Latest Overhead T&D Articles

Transmission lines carry electrical power and RF signals with characteristic impedance, distributed parameters, attenuation, reflection, and phase velocity, enabling efficient power distribution, signal integrity, impedance matching, and low-loss, high-voltage transmission.

What Are Transmission Lines?

Transmission lines are conductors that guide power or RF signals with defined impedance to minimize loss and reflections.

✅ Distributed RLC parameters define impedance and propagation.

✅ Proper termination reduces reflections and VSWR.

✅ Used in high-voltage grids, coaxial cables, and microstrip.

Transmission lines are crucial in delivering electric power from generating stations to consumers. These vital power system components ensure that electrical energy reaches homes, businesses, and industries efficiently and safely. This article explores transmission lines' fundamentals, types, materials, and environmental impact. For a broader grid perspective, see how electricity transmission integrates generation, substations, and long-distance corridors in practice.

Types of Transmission Lines

There are two main categories of transmission lines: overhead and underground. Overhead lines, the most common type, are suspended above the ground using transmission towers. These structures facilitate electric power transportation over long distances at high voltage levels. Overhead lines are cost-effective and easy to maintain but can be visually unappealing and susceptible to weather-related damage. Utilities increasingly deploy advanced overhead switchgear innovation to improve reliability and fault isolation on exposed spans.

On the other hand, underground power cables are buried beneath the ground and are generally used in urban areas or environmentally sensitive regions. Although less prone to weather-related issues and more visually pleasing, they are more expensive to install and maintain. In dense urban networks, coordinated electrical distribution systems planning helps align cable routes with load centers and maintenance access.

Understanding the Functioning of Transmission Lines

Transmission lines are responsible for carrying electrical energy from power generation facilities to substations located near consumers. These lines consist of conductors typically made of copper or aluminum. The conductors are designed to have a specific cross-sectional area to accommodate the flow of electrical current without causing excessive power losses or overheating. For certain corridors and submarine links, modern direct current technology can lower losses and improve controllability compared with conventional AC lines.

The flow of electrical energy along transmission lines is subject to certain natural phenomena, such as electromagnetic fields, which can influence the line's performance. Engineers design transmission lines with a specific characteristic impedance to minimize these effects and ensure efficient power transmission. This parameter measures the line's opposition to alternating current (AC) flow at a particular frequency.

Minimizing Transmission Line Losses

Power losses along transmission lines are an important concern in electrical engineering. These losses occur due to the resistance of the conductors and can lead to decreased efficiency and higher operational costs. Therefore, engineers employ various techniques to minimize line losses, such as selecting low-resistance conductors, optimizing conductor size, and using higher voltage levels for long-distance power transmission. These strategies ultimately support resilient power distribution by reducing upstream transmission inefficiencies that propagate through the grid.

Materials Used in Transmission Lines

Conductors for transmission lines are commonly made of copper or aluminum, both of which offer good conductivity and mechanical strength. The choice of material depends on factors such as cost, availability, and environmental considerations. Transmission towers are typically constructed from steel or aluminum, offering strength and durability while minimizing weight. Line hardware selections often include durable glass electrical insulators to provide mechanical strength while maintaining excellent dielectric performance.

Environmental Impacts of Transmission Lines

The construction and operation of transmission lines can have significant environmental impacts. The visual effects on landscapes and the potential harm to wildlife, such as birds colliding with conductors, are key concerns for overhead lines. Electromagnetic fields produced by transmission lines have also raised concerns about potential health effects on humans, although research has not provided conclusive evidence of harm. Appropriate specification of each electrical insulator can mitigate leakage currents and flashover risks that might otherwise affect habitats and nearby communities.

In contrast, underground power distribution lines have a smaller visual impact and pose fewer risks to wildlife. However, their installation can disturb ecosystems and contribute to soil erosion. Additionally, the materials used in transmission lines and towers can have environmental consequences, such as the energy required for their production and waste materials disposal.

Comparing Underground and Overhead Transmission Lines

Both overhead and underground transmission lines have their own set of advantages and disadvantages. Overhead lines are more cost-effective and easier to maintain but are more susceptible to weather-related damage and have a greater visual impact on the environment. Underground lines offer aesthetic and environmental benefits but are more expensive to install and maintain. The choice between the two options largely depends on budget, location, and ecological considerations.

In conclusion, transmission lines are essential electrical grid components, enabling the efficient distribution of electric power across vast distances. Understanding these lines' types, materials, and environmental implications is crucial for making informed decisions about their design, installation, and maintenance. Engineers and planners can develop transmission infrastructure that balances cost, efficiency, and environmental concerns by considering all relevant factors.

Ensuring electrical energy's continued and efficient flow is paramount for modern society. The various transmission lines, such as overhead lines and underground power cables, have unique benefits and challenges. We can work towards more effective and sustainable power distribution solutions by understanding the materials used, the way transmission lines function, and the potential environmental impacts.

The role of transmission lines in the electrical grid cannot be overstated. As technology advances and our reliance on electricity grows, it is increasingly important to understand these essential components thoroughly. Through diligent research and continuous innovation, we can continue improving the efficiency and sustainability of our power systems, ensuring a reliable and secure electricity supply for generations to come.

Addressing the questions and concerns surrounding transmission lines can promote greater awareness and understanding of this vital aspect of our power infrastructure. As we seek innovative solutions for efficient power delivery, we can look forward to a future with more sustainable and environmentally friendly electrical transmission systems.

Transmission lines are an integral part of the electric power system, critical in delivering electrical energy from power generation facilities to consumers. Understanding the various aspects of transmission lines, such as their types, functioning, materials, and environmental impact, is essential for the ongoing development and maintenance of efficient and sustainable power distribution infrastructure. As we continue to advance in our understanding and innovation, the future of transmission lines promises increased efficiency, sustainability, and reliability for future generations.

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• Transmission And Distribution Channel

Critical energy storage ensures uptime with UPS systems, battery backup, and microgrids, stabilizing renewables and grid resilience through frequency regulation, peak shaving, and long-duration solutions for hospitals, data centers, and industrial facilities.

What Is Critical Energy Storage?

Systems that provide guaranteed power continuity and grid support using UPS, batteries, and microgrids.

✅ Ensures uptime for critical loads during outages

✅ Stabilizes grids via frequency regulation, peak shaving

✅ Integrates renewables with storage, UPS, and microgrids

Upgrading and deferring existing wires and substations may be the most common application of battery storage utilized for transmission and distribution. However, batteries also provide a range of solutions designed to maximize the lifetime of T&D infrastructure. Also referred to as T&D asset optimization, these energy storage systems (ESSs) are designed to enhance the efficiency and effectiveness of existing T&D assets to provide electricity in a given service territory. Ensuring that these systems are reliable is critical to the effective operation of electricity throughout a given service territory.
Navigant Research anticipates that a cumulative 35.5 GW of new energy storage will be built for critical infrastructure through 2027. Approximately 25% of this storage capacity is expected to directly address T&D issues. Mission critical installations require systems that deliver continuous electrical service with high power quality to the grid. Such installations also require facilities like large data centers, telecom operations, financial services centers, hospitals and complex manufacturing operations. This market segment is growing and can be addressed by a variety of system design topologies that can deliver high-fidelity electricity.
There exist a variety of specific drivers that have led utilities around the world to deploy ESSs to improve operations in T&D infrastructure. Local grid conditions and utility preference have a significant impact on the likelihood that storage systems will be developed to defer T&D upgrades. Specifically, there are three key issues that ESS help mitigate in this market. For readers new to system architecture, the fundamentals of power distribution help explain how storage eases bottlenecks across feeders.

Reliability
The primary driver for utilities pursuing reliability improvements—with or without energy storage—is the need to enhance the reliability of energy supply for their customers. ESSs enable this by either avoiding local outages that may originate on the feeder where an ESS is deployed or islanding the feeder and maintaining power supply for customers. Improving reliability is a concern for commercial and industrial (C&I) customers, who often place a premium on reliability as they risk significant financial losses from an outage. To understand the impact of grid outages for customers, analysts and utilities calculate the value of lost load (VOLL), which represents the cost of going without power for a certain period. For a homeowner this cost is minimal, more of an inconvenience than a major economic impact. However, for C&I buildings, the VOLL in the United States is estimated to average around US$20,000/MWh, according to a 2014 study from The Brattle Group. With the increasing cost-effectiveness of distributed energy resources and independent energy procurements allowing large companies to defect from their local utilities, maintaining reliable service is a critical concern for grid operators. In outage-prone zones, deploying a microgrid can maintain service while upstream faults are cleared.

Congestion and Curtailment
Transmission line congestion is a frequent issue faced by grid operators around the world. Transmission congestion issues can occur in both urban and rural areas and may be driven by either renewable or conventional energy generation. Congestion is caused when increased demand for electricity during peak periods outpaces the available transmission capacity. This issue is frequently the result of generation facilities being located far from load centers, with limited bandwidth to transfer energy from generation to load centers. During peak demand periods (that is, when wires heat up), congestion on transmission lines can result in insufficient energy to serve load, instability on the transmission network and increased costs for load-serving utilities. Although congestion issues on the transmission network receive the most attention, congestion can also occur on the electricity distribution system when existing infrastructure is unable to serve peak demand in each area. This situation is often exacerbated by high penetrations of variable distributed generation, such as solar PV, wherein fluctuating output leads to rapid changes in demand for electricity at the grid edge. As utilities integrate more distributed energy resources, storage can buffer variability at the grid edge.

Load Growth
Overall load growth rates have decreased or remained flat in the US and other developed economies in recent years; however, the dynamics of peak demand periods on the grid continue to evolve. Some utilities are experiencing decreasing overall load growth rates yet have increasing growth in their peak demand. Furthermore, the duration of peak demand is growing in many areas, moving from the traditional two to four-hour peak period to well over four or even eight hours in some locations. This trend is being exacerbated by the rising penetration of solar generation, particularly in hot climates. According to utility Arizona Public Service, hot summer temperatures above 100°F combined with decreasing solar generation in the evening result in six to seven-hour peaks across their system to cover air conditioning usage. Advanced smart grid controls can stretch capacity during extended peaks without immediate wire upgrades.

What Types of Technologies Fit?
There are key advanced battery technologies that have the optimal characteristics to serve critical loads in high fidelity settings. These technologies are judged by metrics including the following:

• Power and Energy Density
• Lifespan
• Cost
• Operation and Maintenance Requirements
• Physical Size/Housing Requirements

While there are several technologies that have attractive profiles across the above criteria, there are three key technologies that are poised to have a substantial impact on the backup power market.

Li-ion
Lithium ion (Li-ion) batteries have good energy and power densities, round-trip efficiency and life cycle expectations, making them particularly well-suited for power-intensive critical infrastructure applications. Li-ion batteries have emerged as the leading technology for both utility-scale and C&I energy storage applications because of their flexibility and availability through mass production, pushing them further down the experience curve than other advanced batteries. Several leading vendors—including LG Chem, Samsung SDI, Panasonic and BYD—have rapidly expanded manufacturing capabilities in recent years, contributing to the falling costs of  the technology. For project timelines, anticipating costly interconnection delays helps developers align procurement and commissioning.

Flow
Flow batteries are advantageous because they can store chemical energy for long periods of time by simply adding more tanks of liquid electrolyte. This makes them favorable for low cost, long-duration applications that require shifting of multiple hours’ worth of energy from one time of day to another. They are generally safer than Li-ion batteries as thermal management is not required. They also have little to no depletion of active materials over time, giving them greater life cycle expectancies than other battery types. This benefit is magnified by the fact that many flow batteries use inexpensive materials, vanadium being the primary exception.

Hybrid Battery/Fossil Generator
Hybrid battery-fossil fuel technology can be especially flexible as a grid or building asset and is increasingly being recognized as a tool to improve the efficiency, flexibility, and resiliency of existing fossil fueled power systems. In the same way a hybrid car uses battery storage to improve efficiency and reduce fuel consumption, an ESS integrated with conventional power can result in significant fuel savings while improving the system’s overall resiliency. Additionally, critical facilities with the need for long-duration guaranteed power (for example, 12-, 24-, or 72-hour needs) often are required by legislature to have diesel generators onsite. Pairing storage with improved overhead switchgear can further enhance fault isolation and reduce restoration times.

What Should Stakeholders Do to Prepare?
Utilities should work with vendors and project developers to offer solutions tailored to their customers’ specific needs. The most viable early projects may be smaller in capacity and specifically target a T&D issue a utility is experiencing. Smaller problems are more likely to be accepted by utilities and regulators due to the lower risk involved. Additionally, vendors should focus on providing standardized, modular systems that can be scaled to meet the required capacity for projects now and in the future. By starting small with modular systems, additional capacity can always be added as needed. Once utilities and regulators become comfortable with ESSs for T&D deferral, small modular systems will be easier to replicate in new locations and with new customers.
Storage providers need to determine how to structure their business models to take advantage of additional revenue streams while ensuring the reliability of core T&D optimization benefits. This challenge will require input and collaboration between project developers and integrators, software providers, utilities and market regulators to determine the best-fitting solutions. Storage industry stakeholders should be actively involved in ongoing regulatory processes to ensure that the full benefits of the technology are well understood.

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• Transmission And Distribution Channel

Electricity transmission delivers high-voltage power from generating stations to substations across vast electrical grids. Using transmission lines, transformers, and substations, it ensures efficient energy transfer, grid stability, and reliable service to businesses and industries.

What is Electricity Transmission?

Electricity transmission involves the bulk movement of electrical energy through high-voltage lines from power plants to substations for safe and efficient distribution.

✅ Transfers bulk power efficiently over long distances

✅ Uses transmission lines, transformers, and substations

✅ Ensures reliability, grid stability, and energy security

History and Evolution of Transmission

Early electricity networks in the late 1800s used direct current (DC), championed by Thomas Edison. However, DC was inefficient for long-distance delivery. Nikola Tesla and George Westinghouse pioneered alternating current (AC), which allowed voltage to be stepped up and down using transformers. This advantage made AC the global standard.

Since then, transmission systems have expanded to ultra-high voltage (UHV) alternating current and high-voltage direct current (HVDC) lines. Modern HVDC links connect countries across seas and continents, such as submarine cables linking offshore wind farms to mainland grids. The latest UHV lines operate at voltages up to ±1,100 kV, carrying thousands of megawatts with minimal losses. One of the biggest barriers to expanding electricity transmission capacity is costly interconnection delays, which slow down the integration of new generation projects into the grid.

Difference Between Transmission and Distribution

Transmission and distribution are distinct stages of the power grid. Transmission moves electric energy at high voltages (115 kV–765 kV) across long distances to regional substations. Distribution then lowers the voltage to safer levels for delivery to homes, schools, businesses, and factories. In short, transmission is concerned with long-distance efficiency, while distribution focuses on local access. A critical distinction within the power grid lies between high-voltage transmission and electric power distribution, which delivers electric energy to end users.

How the Power Grid Works

The power grid integrates generation, transmission, and distribution into a continuous flow of energy. Electric energy is generated and then stepped up by transformers to high voltages. Transmission lines carry this power over large areas, supported by towers and insulated conductors. Along the way, electrical substations regulate voltage, manage switching, and maintain grid reliability. Finally, local distribution networks step down the voltage for safe delivery to consumers. Reliable transmission relies on robust electrical distribution systems that work in conjunction with substations to ensure consistent power delivery.

Main Components of a Transmission System

Several critical components ensure that electricity transmission functions smoothly, each playing a unique role in maintaining efficiency, reliability, and safety across the power grid:

• Transmission lines – High-voltage conductors supported by towers or poles.

• Transformers – Devices that step up or step down voltage levels for efficiency.

• Electrical substations – Facilities that switch, regulate, and control power flows.

• Protective systems – Circuit breakers and relays that safeguard against faults.

Together, these components form the backbone of the energy infrastructure that powers modern life. Modern high-voltage networks incorporate both AC transmission lines and advanced direct current (DC) technology, each with distinct advantages for long-distance power transfer.

Why High Voltage Reduces Energy Loss

Transmission losses average between 5% and 8% of the total generated power. Losses are reduced by transmitting at higher voltages, which lowers current and minimizes resistive heating. That is why modern grids use voltages up to 765 kV AC and beyond, ensuring long-distance efficiency.

Economic and Regulatory Framework

Electricity transmission is not just an engineering system—it is also an economic and regulatory enterprise. Transmission is financed through regulated rates, where costs are recovered from consumers. Market mechanisms, such as congestion pricing and locational marginal pricing (LMP), determine the cost of transmitting energy across constrained transmission lines. Open-access rules, such as the OASIS system in the U.S., ensure fair use of transmission networks. These frameworks shape investment, grid expansion, and modernization.

Challenges and Barriers

Despite its importance, electricity transmission faces significant challenges that threaten reliability, expansion, and long-term sustainability of the power grid:

• Permitting delays and public opposition to new line projects.

• Environmental and land rights issues, especially with cross-country corridors.

• Aging infrastructure, with many lines over 40 years old.

• Cybersecurity and resilience threats, from storms to physical attacks.

Meeting climate goals will require overcoming these barriers to rapidly expand transmission capacity. As transmission systems evolve, they must adapt to accommodate distributed energy resources, including rooftop solar, wind, and battery storage.

Emerging Technologies and Future Trends

New technologies are reshaping electric power transmission, driving modernization and preparing the grid for renewable integration and long-term energy security:

• HVDC technology for long-distance and submarine interconnections.

• UHV AC and DC systems, enabling massive power transfers.

• Smart grids with sensors, automation, and real-time monitoring.

• Integration of storage and renewables to improve flexibility.

• Cross-border supergrids, which could balance renewable output between nations.

The U.S. Department of Energy’s National Transmission Planning Study estimates billions of dollars in benefits from expanding transmission, reinforcing its central role in decarbonization and resilience. Advanced distribution automation technologies are increasingly integrated with transmission networks to improve grid stability and efficiency.

Role of Electrical Substations

Electrical substations play a crucial role in electricity transmission. They act as control points where voltage is adjusted, circuits are switched, and faults are isolated. Substations also provide stability by balancing power flows, ensuring that the grid remains reliable even when demand spikes or unexpected outages occur.

Smart Grid and Grid Modernization

As demand for electrical energy grows and renewable energy sources expand, the need for grid modernization becomes more pressing. Smart grid technology integrates digital monitoring, sensors, and automated controls into the transmission network. This enables real-time adjustments, improved demand prediction, and more efficient utilization of transmission capacity. Smart grids also improve resilience by quickly isolating faults and rerouting power flows, reducing downtime for consumers.

Case Studies and Examples

One of the world’s largest transmission projects is the Zhundong–Wannan ±1,100 kV HVDC line in China, which transmits 12 GW of power over 3,000 km with minimal loss. In North America, proposals for new interstate transmission corridors often face decade-long permitting challenges, highlighting the need for technical achievement to align with regulatory approval. Supporting hardware, such as electrical insulators and glass electrical insulators, plays a vital role in preventing leakage and maintaining system reliability.

Frequently Asked Questions

What is the difference between electricity transmission and distribution?

Transmission delivers bulk high-voltage power over long distances, while distribution reduces voltage and delivers it locally.

How does the power grid work to transmit power over long distances?

By stepping up voltage at generators, sending it over transmission lines, and stepping it down at substations for distribution.

What are the main components of an transmission system?

Transmission lines, transformers, substations, and protective devices.

How do high-voltage transmission lines help reduce energy loss?

Higher voltage reduces current flow, minimizing resistive heating and cutting transmission losses.

What role do electrical substations play?

They adjust voltages, balance loads, and isolate faults to maintain reliability.

How can smart grid technology improve transmission?

By using automation, sensors, and real-time data to optimize power flows, reduce downtime, and improve efficiency.

What challenges does transmission face in the future?

Aging infrastructure, expansion delays, cybersecurity threats, and integrating renewables at scale.

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• Overhead T&D Channel

Costly interconnection delays stall grid connection for solar, wind, and storage, driven by interconnection queue backlogs, transmission constraints, lengthy permitting, and network upgrade studies, inflating project CAPEX, financing risk, and PPA timelines.

What Are Costly Interconnection Delays?

Delays in grid connection that create backlogs, raise upgrade costs, and push out timelines for energy projects.

✅ Queue backlogs extend interconnection studies and approvals

✅ Transmission constraints trigger costly network upgrades

✅ Financing and PPA milestones slip, increasing project risk

Utilities Have Found Ways To Save Time & Money

Policy debates on solar incentive and valuation make headlines across the nation, but less attention is paid to the nuts and bolts of solar installation: the interconnection process.

But the struggle there is very real. Take Hawaii, where the high queue of solar applications and slow interconnection process slowed down installations of distributed solar two years ago. Eventually the process was streamlined but it still wavers under the hefty weight of applications.

But performances by some of the busiest utilities in sunny states demonstrate that they have necessary skills to finish interconnections quickly. The new challenge lies in how to transfer those capabilities to utilities slow to catch on. These improvements also intersect with the rise of distributed energy resources, which require streamlined processes to connect efficiently.

The average time it takes from when the rooftop solar installation is finished to when the utilities gives it permission to operate increased from 28 days in 2014 to 45 days last year, according to data from a recent EQ Research survey. Longer queues can exacerbate stress on power distribution networks as crews juggle inspections, metering, and safety checks.

“It was one of the most surprising findings from the survey,” said Chelsea Barnes, EQ’s policy research manager and lead author of Comparing Utility Interconnection Timelines for Small-Scale Solar PV.

There are three overarching reasons why interconnection processes are slowing down, Barnes said.

“The number of interconnection applications is increasing, utilities are not prepared to handle more applications, and there are more applications for interconnections at parts of the distribution system near their interconnection capacities,” Barnes said.

“Many utilities are not prepared to handle the increasing volume of applications.”

Utilities interviewed by Utility Dive said there were some discrepancies in the numbers from EQ Research, which took their data set mostly from installers. But the conclusion was the same: slow interconnection queues didn’t help the growth of solar, leading those utilities to find ways to streamline the process.

For example, San Diego Gas and Electric (SDG&E) moved to online applications when it saw interconnection applications start to rise rapidly, said Amber Albrecht, a spokesperson. Digitizing applicant intake dovetails with modern distribution automation practices that reduce manual handoffs and errors.

And Pepco won the Smart Electric Power Alliance 2016 IOU of the Year Award for its online application for residential and small business customers to help trim the interconnection process, a complaint the utility faced during proceedings over its proposed merger with Exelon.

Moving to an online application process trimmed the processing time by 10 days, according to William Ellis, Pepco’s manager for demand side management and green power connections.  

And Tucson Electric Power moved an automated system called PowerClerk that enabled their staff handling applications to tackle 4,000 requests last year, said Chris Lindsey, TEP’s manager of its distribution energy resources engineering group. Such tools are hallmarks of a smarter grid, aligning utility workflows with core smart grid capabilities for visibility and rapid decision-making.

The paper outlined a series of recommendations for all stakeholders to streamline the process, but it only works if all participants are at the table.

Number Discrepancies and What They Might Mean

EQ Research numbers depended on PV installers in 62 service areas spread out in 20 states and the District of Columbia. The group targeted areas with high residential solar penetration. But the numbers are incomplete, noted the group in an email to Utility Dive.

“The report is based on installer survey responses only.  We did send a survey to each utility asking for the same data, but only a couple responded, so we relied only on the installer data,” Barnes wrote in an email to Utility Dive. “Most utilities do not have to report interconnection timelines so we could not rely on public reports, either.”

Four utilities in high solar areas responded to Utility Dive requests their interconnection numbers.

San Diego Gas & Electric reported 27,202 applications in 2015, but EQ Research only noted 6,114 in their survey. TEP was another one, reporting roughly 4,000 applications in 2015 but EQ put the number at 1,808.

Possibly the biggest discrepancy lies in Southern California Electric’s numbers. In 2015, SCE reported 56,276 applications, but EQ reported 15,327.

Part of the discrepancy is likely due to EQ's limited samples and in part could be due to differing definitions of the interconnection intervals.

For some utility officials, the numbers didn’t match the data they supplied the group.

“The numbers EQ Research attributes to TEP seem a bit high and do not match the data that we supplied them in response to their survey,” TEP Renewables Program Manager Justin Orkney told Utility Dive.

The time between submitting the application and getting the green light to operate is also shorter than what the EQ survey showed, Orkney said.

Orkney said residential approvals took between 2 days and 3 days in 2014 and 2015 and most are being handled this year on the same day they are submitted.

But that is not the whole story, he added. “For 2016, TEP is averaging 16 calendar days between when the installer tells us the project has been inspected and when the status in PowerClerk (an online portal) is updated.”

The bulk of the difference between “same day” and the “16 calendar days” reports is that permission to operate work is not officially initiated until the Authority Having Jurisdiction (AHJ) issues its permit.

Despite the discrepancies between EQ’s data set and the few utilities surveyed by Utility Dive, the conclusions drawn from the research paper do highlight potential best practices for utilities to speed up the process.

Costs and Causes of Delays

The most important conclusion pulled from the paper is how interconnection delays play a role for utilities, customers and installers.

“It is underappreciated how much these delays have slowed solar growth, caused frustration for customers and installers, and burdened the utility industry,” Barnes said.

Both SDG&E’s Albrecht and TEP’s Orkney said the costs and burden to manually process the applications were hefty until their systems were automated. But the utilities didn’t disclose those amounts.

There is also significant cost to the customer, the paper noted.

“A hypothetical customer in Connecticut who installs a 7 kW system would be deprived of more than $150 in electricity generation for every month that interconnection is delayed,” the paper reports. “Multiplied over many individual systems, the cumulative costs are considerable.”

A National Renewable Energy Lab sturdy said interconnection delays are among many soft costs that make up 64% of the price of a residential solar array. The higher the costs, the bigger the price tag for the customer. Those costs also impact installers, with delays affecting final payments, slowing down their cash flow. It can also have a ripple effect, impacting word-of-mouth advertising for both installers and utilities, according to the paper.

Despite that, many utilities still depend on manual processes, such as mail-in applications, which could delay applications up to 100 days or more.

“The lack of online systems and automation is the main source of interconnection delays that may be as high as 100 days or more, the paper reports. “The challenge in this area may be convincing decision-makers that the long-term benefits outweigh the short-term costs.”

But an efficient system to process interconnection applications is the obvious solution for tackling delays, the researchers found, leading to cost savings down the road.

“Improvements to the interconnection process typically yield cost savings for the utility,” utility staff interviewed by EQ Research added. “The more user-friendly and automated the interconnection application system is, the less staff time is needed.”

EQ Research pushed for a more transparent, integrated process that would allow applicants to track the progress of that application.

Some utilities have streamlined their process and said they have already seen fewer delays and reduced time intervals between submitting and operating. For instance, SDG&E launched its system in 2013 and allows installers to obtain their permission to operate within 24 hours.

For Pepco customers, the utility established an online portal that processes signatures and fee payments, eliminating follow-up paperwork, Ellis told Utility Dive. The utility also engineered a semi-automated technical analysis of applications, which accelerates approval for residential solar arrays, Pepco’s Stephen Steffel told Utility Dive.

Reliability Concerns

Concerns over reliability are another big issue causing some interconnection delays. In solar-heavy states like Hawaii, some distribution system circuits and feeders are near their interconnection capacities, causing utilities and regulators to worry about grid congestion. Strategically deployed critical energy storage can absorb excess generation and smooth feeders during peak PV output.

EQ’s paper acknowledges “fewer data points” on the use of grid reliability as a reason for delays. But, in some places, it has added to tensions between utilities and solar installers.

“Some PV installers believe that utilities are overly cautious in some cases, or that utilities invoke grid reliability concerns as an excuse to delay application processing,” the paper reports. “Utility staff sometimes believe that the PV industry seeks special treatment not granted to other industries.”

One way to mitigate the tension is through regulatory proceedings. Requiring utilities to provide installers with maps or information showing interconnection congestion would allow installers to work around congested system locations.

Some utilities have have already done so, offering “interactive, web-based maps that allow installers to easily identify geographic areas where new DG facilities could encounter problems receiving approval for interconnection,” the paper reports. In parallel, well-planned microgrid projects can localize reliability and defer upgrades on constrained circuits.

“It is not yet common but utilities are starting to do it,” Barnes said.

When installers have that information, they can warn customers in congested areas that approvals will take longer and would likely cost more, she added. “They also can market to customers in less congested locations on the distribution system.”

Some utilities, including PG&E, SDG&E, and National Grid, have integrated automated checks for reliability and safety issues into their application processing, the paper reports. “Checking for concerns early in the application process can save utilities and installers time and money by avoiding the cost of engineer labor to review potential concerns.”

Best Practices

Some states have implemented reporting deadlines, but those so far are less than adequate to speed up interconnections, Barnes said. Those rules lack enforcement requirements or contain other shortcomings, leaving applications stuck in the process.

“Regulators and utilities need to be forward-thinking and to prepare for the renewable energy that state policies will bring onto the grid,” Barnes said,

The paper recommended simplified and accessible online systems with standardized forms as one way to streamline the process. Other methods include collaborating with stakeholders, expediting permitting, and combining the permitting and interconnection process. Keeping consistent rules and regulations as well as firm deadlines is another recommendation. Upgrading field equipment, including modern overhead switchgear innovation, helps integrate new PV safely while controlling capital costs.

Policymakers should keep rules and regulations consistent over the long term. Deadlines should be clear and firm. Regulators should require utilities to be transparent throughout processing, make grid capacity maps or data available to installers, and provide timeline performance reports.

Utilities, regulators, and AHJs should also collaborate to improve the standardization, according to the paper. And if policymakers fail to act, utilities can voluntarily automate grid reliability and penetration data and make grid capacity maps or grid capacity data available to installers. Utilities should also facilitate advanced meter installation. Meanwhile, part of the burden lies with installers to track utility performance and make the source of their findings publicly available.

“Regulators, utilities, AHJs, installers, and customers can all benefit from the experiences and lessons learned in other jurisdictions and from communication among stakeholders, ”the paper concluded.

“Each of these industry participants can encourage and facilitate workshops, webinars, trainings, and other education and outreach activities to enable such learning experiences.”

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• Transmission And Distribution Channel

A grounding electrode is a conductive element, such as a metal rod or plate, that connects electrical systems to the earth. It safely disperses fault currents, stabilizes voltage levels, and is essential for electrical safety and code compliance.

What is a Grounding Electrode?

A grounding electrode is a vital component of any electrical system. It is a conductive element, such as a metal rod, plate, or concrete-encased rebar, that connects the electrical system to the earth.

✅ Connects electrical systems to earth to safely discharge fault currents

✅ Helps stabilize voltage and prevent equipment damage

✅ Required for electrical code compliance and personal safety

This connection safely dissipates fault currents, stabilizes voltage levels, and protects both equipment and personnel. Proper grounding is not only essential for electrical safety but is also mandated by national electrical coA grounding electrode is a vital component of any electrical system. It is a conductive element, such as a metal rod, plate, or concrete-encased rebar, that connects the electrical system to the earth. des such as NEC 250.52 and CSA standards. To better understand the broader framework behind safe grounding practices, see our overview of electrical grounding principles.

NEC-Approved Grounding Electrode Types

The National Electrical Code (NEC) outlines various types of grounding electrodes approved for use in electrical installations. These include metal underground water pipes, building steel embedded in concrete, concrete-encased electrodes (commonly referred to as Ufer grounds), ground rings, and rods or pipes driven into the earth. These different electrode types are chosen based on the installation environment and desired longevity.

• Metal water pipes must be in contact with earth for at least 10 feet.

• Concrete-encased electrodes use rebar or copper conductor at least 20 feet in length.

• Ground rods and pipes must be at least 8 feet long and meet diameter standards.

NEC standards such as grounding and bonding requirements are essential for selecting compliant materials and configurations.

Grounding Electrode Conductor (GEC) Sizing and Function

Beyond the electrode itself, the grounding electrode conductor (GEC) plays a critical role in the overall grounding system. The GEC connects the electrode to the main service panel or system grounding point. Sizing of the GEC is determined by the largest ungrounded service-entrance conductor, as outlined in NEC Table 250.66. The conductor must be adequately sized to carry fault current safely without excessive heating or damage.

• Copper GECs typically range from 8 AWG to 3/0 AWG, depending on the system size.

• Aluminum conductors may be used but require larger sizes due to lower conductivity.

• For rod, pipe, or plate electrodes, the maximum required GEC size is 6 AWG copper.

Learn how proper grounding electrode conductor sizing ensures the safe dissipation of fault currents in compliance with NEC 250.66.

Best Practices for Ground Rod Installation

Installation best practices ensure that the electrode system performs as intended. Ground rods must be driven at least 8 feet into the soil, and if multiple rods are required, they must be spaced at least 6 feet apart. Soil conditions, moisture levels, and temperature significantly impact the effectiveness of grounding systems, making proper placement and testing crucial.

• Electrodes should be installed vertically, where possible, for better conductivity.

• Ground resistance testing should confirm values below 25 ohms for single rods.

• Supplemental electrodes may be required to meet code if resistance exceeds this limit.

For deeper insight into how grounding integrates into entire system design, explore our guide on grounding systems and layout strategies.

Soil Resistivity and Its Impact on Grounding System Performance

Soil composition is a critical factor in determining the effectiveness of a grounding electrode. High-resistivity soils such as sand or gravel reduce system reliability. In such cases, chemical ground rods or deeper electrode systems may be required. Soil resistivity testing, using methods like the Wenner or Schlumberger test, can guide engineering decisions.

• Moist, loamy soil provides the best conductivity.

• Dry or frozen soil increases resistance significantly.

• Chemical rods are useful in rocky or high-resistance soils.

If you're working in areas with soil that inhibits conductivity, high-resistance grounding methods may be necessary to maintain performance.

Comparing Types of Ground Rods and Their Applications

There are several types of ground rods available, each with unique properties and applications. Hot-dip galvanized rods are cost-effective and provide reliable performance in many environments. Copper-clad rods, while more expensive, offer enhanced corrosion resistance. Stainless steel and chemical ground rods are typically reserved for specialized applications with extreme soil conditions or longevity requirements.

• Galvanized rods are economical and meet ASTM A-123 or B-633 standards.

• Copper-clad rods meet UL 467 and offer superior corrosion protection.

• Stainless steel and chemical rods are high-cost but high-performance options.

For clarification on the term itself, see our complete definition of electrical grounding and how it applies across systems.

Ensuring Electrical Code Compliance

Code compliance and product specification are essential aspects of grounding design. All rods and connectors must meet standards such as UL 467, ASTM A-123, or CSA. Installers must ensure that products ordered match specifications to avoid liabilities and safety risks. Dissimilar metals should be avoided to prevent galvanic corrosion, which can reduce system lifespan.

• Ensure product labeling matches listed standards.

• Avoid mixing copper and galvanized steel in close proximity.

• Confirm resistance-to-ground targets as part of final inspection.

Grounding System Design for Safety and Reliability

In conclusion, designing and installing an effective grounding electrode system requires a comprehensive understanding of codes, soil science, material properties, and safety considerations. Proper selection and installation of grounding components not only ensure regulatory compliance but also promote system reliability and long-term protection of assets and personnel. Additional techniques and requirements are explained in our article on understanding electrical grounding, which connects grounding electrodes to broader system safety.

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Glass electrical insulators support and separate conductors in power lines, preventing unwanted current flow. Known for high dielectric strength and durability, they resist weathering and mechanical stress, ensuring reliable performance in transmission and distribution.

What are Glass Electrical Insulators?

Glass electrical insulators are non-conductive components used in power systems to suspend and isolate energized conductors.

✅ Provide strong dielectric insulation and mechanical stability

✅ Resist environmental stress, UV exposure, and contaminants

✅ Commonly used in high-voltage transmission and distribution networks

Glass insulators are essential components in modern power systems, ensuring the safe and reliable flow of electricity from generating stations to consumers. Their role is not only to hold conductors but also to prevent leakage currents and flashovers. Understanding their properties, applications, and maintenance is crucial for utility professionals who design and operate reliable networks. To understand the role of glass electrical insulators in the grid, begin with an overview of long-distance power transmission and the planning and maintenance of transmission lines.

Comparison of Electrical Insulator Types

Dielectric and Mechanical Properties

Glass insulators excel due to their high dielectric strength, which enables them to withstand elevated voltages without breaking down. This reduces the risk of short circuits and ensures safe operation. Their performance depends on glass composition, thickness, and surface condition. Equally important is mechanical strength. Toughened glass offers high tensile resistance, withstanding conductor loads, wind pressure, and ice accumulation. These combined properties make glass insulators particularly reliable in high-voltage environments. For fundamentals and material choices that influence glass, porcelain, and polymer, review the primer on electrical insulators.

Electric Field and Creepage Distance

A key design factor is creepage distance—the surface path along the insulator that leakage current might follow. Contamination reduces creepage performance, increasing the risk of flashover. For transmission systems, the design typically requires creepage ratios of 25–31 mm/kV. Voltage distribution across insulator strings must also be balanced; otherwise, stress concentrates on certain discs. Utilities often use grading rings to improve field distribution and reduce corona. Because leakage and flashover risks grow with span length and voltage, compare insulation needs on AC transmission lines.

Failure Modes and Reliability Issues

Despite their strengths, glass insulators are not immune to failures. A well-documented phenomenon is self-blast—spontaneous shattering due to internal impurities or thermal stress. Microcracks, aging, and partial discharge can also degrade performance. While shattering does not usually cause outages—because the cap-and-pin hardware still holds—the damaged “stub” alters electrical behavior and increases stress on the remaining discs. Utilities rely on infrared thermography, UV cameras, and periodic inspection to detect defects early and avoid cascading failures.

Testing and Standards

Glass insulators undergo rigorous testing under IEC and ANSI/IEEE standards. Key tests include:

• Power-frequency withstand voltage (IEC 60383)

• Lightning and switching impulse tests

• Pollution performance tests (IEC 60507, IEC 60815)

• Mechanical tensile and bending strength tests

• Thermal cycle and aging tests

• Salt fog and dust chamber contamination tests

These assessments ensure long-term reliability under electrical, mechanical, and environmental stresses.

Applications of Glass Insulators in Different Voltage Levels

Glass insulators are widely used from low-voltage distribution to ultra-high-voltage transmission. Pin-type insulators serve lower voltages, while suspension discs—linked in strings of 10–12 discs for a 400 kV line—handle higher voltages. Strain insulators manage tensile forces at line ends and angles. Post insulators are common in substations. Each design addresses specific electrical and mechanical demands. On the distribution side, insulator selection is directly tied to topology and contamination levels, as covered in electric power distribution and deeper system design in electrical distribution systems.

Environmental Impact of Glass Insulators

Glass offers environmental advantages compared to porcelain and polymers. It is made from abundant raw materials and is 100% recyclable. Although energy-intensive to produce, its long service life and recyclability reduce its lifecycle impact. Studies also show that glass insulators maintain their surface properties over decades, thereby reducing the need for maintenance. A foundational overview of materials and construction can be found in the article on the electrical insulator.

Innovations and Coatings

Modern developments include glass insulators with hydrophobic surface coatings to improve pollution performance, hybrid assemblies combining glass and polymer, and anti-pollution profiles tailored for coastal or desert regions. These innovations extend lifespan, reduce cleaning cycles, and lower the risk of self-blast.

Case Studies and Field Experience

Long-term field studies, such as GCCIA’s evaluation of coated glass insulators after 15 years of service, report low failure rates and excellent resistance to contamination. Utilities note that visible breakage makes inspection easier than with porcelain or polymer, where hidden defects can persist unnoticed.

Economics and Market Trends

Global demand for glass insulators is increasing with the growth of renewable energy integration and transmission expansion. While initial costs are moderate, lifecycle benefits—long lifespan, low maintenance, and recyclability—make glass attractive compared to polymers that may degrade faster. Market reports indicate glass remains dominant in transmission, while polymers expand in distribution. Utilities also consider using monitoring devices, such as fault indicators, to complement insulator inspection and maintenance.

Installation and Maintenance

Proper installation ensures maximum performance. Insulators must be aligned to minimize mechanical stress and installed with the correct torque on the hardware. Best practices include live-line inspection, periodic cleaning in polluted areas, and prompt replacement of shattered units. Preventive maintenance is critical to sustaining high reliability.

Best Practices

Glass insulators combine high dielectric strength, mechanical durability, and environmental resilience. Their visible failure modes simplify inspection, while their recyclability supports sustainability goals. Challenges include weight, impact vulnerability, and risk of self-blast, but innovations and coatings are reducing these limitations. For high-voltage transmission, glass remains one of the most reliable insulator options, provided utilities follow rigorous installation, testing, and maintenance protocols. In AC networks, insulators play a vital role in supporting AC transmission lines and preventing leakage currents under high stress.

Frequently Asked Questions

What are the advantages and disadvantages of glass insulators?

Glass insulators provide high dielectric strength, long lifespan, and recyclability. Drawbacks include weight, brittleness, and susceptibility to vandalism.

What is creepage distance, and why is it important?

Creepage distance is the surface path along the insulator that leakage current can travel. Adequate creepage ensures resistance to flashover in polluted or wet environments.

What tests ensure the reliability of glass insulators?

Tests include power-frequency withstand, impulse tests, tensile and bending strength, and pollution performance under IEC 60383 and related standards.

What happens when a glass insulator shatters?

The insulator becomes a stub. The line remains mechanically intact, but electrical stress increases on adjacent discs, so damaged units must be replaced.

When should glass be chosen over porcelain or polymer?

Glass is preferred for high-voltage lines where durability, recyclability, and the ability to detect visible failures are priorities. Polymers are better suited for lightweight distribution applications or in regions with heavy salt fog.

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