divisions in ownerships of distribution, transmission and generation assets and the separate jurisdictions of the Energy Security Board, the Australian Energy Regulator, the Australian Energy Market Commission and the Australian Energy Market Operator there is urgent need for mandated, overall monitoring and control of the NEM.
Synchronised, GPS-based monitoring and the use of Big Data analysis is the way towards flexible AC transmission as renewable penetration continues on its seemingly unstoppable growth.
Given the divisions in ownerships of distribution, transmission and generation assets and the separate jurisdictions of the Energy Security Board, the Australian Energy Regulator, the Australian Energy Market Commission and the Australian Energy Market Operator there is urgent need for mandated, overall monitoring and control of the NEM.
The future of a power grid system with baseload thermal, hydro and pumped hydro, gas-fired, wind and solar farm generation, AND the fast-growing private sector of virtually exclusive solar photovoltaic (PV) generation is a vexing problem for politicians, legislators and grid operators alike.
The argument that synchronized, granular, multi-nodal information has to be the basis for any number of control paradigms is easy to support—even if, depending on initial expenditure considerations, limitations are imposed on control protocols and there is a superfluity of information.
The future of a power grid system with baseload thermal, hydro and pumped hydro, gas-fired, wind and solar farm generation, AND the fast-growing private sector of virtually exclusive solar photovoltaic (PV) generation is a vexing problem for politicians, legislators and grid operators alike.
The argument that synchronized, granular, multi-nodal information has to be the basis for any number of control paradigms is easy to support—even if, depending on initial expenditure considerations, limitations are imposed on control protocols and there is a superfluity of information.
It is well accepted that electric transformer maintenance is a key component of grid resilience. Considering the number of transformers installed across a grid, the maintenance cost savings and optimizations can be considerable. Replacement costs for LPT’s (large power transformers) can range from $1 million to $7.5 million. It is for this reason, that power grid operators, seriously consider digital twin preventative maintenance strategies.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.
Electrical power transmission systems operators investigate transitioning to a Distributed Grid without compromising system strength.
In May 2020, the Australian Renewable Energy Agency (ARENA) announced AU$490,629 in funding for transmission network operator Powerlink Queensland.
The purpose of the funding is to investigate technical, commercial, and regulatory solutions to address system strength challenges.
As renewable energy (RE) gains traction, power grid regulators and operators are scrambling to find viable solutions to prevent variable energy sources destabilizing the power grid.
Electrical power transmission systems operators investigate transitioning to a Distributed Grid without compromising system strength.
In May 2020, the Australian Renewable Energy Agency (ARENA) announced AU$490,629 in funding for transmission network operator Powerlink Queensland.
The purpose of the funding is to investigate technical, commercial, and regulatory solutions to address system strength challenges.
As renewable energy (RE) gains traction, power grid regulators and operators are scrambling to find viable solutions to prevent variable energy sources destabilizing the power grid.
Rooftop solar is already South Australia’s largest electricity generator with about 1300 megawatts of capacity involving one in every three homes. A full picture of the grid, as it stands, is the precursor to a successful transition to a resilient, distributed grid architecture. Policy makers need to give engineers the data they need if they are to expect a successful transition.