Latest Overhead T&D Articles

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

Reliability & Protection in Utility Distribution

Reliability and protection in utility distribution are safeguarded through breakers, relays, automation, and fault isolation, ensuring grid stability, preventing outages, and providing safe, resilient power for residential, commercial, and industrial users.

What is Reliability & Protection in Utility Distribution?

Reliability and protection in utility distribution ensure safe, continuous electricity delivery by detecting faults, isolating affected areas, and restoring service efficiently.

✅ Uses relays, reclosers, and breakers to clear faults quickly

✅ Improves outage performance with automation and fault isolation

✅ Adapts to DER integration for stronger grid reliability

Part of enhancing reliability and protection in Utility Distribution involves harmonizing protection strategies with the overall network design, as discussed in our overview of electrical distribution systems.

Utility distribution is where electricity meets the customer, and its reliability depends on strong protection strategies. Faults, equipment failures, and severe weather are inevitable — but with coordinated protection, utilities can minimize outages and restore service quickly. Reliability and protection are not just technical concerns; they define the customer experience and the resilience of the modern grid. One of the key challenges to reliability in utility distribution is dealing with costly interconnection delays, which can slow down system upgrades and impact protection planning.

The Role of Protection in Reliability

In utility networks, reliability is measured through indices such as SAIDI, SAIFI, and CAIDI, which track outage frequency and duration. Behind those numbers lies a simple principle: protection devices must respond fast enough to clear faults but selective enough to avoid cutting off more customers than necessary.

Consider a radial feeder serving a rural community. A single fault along the line can interrupt service for everyone downstream. With the right combination of breakers, reclosers, and fuses, that same fault could be confined to a small segment, keeping most customers supplied while crews make repairs.

Layers of Protection in Utility Distribution

Protection in utility distribution relies on multiple devices working together:

Breakers at substations interrupt large fault currents.
Reclosers attempt to clear temporary faults and restore service automatically.
Sectionalizers detect passing fault current and open to isolate problem areas.
Fuses protect lateral branches and small loads.

The effectiveness of these devices comes from careful coordination. Each must operate in the right sequence so that the smallest possible section is taken out of service. Poor coordination risks unnecessary outages, while proper design ensures reliability. Understanding electric power distribution provides the foundation for evaluating how protection devices interact within the broader utility grid.

Comparative Roles of Protection Devices in Utility Distribution

Device	Typical Fault Response Time	Coverage Area	Reliability Impact
Breaker	Instant to a few cycles	Entire feeder circuit	Prevents catastrophic faults from spreading upstream.
Recloser	Less than 1 second, with reclosing attempts	Feeder segments	Clears temporary faults, reducing unnecessary outages.
Sectionalizer	Opens after fault current passes	Branch or loop section	Isolates smaller faulted areas, keeping most customers online.
Fuse	Seconds (melts under sustained fault)	Small branches, taps	Protects localized loads, acts as final safeguard.

Effective protection depends on critical components like the electrical insulator, which maintains safety and stability by preventing leakage currents and supporting conductors. To minimize downtime and improve service reliability, utilities often rely on monitoring devices, such as fault indicators, to pinpoint disturbances quickly.

Protection Coordination in Action

Protection is effective only when devices operate in harmony. Two common strategies are:

Fuse-saving: a recloser operates first, giving temporary faults a chance to clear before a fuse blows.
Fuse-blowing: the fuse operates on sustained faults, preventing upstream devices from unnecessarily tripping.

Modern adaptive relays now adjust thresholds dynamically. For example, when distributed energy is producing heavily, relay settings shift to account for reverse power flow.

Did you know? FLISR (Fault Location, Isolation, and Service Restoration) can reconfigure feeders in under 60 seconds. One Midwestern utility reported a 25% reduction in SAIDI after installing automated reclosers and FLISR software across its suburban service territory.

Smart Protection and Automation

Utilities are increasingly adopting automated protection schemes. Fault Location, Isolation, and Service Restoration (FLISR) technology uses sensors, communications, and smart switches to reroute power in seconds. Instead of dispatching crews to manually isolate a fault, the system reconfigures itself, reducing both outage duration and the number of affected customers.

Automation turns protection from a reactive safeguard into a proactive reliability tool. Utilities that deploy digital relays, SCADA integration, and smart switching see measurable improvements in performance, with lower SAIFI and CAIDI values across their service areas. Advances in distribution automation enable utilities to detect faults, isolate problem areas, and restore service more quickly, directly improving reliability indices such as SAIDI and SAIFI.

Impact of Protection and Automation on Reliability Indices

Reliability Index	Definition	Effect of Protection & Automation
SAIDI	Average outage duration per customer (minutes/year)	Automation reduces restoration time by rerouting power quickly.
SAIFI	Average number of outages per customer (interruptions/year)	Coordinated reclosers and sectionalizers lower outage frequency.
CAIDI	Average outage duration per interruption	Faster fault isolation and service restoration shorten each outage.

Challenges in a Distributed Era

Distributed energy resources (DERs) such as solar, wind, and storage are transforming how protection operates. Power no longer flows one way from the substation to the customer. Reverse flows can confuse traditional protection settings, while inverter-based resources may not produce fault currents large enough to trigger older devices.

To address this, utilities are deploying directional relays, adaptive settings, and advanced digital relays capable of handling bidirectional power. Protection strategies must evolve in tandem with the grid to maintain reliability as more distributed resources connect at the distribution level. The rapid growth of distributed energy resources has reshaped how utilities design protection schemes, necessitating adaptive relays and more sophisticated coordination strategies.

Barriers to Stronger Protection

Despite technological progress, several barriers remain:

Interoperability between legacy and digital equipment is often limited.
Communication networks must be robust enough to support widespread automation.
Cybersecurity is critical, as protection devices are now part of utility control systems.
Workforce skills must expand, with protection engineers learning networking and analytics alongside relay coordination.

Utilities that overcome these barriers position themselves to deliver safer and more reliable services in the decades ahead. Long-term resilience in distribution systems also depends on strong links with electricity transmission, which supplies the bulk power that distribution networks deliver safely to end users.

Reliability and protection in utility distribution are inseparable. Protection devices detect, isolate, and clear faults; reliability is the result of how well those devices are coordinated. With automation, adaptive relays, and smarter strategies, utilities can minimize outages and keep customers connected even as the grid grows more complex. In an era of distributed resources and rising expectations, robust protection is the foundation of reliable utility distribution.

Overhead T&D Channel

Transmission Lines Explained

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.

Transmission And Distribution Channel

Electricity Transmission

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.

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.

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.