Transmission & distribution |


Thankfully, some solutions can optimise the use of the existing grid with the potential to accelerate progress and help get more from any new linear infrastructure once it is built.


Addressing grid congestion with APFC


One such solution is advanced power flow control technology, which effectively changes the reactance of the line on which it is deployed. APFC enhances the efficiency of existing grid infrastructure by dynamically managing power flows and redistributing them to alleviate congestion. By unlocking additional network capacity, APFC provides a cost-effective, time- efficient way to enhance grid performance. Moreover, this solution can be deployed within 12 to 18 months of ordering.


The effectiveness of APFC is well-documented through several high-impact installations worldwide. In fact, it is already being leveraged across four continents to increase transfer capacity between regions. The most notable examples include National Grid in the UK, Central Hudson in the USA, and Transgrid in Australia. All three demonstrate the potential of APFC and offer valuable insights into best practices for maximising grid efficiency.


In the UK, National Grid Electricity Transmission (NGET) has implemented APFC at three substations across five circuits operating at 275 and 400 kV to address congestion on


critical north-to-south power flow boundaries. This initiative was driven by both the significant growth of renewable generation in Scotland that needs to be delivered to demand centres in England and the unexpected early retirement of conventional generation plants.


By leveraging APFC, NGET redirects power from overloaded circuits to those with spare capacity, optimising power flows on its network. This approach has unlocked more than 2 GW of additional transmission capacity across three key boundaries between Scotland and Northern England. Remarkably, the first 1.5 GW of this extra capacity was achieved within two years. Moreover, when a generator closure occurred earlier than was expected, NGET demonstrated the flexibility of this solution by resizing two deployments in an even shorter timeframe. Across the Atlantic in the USA, Central Hudson is using APFC at its Hurley substation to provide series compensation on 345 kV circuits. This upgrade increased the transfer capacity of the UPNY-SENY interface in New York State by 185 MW, reducing bottlenecks in an area where heavily loaded grid assets were limiting regional power flows. The alternative option considered for this network need was a fixed series capacitor (FSC) that would have required 25% more substation space, additional site work, a $10 million higher cost, and it would not allow easy resizing. APFC avoided the need for this more disruptive and expensive alternative.


Lastly, Transgrid has implemented APFC across two 330 kV circuits in Australia, unlocking 170 MW of additional interconnection capacity between Victoria and New South Wales. This upgrade supports the transition to renewable energy as coal-fired generation is retired earlier than expected. By deploying APFC, Transgrid avoids the need for costly and environmentally disruptive infrastructure projects, such as reconductoring lines and constructing a transformer in a national park. The project resulted in roughly $170 million USD (268 million AUD) in savings, which was achieved through reduced generation dispatch costs and lower capital expenditures for connected new renewable generation in New South Wales.


Challenge and opportunity The EU’s 70% cross-border capacity interconnection requirement presents a formidable challenge. However, it also offers an opportunity to transform the European grid into a more efficient, integrated, and sustainable system. Leveraging APFC technology provides TSOs with an opportunity to accelerate progress. By combining APFC with targeted new infrastructure investments and improved bidding zone configurations, TSOs can meet cross- border capacity obligations while also delivering cleaner, more affordable, and reliable electricity — not just by the end of 2025 but for decades to come.


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For more information visit: www.franke-filter.com 32 | March 2025| www.modernpowersystems.com


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