Summary

Switchgear is a critical component of electrical distribution systems in the United States. It refers to a combination of electrical disconnect switches, fuses, and circuit breakers that are used to control, protect, and isolate electrical equipment in power generation, transmission, and distribution. In the United States, the use of switchgear is pervasive, as it ensures the reliable and safe distribution of electricity to homes, businesses, and industries. The Electrical Generating Systems Association (EGSA) is the world’s largest organization exclusively dedicated to On-Site Power Generation. The Association is comprised of 500 companies—Manufacturers, Distributor/Dealers, Contractors/Integrators, Manufacturer’s Representatives, Consulting & Specifying Engineers, Service firms, End-Users and others—throughout the United States and around the world that make, sell, distribute and use On-Site Power generation technology and equipment, including generators, engines, switchgear, controls, voltage regulators, governors and much more. National Electrical Manufacturers Association (NEMA) is a trade association that represents electrical manufacturers in the United States. It uses a standard rating system to define the types of environments in which an electrical enclosure can be used. NEMA switchgear is rated for up to 635 volts with a continuous current main bus rating of up to 10,000 amps. The American National Standards Institute (ANSI) has standards for switchgear which are closely tied to building and safety codes. These organizations continue to drive the development of more efficient, safer, and environmentally sustainable switchgear solutions in the United States.

According to the research report "United States Switch Gear Market Overview, 2028," published by Bonafide Research, the market is anticipated to grow with more than 7% CAGR from 2023-2028. The market for switchgear in the United States is poised for substantial expansion in the coming years, driven by a confluence of factors that are reshaping the energy landscape and the electrical infrastructure within the country. One of the most prominent trends accelerating this growth is the rapid evolution of smart and advanced switchgear technologies. These innovative switchgear solutions are designed to enhance energy efficiency, ensure a more reliable power supply, and enable more effective monitoring and control of electrical systems. As the world grapples with the urgent need to address climate change and reduce carbon emissions, the integration of renewable energy sources has taken center stage. The shift towards cleaner energy generation, including wind, solar, and hydroelectric power, necessitates sophisticated switchgear systems that can efficiently manage the intermittent nature of these energy sources, ensuring smooth integration into the grid. Simultaneously, the United States is witnessing increased investments in power generation and transmission infrastructure. This investment is driven by the growing energy demands of a modern economy and the need to replace or upgrade aging electrical infrastructure. To accommodate the expanding grid and improve grid reliability, there is a growing demand for modern switchgear solutions that can handle higher voltage levels, offer better protection against electrical faults, and enable more precise control over electricity distribution. Also the development of smart grids and the increasing deployment of distributed energy resources, such as micro grids and energy storage systems, are further bolstering the demand for advanced switchgear.

In the United States, the market for switchgear systems is characterized by a diverse range of insulation technologies, with gas-insulated switchgears (GIS) and air-insulated switchgears (AIS) emerging as dominant players in the field. GIS's cutting-edge technology and extensive feature set have attracted a lot of attention and market share. These systems function very well in terms of electrical insulation and arc quenching because they use sulfur hexafluoride (SF6) or other gases as an insulating medium. Due to its compact design, GIS is the perfect option for spaces-constrained applications, like those found in industrial facilities or heavily populated urban regions. On the other hand, AIS, which relies on the surrounding air as its insulating medium, also maintains a significant market share. While AIS may not be as space-efficient as GIS, it offers a cost-effective solution for various applications, particularly in less densely populated regions where space is not a critical concern. AIS systems are known for their reliability and simplicity, making them a popular choice for a wide range of utility and industrial applications. Besides GIS and AIS, other types of switchgear insulation technologies also play a role in shaping the overall market. For instance, hybrid switchgears combine the strengths of both GIS and AIS, offering a compromise between space efficiency and cost-effectiveness. Additionally, solid insulation systems, which use solid dielectric materials instead of gases or air, have gained traction in recent years due to their environmental friendliness and safety advantages. Furthermore, as the demand for more sustainable and environmentally friendly solutions grows, there is a growing interest in eco-friendly insulating materials that are free from greenhouse gases and pose fewer environmental risks compared to traditional SF6-based GIS. This push towards eco-conscious solutions has led to research and development in the field of switchgear insulations, with a focus on alternative gases and solid dielectric materials to reduce the carbon footprint associated with these systems.

In the domain of switchgear systems, the segmentation by voltage type is a crucial aspect, with distinctions made between low, medium, and high voltage categories. Among these, low voltage switchgears have emerged as a prominent and dominant segment, commanding a significant share of the market in the United States. Low voltage switchgears, typically designed to operate at voltages up to 1,000 volts, are widely favored for their versatility and wide-ranging applications. They find extensive use in residential, commercial, and industrial settings, where the need for electrical distribution, protection, and control is ubiquitous. These switchgears are the cornerstone of countless everyday electrical applications, from power distribution in residential buildings to safeguarding industrial equipment. Their user-friendly and space-efficient designs, along with a multitude of protective features, make them an integral component of modern electrical infrastructure. Medium voltage switchgears, which typically operate in the voltage range of 1,000 to 35,000 volts, also hold a significant share in the market. These systems play a crucial role in power distribution networks, renewable energy installations, and various industrial applications. Their robust design and enhanced safety measures make them indispensable for managing the challenges associated with medium voltage power distribution, ensuring reliable and efficient electricity supply. High voltage switchgears, typically designed for voltages exceeding 35,000 volts, constitute another vital segment of the market. These systems are fundamental in the transmission and distribution of electricity over long distances, linking power generation facilities to substations and, eventually, to end consumers. High voltage switchgears are engineered to withstand the demands of high-voltage applications, providing essential protection against electrical faults and ensuring the safe and reliable flow of electricity across the grid.

In the realm of switchgear systems, the market segmentation based on installation methods is a pivotal aspect, distinguishing between outdoor and indoor installations. Among these categories, outdoor installations have emerged as a prominent and influential player, capturing a noteworthy share of the market in the United States. Outdoor switchgear installations are designed to withstand the rigors of the external environment, making them vital components in various applications such as utility substations, power generation facilities, and large industrial complexes. These installations are known for their durability, resistance to environmental factors, and ease of access for maintenance and servicing. Their ability to function efficiently under diverse weather conditions and challenging outdoor settings is particularly valuable, especially in sectors where the continuity of power supply is mission-critical. Indoor installations, while not as dominant as their outdoor counterparts, also secure a significant market share. These switchgear systems are typically situated within buildings, factories, and facilities where space constraints or environmental considerations necessitate an indoor setup. Indoor installations are essential for applications such as data centers, commercial buildings, and industrial plants, where the proximity to sensitive equipment or the need for a controlled environment makes indoor switchgear solutions an ideal choice. Their design focuses on optimizing space usage, reducing exposure to environmental factors, and providing enhanced safety features to protect personnel and equipment from electrical hazards.

In the comprehensive report on switchgear applications, one of the key segmentation criteria is based on the end-users, and it divides the market into four distinct categories; Transmission & Distribution Utilities, Industries, Commercial & Residential, and Other End Users. Among these categories, Transmission & Distribution Utilities emerge as the primary and most significant users of switchgear systems. These utilities are the backbone of our electrical infrastructure, responsible for transmitting and distributing electricity from power generation sources to end consumers. Switchgear systems are critical components within this sector, ensuring the efficient and reliable flow of electricity while safeguarding against faults and disruptions in the power grid. The robust and high-performance nature of switchgear solutions is paramount in this context, enabling utilities to maintain the stability and integrity of the electrical supply. Following closely, the industrial sector also represents a substantial application base for switchgear systems. Industries encompass a wide range of sectors, from manufacturing and process industries to heavy machinery and automation. Switchgear systems in industrial settings are vital for ensuring the safety of electrical equipment, personnel, and processes. They help protect critical machinery, regulate power distribution, and facilitate fault detection, thereby optimizing operational efficiency and reducing downtime. Additionally, commercial and residential end-users play a noteworthy role in the switchgear market. In commercial buildings, switchgear systems help manage electrical loads efficiently, enhance electrical safety, and support power distribution within complex infrastructures. In residential settings, they are employed for circuit protection and the distribution of electricity, ensuring the safe and reliable supply of power to homes. Lastly, "Other End Users" contribute to the market by covering various sectors and applications in data centers, healthcare facilities, transportation, and more.

Considered in this report:
• Geography: United States
• Historic year: 2017
• Base year: 2022
• Estimated year: 2023
• Forecast year: 2028

Aspects covered in this report:
• United States Switchgear market with its value and forecast along with its segments
• Various drivers and challenges
• On-going trends and developments
• Top profiled companies
• Strategic recommendation

By Insulation:
• Gas Insulated Switchgears
• Air Insulated Switchgears
• Other Insulated Switchgears

By Voltage Level:
• Low-voltage Switchgears
• Medium-voltage Switchgears
• High-voltage Switchgears

By Installation:
• Indoor Installation
• Outdoor Installation

By End-User:
• Transmission & Distribution Utilities
• Industries
• Commercial & Residential
• Other End Users

The approach of the report:
This report consists of a combined approach of primary as well as secondary research. Initially, secondary research was used to get an understanding of the market and list out the companies that are present in the market. The secondary research consists of third-party sources such as press releases, and annual reports of companies, analyzing the government-generated reports and databases. After gathering the data from secondary sources primary research was conducted by making telephonic interviews with the leading players about how the market is functioning and then conducting trade calls with dealers and distributors of the market. Post this we have started doing primary calls to consumers by equally segmenting consumers into regional aspects, tier aspects, age groups, and gender. Once we have primary data with us we started verifying the details obtained from secondary sources.

Intended audience:
This report can be useful to industry consultants, manufacturers, suppliers, associations & organizations related to the Switchgear industry, government bodies, and other stakeholders to align their market-centric strategies. In addition to marketing & presentations, it will also increase competitive knowledge about the industry.

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