Eaton – Eaton invests more than $500 million in North American manufacturing to support electrification, energy transition and digitalization across industries 

August 28, 2023
Eaton

  • Eaton continues to increase capacity for essential technologies supporting infrastructure projects including transformers
  • Investments in Texas and Wisconsin help meet surging utility demand for solutions supporting electrification, grid modernization and energy resilience

 

CLEVELAND – Intelligent power management company Eaton (NYSE:ETN) has announced significant investments in its North American manufacturing and operations to support rapidly growing demand for its electrical solutions. The company is expanding manufacturing and bolstering resilience to increase the supply of its solutions for customers in utility, commercial, healthcare, industrial and residential markets across North America. The majority of these investments will be complete in 2024 and 2025.

“Electrical infrastructure has to work harder and smarter to accelerate decarbonization and electrification. At Eaton, we’re all in on the energy transition, and our solutions are essential to reinvent the way power is distributed, stored and consumed,” said Mike Yelton, president, Americas Region, Electrical Sector at Eaton. “We’re making steady investments for our customers, distributors and employees to meet growing demand in the Americas, and there will be more to come.”

 

Eaton invests more than $500 million in North American manufacturing to support electrification, energy transition and digitalization across industries

Eaton invests more than $500 million in its North American manufacturing to meet rapidly increasing demand for the company’s electrical solutions across utility, commercial, data center, healthcare, industrial and residential markets.

 

Investments in Texas and Wisconsin increase U.S. manufacturing of essential utility solutions advancing electrification, grid modernization and energy resilience

Eaton is adding 200,000-square-feet to its Nacogdoches, Texas manufacturing facility, more than doubling its size. The project will double production capacity of Eaton’s voltage regulators to help utility customers across North America accelerate grid modernization and resilience projects. Eaton will continue to produce single-phase, pole-mount and pad-mount transformers in Texas to address the acute supply shortage for these products. The expansion will create more than 200 skilled manufacturing jobs.

The Texas expansion frees up capacity at the company’s largest Wisconsin manufacturing facility in Waukesha, where Eaton is investing in equipment to increase manufacturing of three-phase transformers for utility, data center, large commercial and industrial applications. Eaton will continue to produce regulators, including complex pole and substation voltage regulators, for utility customers in Wisconsin.

 

South Carolina facility expands manufacturing for busway products and industry-first EV charging technology

Eaton is increasing production of busway to meet rapidly growing demand for this power distribution technology used in commercial, industrial and fleet charging applications. This expansion includes Eaton’s EV charging busway, an industry-first innovation that dramatically simplifies and expedites infrastructure for fleet charging, while avoiding major infrastructure modifications. For more than 60 years, Eaton has manufactured hundreds of thousands of miles of busway in South Carolina and continues to expand manufacturing capacity regionally.

 

Increased production across the Americas region supports circuit protection and metering for homes, businesses

Eaton is increasing the manufacturing of its circuit breakers and metering for homes and commercial buildings. These investments include expanding capacity and diversifying production across various locations in the Americas region to increase the supply of its solutions for customers, enhance supply chain efficiency and boost manufacturing resilience.

 

Manufacturing growth strengthens power backbone for commercial, industrial and utility infrastructure projects

Eaton is adding capacity to increase supplies of essential power distribution equipment to support infrastructure projects across industries. The company’s most recent investments enhance its manufacturing facilities for switchgear and switchboards, which provide the power backbone for customers across the Americas.

 

Expanded distribution centers support data center, healthcare and industrial customers

Eaton is investing in the distribution capacity for its power quality products and connectivity solutions. The company recently opened its largest regional distribution center in Chicago and is expanding its distribution facility in Dallas to serve commercial, data center, industrial, healthcare and communications customers.

 

SourceEaton

EMR Analysis

More information on Eaton: See full profile on EMR Executive Services

More information on Craig Arnold (Chairman and Chief Executive Officer, Eaton): See full profile on EMR Executive Services

More information on Mike Yelton (President Electrical Sector, Americas Region, Eaton): See full profile on EMR Executive Services

 

 

 

EMR Additional Notes: 

  • Transformers (Distribution Transformers and Power Transformers):
    • A distribution transformer is the type of transformer that performs the last voltage transformation in a distribution grid. It converts the voltage used in the transmission lines to one suitable for household and commercial use, typically down to 240 volts.
    • The transformer is classified into three types based on the voltage level produced: Step down, Step up, and an isolation transformer.
    • Transformers changes from high voltage to low voltage, used in homes and businesses. The main function of this is to reduce the voltage to provide isolation between the two windings as primary and secondary. This transformer distributes electricity to remote areas generated from power plants.
    • While transformer stations are linked to high/medium-voltage transmission systems, electrical substations are designed to support and transform lower voltages.
    • Distribution transformers always operate at a load less the rated full load. Power transformers always operate at full load. Distribution transformers are designed to give maximum efficiency at 60 to 70% of the rated load. Power transformers have maximum efficiency at full load.
    • Power Transformers are used in transmission network of higher voltages for step-up and step down application (400 kV, 200 kV, 110 kV, 66 kV, 33kV) and are generally rated above 200MVA.
    • Distribution Transformers are used for lower voltage distribution networks as a means to end user connectivity. (11kV, 6.6 kV, 3.3 kV, 440V, 230V) and are generally rated less than 200 MVA.

 

  • Grid, Microgrids and DERs:
    • The power grid is a network for delivering electricity to consumers. The power grid includes generator stations, transmission lines and towers, and individual consumer distribution lines.
    • The grid constantly balances the supply and demand for the energy that powers everything from industry to household appliances.
    • Electric grids perform three major functions: power generation, transmission, and distribution.
    • A microgrid is a small-scale power grid that can operate independently or collaboratively with other small power grids. The practice of using microgrids is known as distributed, dispersed, decentralized, district or embedded energy production.
    • Smart Grid is any electrical grid + IT at all levels . Micro Grid is a group of interconnected loads and DERs (Distributed energy resources) within a clearly defined electrical and geographical boundaries witch acts as a single controllable entity with respect to the main grid.
    • Distributed energy resources (DERs) are small-scale electricity supply (typically in the range of 3 kW to 50 MW) or demand resources that are interconnected to the electric grid. They are power generation resources and are usually located close to load centers, and can be used individually or in aggregate to provide value to the grid.
    • Common examples of DERs include rooftop solar PV units, natural gas turbines, microturbines, wind turbines, biomass generators, fuel cells, tri-generation units, battery storage, electric vehicles (EV) and EV chargers, and demand response applications.
    • Distributed energy resources management systems (DERMS) are platforms which helps mostly distribution system operators (DSO) manage their grids that are mainly based on distributed energy resources (DER).
    • DERMS are used by utilities and other energy companies to aggregate a large energy load for participation in the demand response market. DERMS can be defined in many ways, depending on the use case and underlying energy asset.

 

  • Carbon Dioxide (CO2):
    • Primary greenhouse gas emitted through human activities. Carbon dioxide enters the atmosphere through burning fossil fuels (coal, natural gas, and oil), solid waste, trees and other biological materials, and also as a result of certain chemical reactions (e.g., manufacture of cement). Carbon dioxide is removed from the atmosphere (or “sequestered”) when it is absorbed by plants as part of the biological carbon cycle.
  • Decarbonization:
    • Reduction of carbon dioxide emissions through the use of low carbon power sources, achieving a lower output of greenhouse gasses into the atmosphere.

 

  • Voltage Regulator:
    • Voltage regulators (VRs) keep the voltages from a power supply within a range that is compatible with the other electrical components. While voltage regulators are most commonly used for DC/DC power conversion, some can perform AC/AC or AC/DC power conversion as well.

 

  • Busbar / Busway:
    • A busbar is a rigid piece of copper or aluminum, bolted or housed inside switchgear, panel boards, and busway enclosures used to carry large amounts of current / to distribute ac power to the rows of circuit breakers
    • Quite often, busbars have no insulation—they’re protected by a separate enclosure.
    • Busbars are the backbones for most power applications, providing the critical interfaces between the power module and the outside world.
    • They are also used to connect high voltage equipment at electrical switchyards, and low voltage equipment in battery banks.
    • Busways, or bus ducts, are long busbars with protective covers. Rather than branching from the main supply at one location, they allow new circuits to branch off anywhere along the busway. A busbar may be either supported on insulators, or wrapped in insulation.

 

  • Switchgears:
    • Broad term that describes a wide variety of switching devices that all fulfill a common need: controlling, protecting, and isolating power systems. This definition can be extended to include devices to regulate and meter a power system, circuit breakers, and similar technology.
    • Switchgear contains fuses, switches, and other power conductors. However, circuit breakers are the most common component found in switchgear.
    • Performs the function of controlling and metering the flow of electrical power in addiction to acting as interrupting and switching devices that protects the equipment from damage arising out of electrical fluctuations.
    • There are three types of switch gears namely LV (Low voltage), MV (Medium voltage) and HV (High voltage) Switchgear.
  • Circuit Breakers:
    • Mechanical electrical switch designed to protect an electrical circuit from damage caused by overcurrent/overload or short circuit. Its basic function is to interrupt current flow after protective relays detect a fault.
    • By definition a circuit breaker is an electrical safety device, a switch that automatically interrupts the current of an overloaded electric circuit, ground faults, or short circuits.
  • Fuses:
    • Single time mechanical circuit interruption in an over-current situation through fusion of a graded electrical conductor. Employed in 30KV to 100KV range.
    • Electrical safety device that operates to provide overcurrent protection of an electrical circuit. Its essential component is a metal wire or strip that melts when too much current flows through it, thereby stopping or interrupting the current.
  • ACB (Air Circuit Breakers): 
    • Uses air as insulating medium.
    • Air circuit breaker is a circuit breaker for the purpose of protecting low voltage circuit, mainly for energizing and cutting off high current
  • VCB (Vacuum Circuit Breakers): 
    • Vacuum is used as the means to protect circuit breakers.
    • Circuit breaker where the arc quenching takes place in a vacuum medium. The operation of switching on and closing of current carrying contacts and interrelated arc interruption takes place in a vacuum chamber in the breaker which is called a vacuum interrupter.
  • AIS (Air Insulated Switchgears):
    • Air is used for insulation in a metal-clad system
    • Secondary power distribution device and medium voltage switchgear that helps redistribute the power of a primary power distributor powered by a high voltage distribution transformer. AIS controls, protects and isolates electrical equipment in power transmission and distribution systems.
  • GIS (Gas Insulated Switchgears): 
    • All working components assembled under SF6 (Sulfur Hexafluoride HV Switchgears) gas-tight casing.
    • Compact metal encapsulated switchgear consisting of high-voltage components such as circuit-breakers and disconnectors, which can be safely operated in confined spaces.
  • OCB (Oil Circuit Breakers): 
    • Vapors a portion of oil to blast a jet of oil through the arc.
    • Circuit breaker which uses insulating oil as an arc quenching medium
  • Hybrid Circuit Breakers:
    • Combines Air-insulated and SF6 Gas-insulated technologies.
  • MCB (Miniature Circuit Breakers): 
    • Employed in domestic households to safeguard against overload. Rated current max. 100 A.
    • Electrical switch that automatically switches off the electrical circuit during an abnormal condition of the network means an overload condition as well as a faulty condition. Nowadays we use an MCB in a low-voltage electrical network instead of a fuse.
    • Circuit breakers have a tripping relay mechanism, while MCB has a tripping release mechanism. Circuit breakers have a high rupturing capacity, but the MCB has a low rupturing capacity. Circuit breakers are used in High Voltage systems, while MCBs are used in Low Voltage systems.
  • RCCB (Residual Current Circuit Breakers): 
    • To safeguard against electrical shock arising out of indirect contact and includes the detection of residual current such as earth leakage.
    • Current sensing device, which can automatically measure and disconnect the circuit whenever a fault occurs in the connected circuit or the current exceeds the rated sensitivity.
  • MCCB (Molded Case Circuit Breakers): 
    • Incorporates insulating material in the form of molded casing within circuit breaker. Rated current up to 2,500 A.
    • MCCB has a higher interrupting capacity, meaning it can handle larger loads than a conventional breaker. Generally, a standard breaker is used for residential and light commercial applications, while an MCCB is suitable for industrial and heavy commercial applications.
  • Disconnectors: 
    • Automatic switching device that offers specific isolating distance on the basis of specific requirements.
    • Disconnectors (also known as Isolators) are devices which are generally operated off-load to provide isolation of main plant items for maintenance, or to isolate faulted equipment from other live equipment.
  • Contactors: 
    • Works alike high-current switching systems but at higher voltage rates. Contactors can however not be utilized as disconnecting switches. Contactors are employed in 30KV to 100KV range.
    • Special type of relay used for switching an electrical circuit on or off.
    • Electrical device that is widely used for switching circuits on and off. As such, electrical contactors form a subcategory of electromagnetic switches known as relays. A relay is an electrically operated switching device that uses an electromagnetic coil to open and close a set of contacts.
  • PTCB eFuse Circuit Breaker:
    • Electronic micro fuse for DIN rail protecting electronically nominal currents below 1A to facilitate the clear detection of faults and supports precise fault localization and fast recovery. Response times are shorter compared to conventional fuse protection and the exact current value can be adjusted at any time
  • RCD (Residual Current Devices): 
    • Sensitive safety device that switches off the electricity within 10 to 50 milliseconds if there is an electrical fault. An RCD is is designed to protect against the risks of electrocution and fire caused by earth faults.
    • The difference between a circuit breaker and an RCD switch is the purpose of a circuit breaker is to protect the electrical systems and wiring in a home while the purpose of an RCD switch is to protect people from electrocution.
  • RCBO (Residual Current Breaker with Over-Current): 
    • RCDs can protect against electric shocks, residual currents, and earth faults. On the other hand, RCBOs can do what RCDs can do and protect a circuit from short circuits and overload. RCBOs are essentially a combination of MCB and RCCB.
    • An RCBO protects electrical equipment from two types of faults; residual current and over current. Residual current, or Earth leakage as it can sometimes be referred to, is when there is a break in the circuit that could be caused by faulty electrical wiring or if the wire is accidentally cut.