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Advanced Steel Cores for Improved Efficiency

Reducing energy costs and combating climate change are power utilities' two most pressing priorities in a rapidly changing energy landscape. These utilities are under pressure to keep up with increasing power demands, and the current grid often needs significant upgrades to remain viable and combat load reductions, shortages and outages. They must also consider integrating renewable energy sources to work toward the United States' net-zero objectives.

Optimizing the grid is essential to overcome these challenges and move toward overall sustainability goals. Advanced steel cores are crucial to the big picture. They act as the heart of transmission lines, transformers and other critical grid infrastructure. Many utilities place them at the center of their overall infrastructural improvements due to their efficiency and resiliency benefits. 

The Need for Grid Modernization

The electric grid is one of the world's most intricate and critical infrastructures. It has powered homes and businesses for decades. New technology combined with aging infrastructure puts massive pressure on power and telecommunications providers. Today, 70% of U.S. transmission lines are over 25 years old. Grid modernization is essential to improve resilience to increasing demand. 

Efficiency is another critical concern for the grid. Climate change and rising temperatures impact power lines' ability to support increasing consumer demands. Overheating conductors and increased line losses result in more frequent shortages and complete power loss. Improved grid efficiency can reduce energy costs and support climate change.

Grid modernization means upgrading the grid's physical infrastructure, boosting transmission line efficiency and deploying advanced technologies. As we move toward our 2050 net-zero goals, grid modernization must also facilitate the integration of alternative energy sources, which rely on advanced transmission systems and new infrastructure to perform efficiently.

Optimizing advanced conductors for efficiency is an effective and achievable solution for improving the existing grid. The process begins with improving conductor design and core materials to mitigate line losses and shortages.

Understanding Advanced Steel Cores

An advanced steel core is the backbone of aluminum conductor power cables. These cables are commonly used for overhead power transmission.

ACSR cables comprise a central core of steel wires surrounded by aluminum wires. The steel core provides the necessary infrastructural strength, while aluminum is an efficient conductor for the electrical current.

These advanced cable alternatives are gaining popularity in many applications due to their significant advantages. Some common use cases for advanced steel cores include: 

  • Distribution lines: ACSR cables with advanced steel cores are crucial for distributing power to homes and businesses. Their durability and versatility allow for reliable distribution in rural and urban areas. 
  • High-voltage direct-current (HVDC) systems: The steel core plays a central role in transmitting power over long distances via HVDC systems. Its low resistance and high-strength steel core make it ideal for limiting energy loss from one location to another. 
  • Overhead power transmission: Advanced steel cores in ACSR cables are a popular overhead power transmission option. High-strength steel and low-resistance aluminum are ideal for high-tension transmission in overhead lines.
  • Renewable energy systems: ACSS's low resistance and high current carrying capacity make it perfect for use in renewable energy systems, which transmit power from the alternative energy source to the grid.

The Role of Advanced Steel Cores in Power and Telecommunications Infrastructure

The stranded steel core in power cables serves many purposes, including increasing wire strength and stiffness. It allows for more significant current flow without excessive heat, allowing utilities and power providers to meet growing demands without sacrificing efficiency through heat loss. In short, power distribution relies on steel cores for electricity pylons and transmission lines.

Advanced steel cores use innovative materials and designs to make transmission line cores more efficient. Upgrading to advanced steel cores can transform power and telecommunications infrastructure, reducing energy losses and boosting equipment longevity. Upgrades can also make infrastructural components smaller and more powerful, leading to long-term cost savings and improving overall power and telecommunications system performance.

High-tensile steel cores help to maintain the power network's availability and security. These advanced steel cores withstand various conditions while enhancing overhead power line capacity and efficiency. In grid modernization, steel reinforcement core is a cost-effective long-term choice. It increases the breaking strength of aluminum conductors by a factor of 2-3 and is resistant to thermal sag caused by various environmental conditions.

The Benefits of Advanced Steel Cores

Steel is the most used metal in the world today. It's a versatile and durable material option for many industries and applications.

The modern grid can benefit from this choice of metal more than ever. Some of the many advantages of advanced steel cores in transmission cables include:

  • Improved energy efficiency: Advanced steel cores with optimized design and materials lower core losses or energy losses within the core due to eddy current effects. These properties minimize energy losses due to heat, leading to improved overall system efficiency. 
  • Increased conductor breaking strength: Steel has a minimal increase in weight per unit length. It can withstand higher tension or stress levels without breaking. Advanced steel cores support transmission lines in various conditions, improving the grid's reliability and safety.
  • Reduced costs: Despite the upfront investment, advanced steel core reinforcement cables lower your costs in the long term. Steel has an excellent strength-to-weight ratio, meaning less material can handle more stress — ideal for long-distance power transmission. 
  • Simplified installation: Steel-reinforced conductors offer considerable flexibility. They are easier to work with during installation, allowing for faster and more efficient grid modernization. Steel cores are also less likely to break during installation than other conductor options. 
  • Enhanced durability: Advanced steel cores comprise multiple wires, lowering the chance of failure due to damage. They also have a longer life span than alternative metal options, reducing repair and maintenance costs. 
  • Higher power density: Advanced steel cores allow for increasingly compact designs, enabling higher power density in transmission lines and other components without sacrificing performance. 
  • Improved weather resistance: Climate change is expected to affect every aspect of the grid, including transmission lines. As we can expect more extreme weather, steel is an excellent choice due to its ability to withstand various environmental conditions.
  • Minimal reduction in conductor strength at high temperatures: Advanced steel cores can maintain conductor strength at temperatures exceeding 212 degrees Fahrenheit (100 degrees Celsius), making them suitable for regions prone to high outdoor temperatures. 
  • Reduced electromagnetic interference (EMI): An advanced steel core minimizes EMI, making it ideal for high-signal-quality applications. 

Advanced Steel Core Innovations for the Future

As demands on the power grid continue to intensify, utilities and manufacturers seek innovative ways to maximize new and existing infrastructure. Cutting-edge technologies and manufacturing techniques are revolutionizing the metal fabrication industry. Manufacturers are producing advanced steel cores that enhance grid performance. We can expect significant steel core innovations in the future.

Nanocrystalline and amorphous materials can significantly enhance the performance of advanced steel cores in various applications, improving strength and performance and enhancing the efficiency of transformers and other electromagnetic devices. Both nanocrystalline and amorphous materials have lower core losses than traditional steel cores, resulting in higher energy efficiency and reduced heat generation in many energy applications. 

As weather anomalies are likely to become more common, the future also holds the integration of advanced coatings and insulation materials. These advancements aim to protect steel cores from the elements while providing better heat dissipation and reliability. Thermal conductive coatings and insulation materials can prevent heat loss. Corrosion and high-temperature coatings can boost cable longevity further with additional protection from the elements. 

Grids and infrastructure are becoming increasingly sophisticated, and future innovations include smart features like sensors and monitors, which facilitate real-time diagnostics and streamline maintenance. Over time, these infrastructural changes and technological advancements will lead to a more resilient, reliable grid.

Advanced Steel Conductors as Sustainable Energy Solutions

The transition to renewable energy sources requires a rapid expansion and upgrade of existing electrical transmission systems. Wires and cables are at the heart of these systems, moving electricity from the point of generation to the end user. Advanced steel conductors are technologies that increase transmission pace at a lower cost and with less community impact. All advanced steel cores and conductors enable increased power flows while limiting heat loss.

Consumer demand for sustainable business practices is rising. Electricity generation is responsible for about one-third of U.S. carbon emissions, prompting organizations to integrate sustainability into multiple initiatives. As a result, finding energy-efficient and sustainable power transmission solutions is paramount for many organizations. Advanced steel cores and other similar innovations can reduce heat loss in energy transmission. Their longevity also means less strain in the manufacturing, as they infrequently require replacement. 

Achieving net-zero goals requires more transmission capacity within and between transmission planning regions. Advanced steel cores lead this extensive grid expansion, helping utilities and private organizations lower costs and integrate more sustainable, energy-efficient transmission solutions. 

Challenges and Considerations for Advanced Steel Core Integration

Although advanced steel core integration has considerable potential for improving grid efficiency, resilience and sustainability, utilities must still overcome several challenges to make it viable, including:

  • Upfront cost: The initial cost and potential downtime associated with large-scale upgrades are primary considerations in new projects. Despite the upfront investment, organizations can expect significant returns through reduced heat loss and increased efficiency. 
  • Regulatory compliance: Organizations must stay abreast of regulatory changes as the grid evolves to maintain compliance. They must ensure steel cores and other infrastructural changes comply with the latest regulations and environmental guidelines, balancing profitability and sustainability. 
  • Specialized expertise: Despite their ease of use, getting the most from advanced steel core integration may involve specialized training for personnel involved in maintenance and installations. 
  • Maintenance requirements: Advanced steel cores offer exceptional durability but still require regular maintenance to ensure optimal performance throughout their useful life. Providers must establish proactive maintenance schedules, protocols and advanced monitoring systems to detect and address potential issues early.
  • Seamless compatibility: Integrating advanced technology into existing infrastructure means ensuring compatibility. Providers may encounter challenges in ensuring seamless integration and reducing downtime during the transition. 
  • Environmental impact: Advanced steel cores offer significant environmental benefits, including improved energy efficiency and reduced emissions. However, their production process may still have environmental implications. Utilities must consider their entire impact during their life cycle, including sourcing, manufacturing, transportation and recycling. 

Working with experts to proactively address these challenges will equip utilities and providers to navigate the complexities of the changing energy landscape. Professionals who understand these challenges can help providers maximize the benefits of these innovative technologies while optimizing profitability and efficiency. 

Advanced Steel Cores and the Federal Energy Regulatory Commission Rule

The Federal Energy Regulatory Commission (FERC) issued a new rule in 2024 requiring regional transmission system operators to make long-term plans considering a more comprehensive range of regional transmission benefits. Transmission providers must provide 20-year plans and update them periodically to anticipate future needs.

FERC order 1920 specifically defines an advanced conductor as having an advanced steel core. A recent Idaho National Laboratory report supports this standpoint, claiming that aluminum conductor steel supported (ACSS), trapezoidal wire (TW) and ultra-high-strength steel MA5 are the ideal options for grid capacity increases. 

Like all national energy rulings, the new FERC rule strongly emphasizes sustainability. Providing cost-effective expansion of replaced transmission allows for the movement toward net zero while prioritizing grid resiliency. Current expansion operations are underway, but regional transmission must double in the next decade to meet the decarbonization targets. Connecting larger geographical areas means a more reliable and cost-effective grid. 

In short, the newly instituted FERC rule aims to expand regional transmission capacity to support the changing electricity generation mix and growing demand for electrification. Soon, FERC will improve the regional transmission planning process in the following ways: 

  • Focusing on the future: Planners and transmission providers must continually forecast future mixes and demand growth rather than rely on past data. Grid planners must implement proven best practices and plan new infrastructure to meet increasing energy demands. 
  • Considering holistic benefits: Providers should consider all the benefits of transmission holistically, including sustainability objectives. They must also evaluate a portfolio of transmission and non-transmission solutions over individual projects. 
  • Improving resource allocation: The FERC rule also ensures data-driven decision-making, improving the cost allocation process to support the fair allocation of costs. 
  • Prioritizing sustainability: The rule will enable the delivery of power from clean and more affordable energy generation, which benefits consumers while driving toward our short and long-term emissions goals. 

The release of the FERC rule helps providers stay agile in the face of changing energy demands while helping ensure U.S. homes and businesses have access to affordable and reliable electricity. 

Boost Transmission Line Efficiency With Solutions From Bekaert Power and Utilities

Staying ahead of the curve in the energy landscape is a collaborative effort, and you want to work with providers that offer innovative materials solutions to boost efficiency and maximize profitability. Bekaert Power and Utilities has more than 140 years of experience, and we're constantly innovating to meet your industry's new challenges. We take creativity beyond steel, continually expanding our competencies to ensure we can offer our customers the best possible solutions. 

As the largest independent supplier of steel wire solutions in North America, we work to fulfill your special ACSS cable requests, handling various processes under the same umbrella. Contact us to learn more and discover our safe, smart, sustainable solutions today!