Latest Overhead T&D Articles

Costly Interconnection Delays

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.”

Transmission And Distribution Channel

Overhead T&D, Direct Current Technology

Direct current technology delivers efficient DC power distribution via rectifiers, converters, and power electronics, enabling microgrids, energy storage, HVDC links, photovoltaics, and electric vehicle charging with reduced losses and improved reliability.

What Is Direct Current Technology?

Direct current technology uses one-way flow and power electronics to enable efficient DC distribution and control.

✅ Unidirectional conduction for stable voltage and reduced conversion losses

✅ Power electronics: rectifiers, DC-DC converters, inverters, protection

✅ Applications: HVDC links, microgrids, EV charging, PV and battery systems

Direct current (DC) is the preferred technology for moving large amounts of power across long distances. DC results in overall higher efficiency and reliability than an equivalently-sized alternating current (AC) system moving the same amount of power.

The Advantages of DC

More efficient: Over long distances, DC transmission can move more power with less electrical losses than an equivalent AC transmission line. For foundational context on grid-scale power flows, see electricity transmission basics to understand how DC and AC corridors are planned.

Lower Cost: Higher efficiency means a lower transmission cost, helping renewable energy compete against other power sources. Advances in overhead switchgear innovation can also drive capital and operating savings across long routes.

Improved Reliability: HVDC transmission can enhance system stability, allow the operator complete control over power flow, and facilitate the integration of wind from different resource areas. These characteristics align with smart grid strategies that require precise controllability and resilience.

Smaller Footprint: DC transmission lines require narrower right-of-way footprints, using less land, than equivalent AC lines. Planning and design of overhead transmission lines further influence corridor width, clearances, and visual profile.

The major advantage of DC power lines is their efficiency—less energy is lost as it is transmitted and there is no need for reactive compensation along the line. Because DC (Direct Current) flows steadily through the wires without changing direction many times each second and through the entire conductor rather than at the surface, DC (Direct Current) transmission lines typically lose less power than AC transmission lines. By comparison, AC transmission lines must manage reactive power and frequency-related effects over distance.

How HVDC Works

Historically, the transfer of electricity between regions of the United States has been over high voltage alternating current (AC) transmission lines, which means that both the voltage and the current on these lines move in a wave-like pattern along the lines and are continually changing direction. In North America, this change in direction occurs 60 times per second (defined as 60 hertz [Hz]). The electric power transmitted over AC transmission lines is exactly the same as the power we use every day from AC outlets, but at a much higher voltage. From bulk transmission, electrical distribution systems step and route energy to neighborhoods and facilities.

Unlike an AC transmission line, the voltage and current on a direct current (DC) transmission line are not time varying, meaning they do not change direction as energy is transmitted. DC electricity is the constant, zero-frequency movement of electrons from an area of negative (-) charge to an area of positive (+) charge.

The first commercial electric power system built by Thomas Edison in the late nineteenth century carried DC electricity, but given some early advantages, AC power eventually became the primary power system in the United States. Some of these advantages are no longer applicable (e.g., technology has advanced to allow efficient conversion from AC to DC), and DC transmission is the preferred solution for moving large amounts of renewable power over long distances.

Clean Line’s HVDC transmission lines projects will deliver power from new, renewable energy resources. These resources will be AC generators, as is normally the case, and their energy will be transmitted along collector lines. These collector lines will then be connected to a substation where the power will be collected and the voltage will be transformed from the voltage of the collector lines to a common voltage (such as 345,000 volts). The power will then be converted to DC, a process known as rectification, using power electronic switches called thyristors. The power will then be transmitted several hundred miles along a set of conductors called a transmission line before getting converted back to AC, a process known as inversion, again using thyristors as the switching devices. After the DC power is converted back to AC it is transformed to the common voltage of the grid to which it is being connected (e.g. 500,000 volts or 765,000 volts, in the case of Clean Line’s projects). This power is then distributed via the interconnected grid by the local utilities to homes and businesses. See below for an illustration of this process.
Once inverted and synchronized, the power enters local power distribution for last-mile delivery and metering.

The History of DC Transmission

The development of direct current (DC) transmission dates back to the 1930’s and has been a proven technology since the first major installations in 1954. Over the last 40+ years, DC Projects have shown to offer significant electrical, economic, and environmental advantages when transporting power across long distances, where there has been a veritable boom in the use of DC to tap energy resources in remote portions of the country and bring the energy to consumers in more heavily populated areas. Among those direct current lines is the Pacific DC Intertie, which has been in operation for over 30 years. Operating at ±500 kilovolts, the line is capable of transmitting up to 3,100 MW of power. In terms of operating voltage and capacity, the Pacific Intertie is similar to the Clean Line transmission line projects, which will operate at ±600 kilovolts and deliver up to 3,500 MW of power.

Currently there are more than 20 DC transmission facilities in the United States and more than 35 across the North American grid.

Transmission And Distribution Channel

Grounding Electrode

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.

Power Quality Channel

Distribution Automation Reliability

Distribution automation enhances grid reliability, efficiency, and fault detection using smart sensors, communication networks, and control systems. It supports smart grid operations, reduces downtime, and ensures consistent, safe power delivery.

What is Distribution Automation?

Distribution automation is the application of sensors, communication networks, and control technologies to monitor and optimize power distribution systems. It improves SCADA integration efficiency, reduces outages, and enables utilities to support smart grid functionality.

✅ Improves grid reliability and fault detection

✅ Enhances efficiency through real-time monitoring

✅ Supports smart grid operations and automation

Distribution automation is a vital component of smart grid modernization, enabling utilities to create more reliable, efficient, and adaptable power networks.

The Role of Distribution Automation in Power Systems

Distribution automation is one of the most important technologies driving the modernization of transmission and distribution (T&D) grids. By integrating sensors, communication networks, control devices, and software platforms, utilities can optimize performance, manage the integration of renewable energy sources, and enhance power quality.

While DA offers tremendous benefits, it also requires significant investment in infrastructure and skilled personnel. Still, most utilities recognize that the advantages outweigh the challenges, making DA a cornerstone of smart grid development and overall grid modernization. By combining DA with coordinated automation schemes, utilities can optimize system performance across substations and feeders, thereby enhancing resilience.

How Distribution Automation Works

Distribution automation systems rely on a combination of field devices and communication links. Sensors measure parameters such as voltage, current, and equipment status, while communication networks deliver this data to control centers. Software algorithms analyze the data and trigger appropriate actions. These analytics not only guide operational decisions but also support predictive maintenance, allowing utilities to anticipate failures before they occur.

For example, if a feeder fault is detected, a DA system can remotely operate switches to isolate the problem and reroute power, restoring service to unaffected customers in seconds. This ability to detect and respond in real time minimizes downtime and enhances resilience. The success of DA depends on advanced data analytics, which transform real-time sensor data into actionable insights for operators.

Technical Applications of Distribution Automation

DA Function / Application	Technical Description	Utility Benefit	Customer Impact
Fault Detection, Isolation, and Service Restoration (FDIR/FLISR)	Automated detection of faults, isolation of faulted sections, and restoration of power to unaffected areas.	Reduces SAIDI/SAIFI indices, lowers outage duration.	Faster restoration and fewer service interruptions.
Volt/VAR Optimization (VVO)	Uses sensors, regulators, and capacitor banks to maintain voltage within optimal limits.	Improves power quality, reduces system losses, supports DER.	More stable voltage, lower energy costs.
Conservation Voltage Reduction (CVR)	Adjusts feeder voltage closer to lower operational limits without violating standards.	Reduces peak demand and overall energy consumption.	Lower electricity bills without reduced performance.
Remote Switching & Control	Intelligent electronic devices (IEDs) allow remote operation of switches and reclosers.	Improves operational flexibility, reduces truck rolls.	Faster fault response, reduced outage duration.
Distributed Energy Resource Management (DERMS)	Integrates solar, wind, and battery storage into grid operations using real-time monitoring.	Balances supply-demand, enhances renewable integration.	Reliable service even with high levels of renewable energy penetration.
Automated Feeder Reconfiguration	Real-time reconfiguration of feeder topology in response to load changes or outages.	Optimizes load flow, prevents overloads, and improves reliability.	Stable supply even during high demand or equipment failures.
Predictive Maintenance	Uses sensor data and analytics to anticipate equipment failures before they occur.	Extends asset life, reduces maintenance costs.	Fewer unplanned outages, improved service reliability.

Benefits for Utilities and Customers

Distribution automation is more than just a technical upgrade; it transforms the way utilities operate and how customers experience electric service. By creating a smarter, more responsive grid, distribution automation reduces disruptions, improves efficiency, and supports a sustainable energy future. For customers, this means fewer outages and more reliable service. Utilities must also be mindful of security, as highlighted in the DHS/FBI alert on vulnerabilities affecting critical infrastructure. Utilities must also adopt a robust grid cybersecurity strategy to safeguard DA systems from digital threats. For utilities, it means streamlined operations and the ability to meet growing energy demands without proportional increases in cost. These advantages span across operational, economic, and customer service dimensions, making DA a cornerstone of modern grid management.

Reliability: DA systems detect and respond to faults instantly, reducing the duration and frequency of outages.
Efficiency: By optimizing power flows and reducing energy losses, DA improves overall system performance.
Renewable integration: DA helps manage the variability of solar, wind, and other distributed energy resources, improving flexibility and stability.
Cost savings: A reduced need for manual inspections and faster restoration, lower utility operating expenses.

Key Components of Distribution Automation

The effectiveness of distribution automation relies on the seamless integration of multiple technologies. Each component plays a specific role, but together they form a system capable of monitoring, analyzing, and responding in real-time. Utilities rely on this integration to maintain reliability and efficiency while adapting to new demands, such as integrating renewable energy sources and increasing electrification. To function effectively, these automated distribution networks rely on interoperability, guided by standards such as IEC 61850 and IEEE 1547. Understanding these components helps explain how DA functions as the nervous system of a modern grid, continuously sensing, communicating, and adjusting to maintain stability.

Sensors – Monitor voltage, current, temperature, and equipment conditions.
Communication networks – Wired or wireless platforms that connect field devices with control centers.
Control devices – Switches, capacitors, and regulators that can be operated remotely to manage the grid.
Software platforms – Analytical tools and algorithms that process data and optimize grid operations.

Together, these elements form the backbone of automated decision-making in modern distribution systems, allowing utilities to run a more intelligent and adaptive network. Protecting distribution automation systems requires a comprehensive grid cybersecurity strategy that safeguards communication and control networks.

Reliability and Fault Detection

Fault detection and location (FDL) is a critical feature of DA. By quickly identifying and isolating faults, utilities can minimize outages and restore service faster. This capability not only enhances reliability but also boosts customer satisfaction.

Supporting Renewable Energy Integration

As more renewable energy sources connect to the grid, DA plays an increasingly important role. Variable and intermittent resources such as solar and wind require real-time monitoring and balancing. DA systems, often combined with advanced metering infrastructure (AMI), help maintain stability while supporting a sustainable energy transition.

Challenges of Implementing DA

Despite the benefits, DA adoption is not without hurdles. Utilities must invest heavily in infrastructure, train skilled personnel, and coordinate across multiple departments to ensure seamless operations. To ensure reliable operations, utilities combine DA with advanced sensor technology that enables faster fault detection and real-time system monitoring, adhering to standards such as IEC 61850 and IEEE 1547. These standards add further complexity but ensure interoperability and reliability.

One of the biggest barriers is capital investment. Deploying sensors, communication networks, and intelligent devices across a distribution system requires substantial upfront funding. Smaller utilities may struggle to justify costs without regulatory incentives or clear cost-recovery mechanisms.

Another challenge lies in interoperability. Many DA systems involve equipment from multiple vendors, and ensuring seamless communication between devices requires adherence to standards such as IEC 61850 and IEEE 1547. Without interoperability, utilities risk fragmented systems that are less reliable and harder to scale.

Cybersecurity is also a growing concern. Because DA depends on digital communication networks and remote control systems, it introduces vulnerabilities that could be exploited by malicious actors. Protecting grid data and control systems requires continuous investment in cybersecurity strategies, including encryption, intrusion detection, and workforce training.

Finally, DA requires a skilled workforce capable of designing, installing, and maintaining advanced systems. Training engineers and operators to manage new technologies adds another layer of complexity to the implementation process.

Together, these challenges highlight that while DA is essential for modernizing the grid, it demands thoughtful planning, strong governance, and ongoing investment to achieve success.

Standards Guiding Distribution Automation

The success of distribution automation depends not only on advanced technologies but also on the consistent use of industry standards. Standards act as the blueprint that ensures DA systems are safe, reliable, and interoperable across different devices, vendors, and utility networks. Without them, utilities would face compatibility issues, fragmented systems, and reduced effectiveness.

IEC 61850 – Defines communication protocols for relays, switches, and control systems.
IEEE 1547 – Establishes technical requirements for integrating distributed energy resources.
NEMA SG-3 and SG-4 – Cover requirements for substation and distribution transformers.
CIGRE WG D2.27 – Provides guidelines for fault detection and location systems.

Compliance with these standards not only promotes interoperability but also ensures that DA investments deliver measurable improvements in reliability, efficiency, and sustainability.

Distribution automation is not just a technical upgrade; it is a strategic investment in the future of reliable, efficient, and sustainable power systems. By combining sensors, communications, and intelligent controls, utilities can modernize their grids, integrate renewable energy sources, and deliver higher-quality service to their customers. Despite the upfront challenges, distribution automation is indispensable for 21st-century utilities seeking intelligent grid management and resilient automated distribution networks. As DA evolves, it plays a key role in overall grid modernization, integrating renewable resources and enhancing customer reliability.

Frequently Asked Questions

How does distribution automation differ from traditional grid management?

Traditional grid management relies heavily on manual monitoring and switching, whereas distribution automation utilizes real-time sensors, remote control devices, and automated decision-making to detect and resolve issues more efficiently with reduced human intervention.

What role does cybersecurity play in distribution automation?

Because DA relies on digital communication networks, it introduces new cybersecurity risks. Utilities must implement robust security protocols to protect control systems and data streams from potential cyber threats that could disrupt grid operations.

Can distribution automation reduce greenhouse gas emissions?

Yes. By improving efficiency and integrating renewable energy sources more effectively, DA helps utilities reduce dependence on fossil-fuel generation and lower overall carbon emissions across the power system.

Is distribution automation only for large utilities?

No. While large utilities are often first movers, municipal and cooperative utilities also benefit from DA. Scaled solutions enable smaller utilities to enhance reliability and customer satisfaction without implementing the full infrastructure all at once.

What future technologies will enhance distribution automation?

Advancements in artificial intelligence, edge computing, and predictive analytics will expand DA capabilities. These tools will enable utilities to anticipate faults before they occur and optimize grid performance with even greater precision.

Smart Grid Channel

Power Line Carrier Communication Explained

Power line carrier communication enables data transmission over electrical power lines for grid automation, SCADA telemetry, and protective relaying, using coupling capacitors, line traps, and narrowband modulation to support substation monitoring and smart grid control.

What Is Power Line Carrier Communication?

A narrowband method sending control, protection, and telemetry data over power lines using coupling and line-trap equipment.

✅ Uses coupling capacitors and line traps to inject and isolate signals

✅ Supports SCADA, teleprotection, and substation automation traffic

✅ Typically narrowband FSK/PSK; robust against high-voltage noise

Power line carrier communication (PLCC) is a vital technology for electrical professionals to understand in today's evolving energy landscape. By utilizing existing power lines for data transmission, PLCC offers a cost-effective and reliable communication solution for a wide range of applications within industrial, commercial, and institutional power systems. In transmission engineering contexts, PLCC must account for impedance characteristics of overhead transmission lines to maintain carrier signal integrity across long spans.

Let's explore the evolution of PLCC, its crucial role in smart grids, its advantages compared to alternative communication technologies, the cybersecurity challenges it faces, and its integration with SCADA systems. By understanding these key concepts, we can harness the power of PLCC to enhance the efficiency, reliability, and security of modern power systems. These concepts align closely with the principles outlined in smart grid architectures that emphasize interoperability and resilience.

Power line carrier communication has emerged as a versatile and essential technology in modern industrial, commercial, and institutional power systems. By leveraging existing electrical infrastructure for data transmission, it offers a cost-effective and reliable solution for a wide range of applications. Within utility operations, PLCC complements core power distribution practices by enabling telemetry and control without new cabling.

Evolution of PLCC in Power Distribution

Power line carrier communication has come a long way from its early days of simple signaling and control functions. Initially, it relied on narrowband carrier frequencies transmitted over high voltage power lines. To achieve this, systems employed coupling capacitors, which provide high impedance to power frequency while allowing the passage of higher carrier frequencies. This ensures that the carrier signals do not interfere with the power flow. Furthermore, wave traps, also known as line traps, were installed to prevent the carrier signals from propagating beyond the desired sections of the power line, effectively creating a trap line for the communication signals. These early systems, often employing band pass filtering to further isolate carrier signals, were primarily used for basic communication between substations and protective relaying. However, with the rise of smart grids and advanced automation needs, PLCC has evolved to encompass broadband technologies, enabling higher data rates and supporting a wider range of applications. This evolution has been driven by advancements in signal processing, modulation techniques, and the development of sophisticated PLC terminal equipment. Design considerations also differ from direct current technology where coupling, filtering, and insulation coordination require different approaches.

Applications in Smart Grids

Power line carrier communication plays a crucial role in enabling the functionalities of modern smart grids. By providing a communication backbone for various grid devices, PLCC facilitates real-time monitoring and control of the power system. This includes applications like demand response, where it enables dynamic pricing and load control to optimize energy consumption. Moreover, it supports voltage control by allowing for real-time adjustments to maintain grid stability. It also aids in fault location by providing precise information about the location of disturbances, enabling faster restoration of power supply. PLCC can also coordinate distributed energy resources such as rooftop solar and battery inverters for local balancing and protection schemes.

PLCC vs. Alternative Communication Technologies

While it offers numerous advantages, it's essential to compare it with other communication technologies used in power distribution. Wireless communication, for instance, offers flexibility and ease of deployment but can be susceptible to interference and may have limited range, potentially impacting signal to noise ratio. Fiber optic communication provides high bandwidth and security but can be expensive to install, especially in challenging terrains. Coaxial cable, while offering a balance between cost and performance, may not be as readily available as existing electrical infrastructure. However, coaxial cables play a critical role within systems themselves, as they are often used to connect the equipment to the coupling capacitors, efficiently carrying the high-frequency carrier signals with minimal loss. PLCC, with its cost-effective utilization of existing power lines, often proves to be a compelling choice, particularly for applications requiring wide coverage and reliable communication in industrial settings. At the feeder level, advancements in overhead switchgear complement PLCC by enabling faster sectionalizing and restoration decisions.

Cybersecurity Challenges and Solutions

As power line carrier communication systems become more integrated into critical power infrastructure, ensuring their cybersecurity is paramount. PLCC is vulnerable to cyberattacks that can disrupt operations, compromise data integrity, and even cause widespread power outages. To mitigate these risks, robust security measures are essential. Encryption techniques protect sensitive data transmitted over PLCC channels, while authentication mechanisms prevent unauthorized access to the system. Intrusion detection systems continuously monitor the network for suspicious activity, enabling prompt response to potential threats. By implementing these security solutions, power systems can enhance the resilience of their infrastructure against cyberattacks. As utilities deploy more critical energy storage systems, securing PLCC channels that supervise these assets becomes increasingly important.

Integration with SCADA Systems

Power line carrier communication seamlessly integrates with SCADA systems, enhancing their functionality and providing real-time data for grid monitoring and control. SCADA systems rely on communication networks to gather data from remote terminal units (RTUs) and intelligent electronic devices (IEDs) located throughout the power system. It acts as a reliable and efficient communication channel for transmitting this data to the central control center. This real-time information enables operators to monitor grid conditions, detect anomalies, and take corrective actions promptly. The integration with SCADA systems improves situational awareness, facilitates faster response times, and enhances the overall efficiency of power distribution operations. Furthermore, by utilizing PLCC for communication, SCADA systems can leverage the inherent protection offered by devices like protective relays and wave traps, enhancing the overall system reliability.

Leading Questions:

What are the core advantages?

Power line carrier communication leverages existing electrical infrastructure, making it cost-effective. It offers wide coverage, especially in remote areas, and the inherent robustness of power lines ensures reliable communication even in harsh environments.

How does it contribute to smart grids?

PLCC enables essential smart grid features like demand response, voltage control, and fault location, contributing to optimized energy consumption, grid stability, and efficient power restoration.

What are the main challenges?

Signal attenuation and noise over long distances, electromagnetic compatibility issues, cybersecurity vulnerabilities, and ensuring interoperability between different PLCC equipment are some of the challenges.

How do narrowband and broadband technologies differ?

Narrowband PLCC typically uses lower carrier frequencies and is suitable for longer distances and applications like SCADA and protection relaying. Broadband PLCC, with its higher data rates, caters to modern applications like smart metering and grid automation.

What are the future trends?

Advanced signal processing techniques, integration with IoT devices, enhanced cybersecurity measures, and applications in electric vehicle charging infrastructure are some of the future trends shaping the evolution of PLCC.

Transmission And Distribution Channel

What is a Microgrid?

A microgrid is a localized energy system that can operate independently of or in conjunction with the main grid. By integrating renewable energy, storage, and smart controls, it enhances reliability, supports sustainability, and provides backup power for critical facilities.

What is a Microgrid?

A microgrid is a self-contained power system that generates, distributes, and controls electricity locally. It is essentially a small-scale version of the grid that can function in either grid-connected or islanded mode, ensuring resilience and efficiency.

✅ Integrates renewable energy and battery storage

✅ Provides backup power during outages

✅ Enhances efficiency through smart energy management

Microgrids are gaining popularity as reliable and efficient solutions for modern energy challenges. They are increasingly valuable as the world pursues cleaner energy sources, carbon reduction, and grid modernization. By complementing smart grid infrastructure, they improve system reliability while helping communities and industries adapt to the demands of today’s evolving power networks.

What Defines a Microgrid?

At their core, microgrids are groups of interconnected loads and distributed energy resources (DERs) that are managed as a single, controllable entity. These DERs include renewable generation such as solar, wind, hydro, and geothermal, as well as conventional sources like natural gas or diesel generators. Unlike centralized generation, distributed generation enables local autonomy, reduces transmission and distribution losses, and improves resilience during grid disturbances.

A key advantage is flexibility. Through the point of common coupling (PCC), they can remain tied to the larger grid when beneficial, or disconnect instantly and operate independently when reliability is threatened. This seamless transition strengthens both grid reliability and community energy resilience.

Load Management and Demand Response

Microgrids excel at managing supply and demand in real time. By participating in demand response programs and using smart controllers, they balance intermittent renewable output with load requirements. This reduces strain on central grids, improves power quality, and supports the wider integration of renewable energy. Within broader electrical distribution systems, they also strengthen resiliency by combining renewable generation with storage.

Depending on the application, components may include generation sources, energy storage, and advanced digital control systems. Supervisory control and microgrid controllers monitor and coordinate operations, while effective distribution automation technologies enable them to transition seamlessly between grid-connected and islanded operations. This coordination ensures stability and efficiency under varying conditions.

Energy Storage and the Microgrid

Storage technologies such as batteries, flywheels, and pumped hydro are vital for maintaining energy resilience. They capture excess renewable generation and release it when demand peaks or during outages. Storage also enables black start capability, ensuring a microgrid can restart after a total grid failure. For hospitals, airports, and data centers, this reliability is crucial in preventing disruptions. Critical facilities often depend on robust critical energy storage within microgrids to ensure an uninterrupted power supply.

Traditional vs. Microgrid Operation

Traditional grids rely on centralized power plants transmitting electricity over long distances. By contrast, microgrids operate within defined boundaries, supplying electricity from diverse local sources. This decentralized design reduces transmission losses, increases efficiency, and improves protection against cascading failures.

Smart Grid Technologies and Standards

Microgrids are also becoming increasingly important due to advances in smart grid technologies and grid modernization. They improve monitoring, interconnection, and control. To ensure safe design and operation, industry standards such as IEEE 1547, IEEE 2030.7, and IEC 61850 define interconnection requirements and grid codes. These standards guide the penetration of renewable energy, demand response, and integration with broader electrical networks. Advances in direct current technology are helping DC and hybrid microgrids deliver more efficient local energy systems.

Microgrids can also play a role in improving power quality. A microgrid can help reduce the occurrence of power outages and provide a stable power source to critical loads such as hospitals, data centers, and other essential facilities.

Topologies of a Microgrid

Microgrids can be classified into topologies based on their electrical characteristics. The most common microgrid topologies are AC microgrids, DC microgrids, and hybrid microgrids.

AC Microgrid: An AC microgrid is a type that operates using alternating current (AC). It comprises a combination of renewable energy sources, conventional energy sources, and energy storage systems. AC microgrids are typically designed for larger-scale applications and can be connected to the main grid or operate in island mode.

DC Microgrid: A DC microgrid is a type that operates using direct current (DC). It comprises a combination of renewable energy sources, conventional energy sources, and energy storage systems. DC microgrids are typically designed for smaller-scale applications and can be connected to the main grid or operate in island mode.

Hybrid Microgrid: A hybrid microgrid combines both AC and DC components to form a single system. It comprises a combination of renewable energy sources, conventional energy sources, and energy storage systems. They are typically designed for larger-scale applications and can be connected to the main grid or operate in island mode.

Basic Components of a Microgrid

Microgrids have several components that generate, store, and distribute energy. The basic components in microgrids include:

Power sources can include renewable energy sources, such as solar panels, wind turbines, and hydroelectric generators, as well as conventional power sources, like diesel generators.

Energy storage systems store excess energy generated by power sources, including batteries, flywheels, and pumped hydro storage systems.

Power electronics convert the electrical characteristics of the power generated by power sources and energy storage systems to match the requirements of the loads.

Control systems regulate the flow of energy and maintain stability. They can include controllers, supervisory control, and data acquisition (SCADA) systems.

Microgrid Applications Across Sectors

Microgrids are being deployed in multiple sectors:

Community ones for resilience during extreme weather
Campus ones at universities to reduce costs and emissions
Military base ones for energy security
Critical facilities like hospitals, airports, and data centers that require uninterrupted power

Point of common coupling (PCC)

The PCC links the microgrid to the main grid, enabling resource sharing, exporting surplus energy, or islanding in the event of a fault. It ensures safe transitions and reliable operations in all modes.

Economic Considerations and ROI of Microgrids

Microgrid economics are driven by both cost savings and financial benefits. They reduce peak demand charges, allow energy arbitrage, and improve return on investment. Government incentives, tax credits, and supportive policy frameworks make projects more feasible, while long-term savings and sustainability goals strengthen their business case.

Case Studies and Future Outlook

Deployment examples include community microgrids under the New York REV initiative, university campus microgrids in California, and U.S. military base projects aimed at ensuring secure operations. These case studies illustrate the practical benefits of microgrids in real-world applications. As renewable penetration increases, microgrids will remain central to grid modernization, offering economic value, energy resilience, and sustainability.

What is a microgrid? A Microgrid represents a pivotal shift in how electricity is generated, managed, and consumed. By integrating DERs, renewable energy, storage, and advanced controls, they improve reliability, resilience, and carbon reduction outcomes. With supportive policies, strong standards, and growing demand, microgrids will continue to expand as a cornerstone of modern energy infrastructure.

Overhead T&D Channel

Distributed Energy Resources - Small Scale Power

Distributed energy resources integrate rooftop solar, battery storage, EV charging, and demand response within microgrids and virtual power plants to optimize load, enhance grid resilience, lower costs, and enable real-time, bidirectional power flows.

What Are Distributed Energy Resources?

Distributed energy resources are small-scale, grid-connected assets that generate, store, or manage electricity locally.

✅ Integrates solar PV, batteries, EVs, and demand response

✅ Enhances grid reliability, resilience, and peak-load flexibility

✅ Enables microgrids and virtual power plants for local balancing

Distributed energy resources (DERs) can benefit the power system and individual homes and businesses. DERs can increase the resiliency and reliability of the power grid, reduce greenhouse gas emissions, reduce the overall power cost, and provide power at the point of use. Several types of DERs can be used to generate electricity, including renewable energy sources like solar photovoltaic, wind power, and fuel cells, as well as energy storage systems like battery storage and combined heat and power (CHP) systems. DERs can also be used to power electric vehicles (EVs) and help to reduce greenhouse gas emissions in the transportation sector.

One of the most significant benefits of DERs is their ability to increase the resiliency and reliability of the power grid. When traditional power plants experience outages, DERs can continue to provide power to homes and businesses, reducing the impact of the outage. DERs can also help to reduce the strain on the power grid during peak demand periods, which can help to prevent blackouts and brownouts. Advanced distribution automation can coordinate DER dispatch for reliability gains.

Another benefit of DERs is their ability to reduce greenhouse gas emissions. Renewable energy sources such as solar photovoltaic and wind power do not produce carbon emissions, which can help reduce the amount of greenhouse gases released into the atmosphere. In addition, CHP systems can use natural gas to generate electricity while using waste heat to provide heating or cooling to homes or businesses. This can help reduce overall power consumption and lower carbon emissions.

Electric vehicles (EVs) are another type of DER that can help to reduce greenhouse gas emissions. EVs can be charged using renewable energy sources, which means that they can help to reduce the use of fossil fuels in transportation. In addition, EVs can also provide energy storage, which can help balance the power grid during periods of high demand.

DERs can also help to reduce the overall cost of power. Because DERs are typically small-scale, they can be less expensive to install and maintain than large-scale power plants. In addition, DERs can provide power at the point of use, which can help reduce the amount of power lost during transmission and distribution. For context, understanding power distribution helps explain how localized generation reduces network losses.

Several types of DERs can be used to generate electricity. Solar photovoltaic (PV) systems use solar panels to generate electricity from the sun's energy. Wind power systems use wind turbines to generate electricity from the wind. Fuel cells use hydrogen and oxygen to generate electricity, with water as the only byproduct.

In addition to renewable energy sources, DERs can include energy storage systems such as battery storage. Battery storage systems can store energy generated by renewable energy sources, which can be used during periods of high demand or when the renewable energy source is unavailable. Utilities often rely on critical energy storage to maintain service continuity during contingencies.

DERs can also include CHP systems, which use natural gas to generate electricity and waste heat to provide heating or cooling to homes or businesses. In addition, CHP systems can provide power at the point of use, which can help reduce the amount of power lost during transmission and distribution.

DERs can be connected to the power grid through a smart grid, which can help to monitor and manage the flow of energy. A smart grid can also help to balance the power grid during periods of high demand by using DERs to provide additional power. To learn more about the enabling technologies, see what a smart grid is and how it orchestrates DERs.

One of the most significant advantages of DERs is their small-scale nature, which allows them to be located close to where the electricity is needed, reducing transmission and distribution losses. DERs can also provide power during peak demand periods, helping to avoid the need for additional power plants or transmission lines. These local benefits accrue within electrical distribution systems where congestion and voltage constraints are most acute.

Another advantage of DERs is their ability to operate independently or in concert with other DERs as part of a microgrid. Microgrids are small-scale power systems that can work independently of the primary power grid, allowing for increased resiliency and reliability in the event of a power outage or other disruption to the power grid. Microgrids can also help to integrate DERs into the power system, providing a more flexible and efficient power system. If you are unfamiliar with the concept, explore what a microgrid is and how its islanded operations support resilience.

DERs can also help reduce the overall power cost by reducing the need for expensive transmission and distribution infrastructure. DERs can be installed and operated by individual homes and businesses, reducing the need for large-scale power plants and transmission lines. This can help reduce the overall power cost and provide more affordable power options for consumers.

However, there are also some challenges associated with DERs. One of the biggest challenges is the integration of DERs into the power grid. DERs can generate electricity intermittently, making it challenging to balance the power grid and ensure a consistent electricity supply. In addition, DERs can be located in areas where the power grid may not be able to accommodate additional power generation. This can require upgrades to the power grid and further investment in infrastructure. Projects may also face costly interconnection delays that extend timelines and budgets.

Another challenge is the need for energy storage systems to balance the power grid during high-demand or low-renewable power availability periods. Energy storage systems can be expensive, and their efficiency and reliability can vary depending on the type of technology used.

Despite these challenges, DERs have the potential to play a significant role in the transition to a more sustainable and resilient power system. By leveraging renewable energy sources and energy storage systems, DERs can help reduce greenhouse gas emissions, increase power resiliency and reliability, and reduce the overall energy cost.

What are the characteristics of distributed energy resources?

DERs are small-scale power sources that can be located close to the electricity needed. Renewable energy sources often power them, and they can be connected to the power grid or operate independently as part of a microgrid. They can also provide power during peak demand periods and help reduce the overall energy cost.

What are the benefits of distributed energy resources?

The advantages of using distributed energy resources include increased resiliency and reliability of the power grid, reduced greenhouse gas emissions, and decreased overall power cost. Disadvantages include challenges related to integration into the power grid and the need for energy storage systems to balance the power grid during periods of high demand or low renewable poweravailability.

How do distributed energy resources impact the existing power grid?

DERs can impact the existing power grid by providing additional sources of electricity during peak demand periods and reducing the strain on the power grid. However, the intermittent nature of some DERs can also create challenges in balancing the power grid and ensuring a consistent electricity supply.

What is the role of energy storage in distributed energy systems?

Energy storage plays a critical role in distributed energy systems by allowing excess energy generated by renewable power sources to be stored and used during periods of high demand or low renewable energy availability. Energy storage can also help balance the power grid and ensure a consistent electricity supply.

How are regulations and policies impacting the adoption of distributed energy resources?

Regulations and policies can impact the adoption of DERs by creating incentives for investment in DERs and promoting the integration of DERs into the power system. However, regulations and policies can also create barriers to entry for new technologies or increase the cost of implementation.

What is the future outlook for distributed energy resources, and what trends are emerging in this field?

The future outlook for DERs is promising as the demand for renewable sources and increased resiliency and reliability continue to grow. Emerging trends in this field include the use of blockchain technology to create peer-to-peer markets and the increased use of artificial intelligence and machine learning to optimize the performance of DERs.