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Edison Machine Works

The Edison Machine Works was an American manufacturing company founded by inventor in 1881 as a to produce dynamos, large electric motors, and related components essential for his direct-current electric illumination system. Initially located at Goerck Street in , the company operated a factory focused on designing, testing, and assembling equipment to power incandescent lamps in homes and businesses, supporting Edison's vision of widespread electrification. Incorporated as a corporation in January 1884, the works expanded by absorbing the Electric Tube Company and Edison Shafting Manufacturing Company in late 1885, enhancing its production capabilities for electrical infrastructure. In 1886, amid growing demand, Edison relocated the facility to Schenectady, New York, where it became a hub for dynamo manufacturing used in both isolated plants and central power stations, contributing to the rollout of Edison's DC-based systems across the United States. Notable figures associated with the company included engineer Nikola Tesla, who briefly worked there in 1884 before departing to develop alternating-current technology. The company's dynamos played a pivotal role in early commercial electrification, powering installations like the in 1882 and enabling rural lighting plants that remained in use into the mid-20th century. In 1889, it merged with other Edison enterprises, including the Edison Lamp Company and Bergmann & Company, to form the Edison General Electric Company, which later consolidated with in 1892 to create the . This evolution marked the transition from Edison's experimental ventures to a major industrial powerhouse in the electrical industry.

Founding and Early Years

Establishment and Purpose

The Edison Machine Works was established in late February 1881, with the formalized around March of that year, marking a pivotal step in commercializing Thomas Edison's electrical innovations. The company was organized as a primarily between Edison, who provided 90% of the initial capital, and his close associate Charles Batchelor, who contributed the remaining 10%; John Kruesi soon joined as a key partner and assistant manager. To launch operations, the partners leased the facilities of the former Etna Iron Works at 104 Goerck Street in , , a site strategically located near the for efficient material transport. This setup represented Edison's transition from experimental invention to large-scale industrial production, building on his earlier development of the and related technologies. The core purpose of the Edison Machine Works was to manufacture dynamos, large electric motors, and essential components for the Edison and power system, enabling the deployment of centralized electric illumination networks. By September 1881, the works began shipping its first dynamos, fulfilling the need for reliable equipment to support commercial electric lighting installations. This focus addressed the limitations of outsourced production, allowing Edison to control quality and scale amid growing demand for his holistic electric system, which integrated , , and consumption technologies. From its inception, the Machine Works faced significant early challenges, particularly in rapidly scaling operations to meet the ambitious timeline for the , New York's first central power station, which opened in September 1882. Production ramped up dramatically to meet demands, straining resources and supply chains for materials like iron and . Management issues, including internal kickbacks and logistical hurdles in , compounded these difficulties, yet the works successfully delivered the necessary equipment, powering an initial 400 lamps at and laying the groundwork for broader .

Initial Facilities in Manhattan

The Edison Machine Works commenced operations by leasing the former Etna Iron Works at 104 Goerck Street in in March 1881 from owner John Roach, a shipbuilder. This existing iron structure was adapted for electrical manufacturing, including investments for building refurbishments and installing specialized equipment, such as machine tools suited for casting, machining, and assembly of dynamos and related components. The adaptation leveraged the site's prior capabilities in heavy ironwork to support the rapid production of electrical apparatus. The facility spanned a 200-foot on Goerck Street and underwent expansion in the summer of with the addition of a four-story storage building to accommodate growing inventory and operations. Equipment installation focused on enabling efficient , culminating in the shipment of the first complete dynamo in September 1881. Workforce recruitment began modestly but expanded swiftly to meet needs, reaching a peak of approximately 800 employees by the mid-1880s, drawn from skilled machinists and laborers in the area. Key site-specific operations at the Goerck Street facility involved the assembly and rigorous testing of early prototypes for Edison's electric illumination system prior to the September 1882 demonstration. This included testing engine-dynamo units—each weighing around 30 tons and rated for 1,200 lamps—starting with the first full assembly on , 1882, as well as of voltage regulators and automatic indicators using galvanometers and test batteries of 1,000 lamps. These activities ensured reliability for the central station's six dynamos before their installation. Logistically, the location offered advantages through its proximity to the docks, facilitating the import of raw materials like and and the of finished to domestic and sites via . The urban setting also positioned the works near key project sites, such as the about a mile away, streamlining coordination for prototype delivery and .

Operations and Expansion

Manufacturing Processes

The manufacturing processes at Edison Machine Works, established in 1881 at 104 Goerck Street in , centered on the production of dynamos and related electrical components essential for Thomas Edison's (DC) illumination systems. These processes adapted techniques from traditional to electrical fabrication, emphasizing precision to ensure compatibility with low-voltage DC distribution. By mid-1881, the facility was equipped with approximately $125,000 worth of specialized machinery, enabling scalable output for commercial applications. The core workflow began with raw material preparation in the on-site , where metals such as iron and were cast into foundational components like frames and housings for . These castings underwent using lathes and other tools adapted for electrical parts, shaping armatures, cores, and shafts to exact tolerances required for DC generation. Coil-winding equipment, often modified from existing industrial lathes, was then employed to wrap insulated wire around armatures, creating the electromagnetic fields necessary for dynamo operation. Following winding, components were assembled in dedicated shops, involving the integration of field magnets, commutators, and wiring harnesses. Final quality testing occurred in a specialized Testing Room, where workers verified electrical , insulation , and overall performance under load conditions to prevent failures in interconnected systems. Worker training was integral to maintaining precision, particularly for assembly tasks that demanded compatibility with Edison's DC-based networks operating at 110 volts. New hires and skilled machinists received hands-on instruction in the Testing Room, focusing on setup, wiring techniques, and repair protocols to minimize in field installations. This training extended to handling specialized tools, ensuring consistent output amid rapid expansion; by summer , the workforce had grown to around 800 employees, supporting efficient operations. A key innovation was the adoption of methods to meet urgent demands, such as the six "Jumbo" dynamos—each a 27-ton, 100-kilowatt unit—manufactured for the Pearl Street Station. These batches, reaching rates of 15-20 smaller K-type dynamos per week by mid-, allowed parallel processing of castings and assemblies while addressing supply chain challenges for materials like wire and insulation. Such efficiencies not only enabled the station's initial operation but also scaled production for broader Edison electric systems.

Relocation to Schenectady

By the mid-1880s, the Edison Machine Works in Manhattan faced significant challenges, including overcrowding at its Goerck Street facility, which limited expansion, and escalating labor unrest, culminating in a major strike by the Knights of Labor in May 1886 over demands for union recognition, overtime pay, shop rules, and an end to the contract labor system. These issues, combined with high land and labor costs in New York City—where daily wages exceeded those in upstate areas—prompted Thomas Edison to seek a new location offering cheaper labor (around $1.45 to $2.25 per day), access to skilled workers less prone to agitation, ample space, low taxes, and proximity to transportation networks like the Erie Canal and railroads. In June 1886, Edison selected an 8-acre site in Schenectady, New York, the former McQueen Locomotive Works in the Mill Pasture area, a triangle-shaped property between Kruesi Avenue and the canal featuring two unfinished factory buildings. The acquisition was finalized on June 26 for $45,000, with Edison securing a personal loan of that amount from Drexel, Morgan & Co., supplemented by a $7,500 subscription from local Schenectady businessmen to meet the seller's price after Edison's initial $37,500 offer. The relocation logistics commenced that fall, involving the transfer of machinery, tools, and select personnel from amid temporary operational disruptions as the strike's aftermath lingered and workers were reshuffled. Approximately 300 skilled and loyal employees were incentivized to relocate with promises of stable employment and rapid growth, while others were dismissed to avoid ongoing labor tensions; production resumed at the new site by early October 1886, utilizing the existing structures for immediate operations. Charles Batchelor oversaw much of the transition, adapting the unfinished buildings despite risks like potential flooding from the nearby canal. Following the move, the Schenectady facility underwent swift expansions, including new construction to house additional machinery and support the of dynamos and motors for Edison's expanding central power stations across the , increasing production capacity from hundreds to thousands of units annually. These developments lowered operational costs through cheaper resources and labor, while boosting Schenectady's local economy by creating hundreds of jobs initially—projected to reach 1,000 within three years—and attracting further industry, which helped double the city's population to over 22,000 by 1892 and established it as an emerging manufacturing hub known as the "Electric City."

Key Personnel and Workforce

Leadership and Management

The Edison Machine Works was incorporated in in 1884 as a manufacturing entity to produce dynamos and related electrical equipment, with Thomas A. Edison serving as president, Charles Batchelor as treasurer and general manager responsible for technical oversight, John Kruesi as assistant manager overseeing production supervision, and as secretary handling financial and administrative duties. This structure formalized the partnership established in 1881, enabling centralized control over operations amid the burgeoning demand for Edison's electric lighting systems. Batchelor, a longtime Edison associate, coordinated engineering and facility decisions, while Kruesi, an experienced , ensured efficient execution; Insull, meanwhile, managed accounts, shipments, and integration with other Edison enterprises. Edison, as primary inventor and director, contributed design inputs and strategic direction but delegated day-to-day management to avoid operational entanglements, focusing instead on at his laboratories. His majority ownership—providing 90% of initial —ensured alignment with broader goals, yet this hands-off approach placed significant responsibility on the executive team to navigate the company's expansion. Management faced substantial challenges in coordinating rapid growth during the electric light boom of the , including cash shortages that required Insull to advance personal funds for payroll, frequent design modifications from Edison, and delays in supplier deliveries such as engines. Patent enforcement became critical to protect amid rising competition, with leadership overseeing legal efforts to safeguard dynamos and motors against infringement. Supplier relations were strained by the need for reliable components to meet surging orders, complicating production timelines. Additionally, grew tense as the workforce expanded to 800 employees by summer 1882, culminating in a 1886 strike in that prompted relocation planning. Administrative milestones included budgeting for facility expansions, such as the initial $42,500 investment for the Schenectady move, funded through reinvested profits and local to support scaling operations. Insull's oversight of financial strategies emphasized , while Batchelor and Kruesi handled negotiations with workers and suppliers to maintain amid the workforce's growth and pressures. These efforts sustained the company's output through 1889, despite ongoing challenges in and market dynamics.

Notable Employees and Contributions

Francis R. Upton served as a key lead at Edison Machine Works, where he optimized dynamo efficiency through detailed calculations and design improvements for electric generators. His mathematical expertise enabled the development of more effective armatures and field magnets, contributing to higher output in the company's manufacturing processes. Upton's work on dynamo efficiency, including computations for the "standard dynamo machine," helped achieve operational efficiencies that supported the scaling of in the early 1880s. Upton also played a pivotal role in advancing parallel circuit designs, which were tested and refined at the works to ensure compatibility with factory-produced dynamos and motors. These designs allowed for safer and more scalable distribution of , directly influencing the assembly and testing of electrical components at the facility. By verifying the feasibility of parallel wiring through rigorous , Upton's contributions facilitated smoother of Machine Works outputs into broader Edison electric systems. Nikola Tesla joined the Edison Machine Works in 1884 as an electrical engineer, where he worked on improving the design and efficiency of direct-current dynamos. During his brief six-month tenure, Tesla proposed enhancements to the company's dynamo technology, though disagreements with Edison over compensation and technical direction led to his departure. He subsequently focused on developing alternating-current systems, marking a pivotal shift in . William J. Hammer emerged as a prominent testing and installation expert during the early operations of Edison Machine Works, focusing on validating the performance of dynamos and before field deployment. As chief involved in experimental tests, Hammer ensured that factory-built equipment met reliability standards, linking production quality to successful on-site implementations. His expertise in handling early electric systems helped troubleshoot issues in installations, such as those for central stations, thereby enhancing the reputation of Machine Works products. The workforce at Edison Machine Works included a diverse group of skilled , many from backgrounds, whose precision craftsmanship was instrumental in electrical assembly. John Kruesi, a -born and later assistant general manager, exerted significant influence by training apprentices and overseeing the machine shop, instilling high standards of accuracy derived from European watchmaking traditions. This emphasis on skilled labor and hands-on apprenticeships built a core of expertise in fabricating complex components like motor housings and parts, supporting the company's expansion. Employee-driven innovations, particularly in assembly techniques and tooling, led to notable improvements in efficiency during the mid-1880s. These gains were attributed to collaborative efforts among engineers and machinists, enabling the works to meet growing demand for Edison's electric systems without proportional increases in labor costs.

Products and Technological Role

Dynamos and Electric Motors

The Edison Machine Works primarily manufactured direct current (DC) dynamos and large electric motors as core components of Thomas Edison's electric lighting and power systems. These dynamos, designed for generating , featured bipolar and multipolar configurations to meet varying power needs. The bipolar models, such as the early Z-type dynamo, were characterized by tall, narrow vertical iron pieces supporting the field magnets, earning the nickname "long-waisted Mary Ann" due to their slender, elongated appearance. Armatures in these dynamos consisted of drum-shaped cores wound with copper wire to produce a , while field coils—also copper-wound around soft iron cores—provided the necessary excitation for DC output. Larger multipolar dynamos, with multiple pairs arranged more compactly around the armature, were developed as "short-waisted" variants to handle higher capacities without excessive height, allowing for capacities up to 600 sixteen-candlepower lamps per unit. These dynamos were steam-driven, directly coupled to Porter-Allen high-speed steam engines, and incorporated iron cores to concentrate and windings for efficient current conduction. Efficiency rates reached over 80% in the Z-type models, approaching the theoretical limit for contemporary generators by minimizing resistive losses in the windings and optimizing commutation. For the in , the Machine Works produced six massive "" dynamos, each rated at about 100 kilowatts and capable of powering around 1,200 lamps, marking a significant scale-up in production for commercial central stations. By , output had expanded dramatically, reflecting rapid adoption of Edison's systems. Complementing the dynamos, the Machine Works developed DC electric motors for industrial applications, designed to operate on the same 110-volt systems. These motors featured similar construction principles, including laminated iron cores for the and , copper windings for torque generation, and commutators for DC compatibility, enabling seamless integration with Edison's power distribution networks. Production of these motors scaled alongside dynamos, as demand grew for electrified equipment.

Contributions to Edison's Electric Systems

The Edison Machine Works played a pivotal role in the operationalization of Thomas Edison's () electric lighting system by manufacturing and supplying the essential generating equipment for the inaugural commercial central at Pearl Street in . Established in , the works produced all six "Jumbo" dynamos—each weighing approximately 27 tons and capable of powering around 1,200 incandescent lamps—that were installed at the station, which commenced operations on , 1882, initially powering around 400 lamps in 59 buildings within Manhattan's financial district. These dynamos, along with associated electric motors for auxiliary functions, formed the core of the station's infrastructure, enabling the distribution of power through an of copper conductors to support Edison's high-resistance incandescent bulbs. Beyond Pearl Street, the Machine Works extended its contributions to the broader deployment of Edison's electric infrastructure, supplying dynamos and motors for shipboard installations and urban power grids. Building on the 1880 prototype electric lighting system installed aboard the SS Columbia—the first commercial application of Edison's technology—the works manufactured equipment for subsequent maritime adaptations, demonstrating the versatility of DC systems in mobile environments. In urban settings, the facility provided generators for expanding networks in and international projects, including the Holborn Viaduct station in , which began operation in January 1882 as the world's first coal-fired public using Edison's design. These outputs facilitated the scaling of electric service to commercial and residential users, powering thousands of lamps in growing districts. The works also produced models such as the smaller K dynamos and L dynamos for isolated lighting plants. The Machine Works also advanced key innovations through its dedicated testing facilities, which validated wiring configurations critical to Edison's subdivided distribution system. By simulating full-scale in a controlled environment, engineers at the works refined wiring methods that allowed multiple high-resistance lamps to operate independently on circuits, minimizing and failure risks while substantially reducing material costs compared to series systems. This testing not only ensured reliability for incandescent scalability but also trained personnel in system and , bridging the gap between Edison's patents and practical deployment. Economically, the works generated substantial — with dynamos under valued at over $350,000 by mid-1882—through sales to the Edison Electric Illuminating and licensees, thereby funding ongoing while addressing bottlenecks for large-scale production.

Merger and Legacy

Formation of Edison General Electric

In 1889, Thomas Edison's various electric enterprises underwent a significant consolidation when the Edison General Electric Company was incorporated in on April 24, merging key manufacturing and patent-holding entities including the Edison Machine Works, the Edison Lamp Company, Bergmann & Company, and the Edison Electric Light Company. This merger unified Edison's fragmented operations under a single corporate umbrella capitalized at $12 million in stock. The primary motivations for this restructuring were to streamline manufacturing processes, centralize control over production and , and bolster competitiveness against emerging (AC) systems promoted by rivals like George Westinghouse's company, which threatened Edison's (DC) dominance during the intensifying "War of the Currents." The new organizational structure preserved the , facility—established earlier as the relocated base for the Edison Machine Works—as the primary manufacturing hub, enabling expanded national distribution of electric equipment. served as chairman and president of the consolidated entity, providing visionary leadership, while , Edison's trusted secretary and business manager, assumed the role of vice president with significant responsibilities in financial operations and administration. This setup facilitated patent pooling across the merged companies, protecting innovations in DC-based lighting and power systems from infringement. Among the immediate outcomes, the merger enhanced production capacity by integrating resources and expertise, allowing for scaled output of dynamos, lamps, and related components to meet growing demand in urban electrification projects. However, Edison's personal involvement began to wane shortly thereafter, as his focus shifted toward other pursuits like ore milling, compounded by internal tensions over the viability of technology amid the escalating AC-DC rivalry, which ultimately diluted his day-to-day influence in the company's strategic decisions.

Transition to General Electric

In 1892, the Edison General Electric Company, which encompassed the Edison Machine Works, merged with the to form the (), a consolidation orchestrated by financier through his firm Drexel, Morgan & Co. to streamline the fragmented electrical industry and enhance profitability. The new entity was capitalized at $50 million, making it one of the largest industrial mergers in U.S. history at the time, with the stock distribution favoring Thomson-Houston shareholders. Thomas Edison, who had already lost significant control during the 1889 formation of Edison General Electric, exited active leadership roles following the merger; while he served on GE's board for a decade, providing patent and consulting support, the presidency went to from Thomson-Houston, marking Edison's shift away from corporate management toward independent invention. The Schenectady facilities of the former Edison Machine Works played a pivotal role in GE's early structure, serving as the company's and evolving into a cornerstone of its operations. Incorporated in but centered in Schenectady, GE's 600-acre campus there expanded rapidly, incorporating the original Machine Works buildings into a vast industrial complex that by the early housed major production lines for generators, motors, and turbines, while also emerging as a hub for . This site drove innovations in , including early advancements in systems and industrial applications, solidifying Schenectady's status as a key node in America's efforts. GE's formation laid the groundwork for the modern electrical industry, transforming localized power generation into a global infrastructure that powered urban growth and industrial expansion worldwide. In April 2024, GE completed a split into three independent public companies—GE Aerospace, GE HealthCare, and GE Vernova—continuing the legacy of innovation in , healthcare, and sectors, respectively. The legacy of the Machine Works endures through preserved historical elements in Schenectady, such as markers at the original commemorating Edison's arrival and the merger, alongside select Edison-era structures integrated into the GE as reminders of pioneering . Modern recognition highlights the workforce's contributions to U.S. , including early union activities like the Knights of Labor strikes at the Machine Works in the , which influenced broader industrial organizing. Additionally, the environmental impacts of early operations—such as industrial discharges into local waterways—have prompted ongoing remediation efforts, underscoring the long-term of 19th-century practices.

References

  1. [1]
    Edison Machine Works
    This company was established as a partnership around March 1881. It manufactured dynamos and large electric motors for the Edison electric light system.Missing: history | Show results with:history
  2. [2]
    Edison Machine Works, Goerck Street, New York, New York, 1881
    In 1881, Thomas Edison formed the Edison Machine Works to produce dynamos that would generate the electricity used to light homes and businesses outfitted ...Missing: founding | Show results with:founding
  3. [3]
    Edison's Electric Light and Power System
    ### Summary of Edison Machine Works from https://ethw.org/Edison%27s_Electric_Light_and_Power_System
  4. [4]
    [PDF] EDISON'S MANUFACTURING OPERATIONS Docs. 2343 and 2368 ...
    23 The Machine Works was incorporated in 1884 with Edison as president, Batchelor as treasurer and general manager, Kruesi as assistant manager, and Insull as.Missing: founding Thomas
  5. [5]
    Pearl Street Station - Engineering and Technology History Wiki
    To solve this problem, Edison developed the “Jumbo” dynamo, a 27-ton machine that produced 100 kilowatts, enough to power 1200 lights. This was four times the ...
  6. [6]
    Edison 'Jumbo' Engine-driver Dynamo - ASME
    This dynamo, connected directly to a high-speed steam engine, was one of six that produced direct current at Thomas A. Edison's electric power station.Missing: Machine manufacturing
  7. [7]
    The Papers of Thomas A. Edison - Project MUSE
    They decided instead to relocate it far from the city in order, as Edison would put it, “to get away from the embarrassment of the strikes and communists to a ...
  8. [8]
    [PDF] Edison's Decision By George Wise
    ... size from its end of Civil War peak, from employing perhaps 200 workers in ... workers of the Edison Machine Works were organized by the Knights of Labor.
  9. [9]
    Col. Furman and the Edison Machine Works - Hoxsie!
    Feb 28, 2018 · In 1886, the Edison Machine Works, building the Edison tubes that carried power underground, was located on Goerck Street in lower Manhattan.
  10. [10]
    Electric City Immigrants: Italians and Poles of Schenectady, N.Y., 1880-1930: Chapter 5
    ### Summary of Edison Machine Works Relocation to Schenectady
  11. [11]
    [PDF] The Old GE - - Schenectady County Historical Society
    expanded into a Works exceptional in size and scope for the 1880s. Few ... jobs were, at first, mainly those of the previous Edison Machine Works. Most ...
  12. [12]
    The Papers of Thomas A. Edison - Project MUSE
    This figure is the last and best of several calculations of the efficiency of Edison's “standard dynamo machine” made by Francis Upton during the first week of ...
  13. [13]
    Thomas Edison the entrepreneur - Works in Progress Magazine
    May 23, 2023 · The Edison Machine Works would make the heavy dynamos – which he had invented – for power stations. The Edison Lamp Works would produce mass ...
  14. [14]
    William J. Hammer Collection | Smithsonian Institution
    In 1880 he was appointed Chief Engineer of the Edison Lamp Works. In this first year, the plant under general manager Francis Upton, turned out 50,000 lamps ...
  15. [15]
    John Kruesi - Engineering and Technology History Wiki
    Feb 1, 2016 · As Edison's machinist, Krusei worked on some of the great inventor's most important inventions. Kruesi was born in Switzerland in 1843.
  16. [16]
    From Research to Development - Thomas A. Edison Papers
    At the end of December Francis Upton was placed in charge of the factory and regular production finally began in March or April 1881. As he began to make plans ...
  17. [17]
    Edison type "Z" direct current dynamo
    An Edison Z-type generator of bi-polar construction, rated for 60 sixteen-candlepower incandescent lamps (52 amps at 110 volts), made about 1881. Markings: "D18 ...Missing: capacities | Show results with:capacities
  18. [18]
    [PDF] Edison “Jumbo” Engine-Driven Dynamo - ASME
    May 29, 1980 · Speed: 350 r.p.m.. Capacity: 99 kilowatts (approx.) 1,200, sixteen candlepower lamps. Weight: 53,836 Ibs. Built by the Edison Machine Works, New ...
  19. [19]
    The "Long-Waisted Mary-Ann" dynamo. This "Z" type ... - Tumblr
    The "Long-Waisted Mary-Ann" dynamo. This "Z" type dynamo developed by Edison in 1879 had an efficiency of 90%. The theoretical limit of dynamo efficiency, ...
  20. [20]
    Pearl Street Station - History | IEEE Power & Energy Magazine
    One ASME Landmark was for the Edison “Jumbo” engine-driven dynamo number 9, a machine that was one of the six original such dynamos installed in 1882 at the ...
  21. [21]
    1892 Article-Edison General Electric Co., Factory View
    Oct 10, 2011 · The Goerok Street shop was greatly enlarged and became the Edison Machine Works. ... motor of about 15 h. p. capacity hauling one car. This ...
  22. [22]
    [PDF] PEARL STREET CENTRAL STATION Doc. 2243 Edison had ...
    ter at the Edison Machine Works. Separate mechanisms, the so-called “cheese ... tery of 1,000 lamps used to test dynamos removed from the main circuit ...
  23. [23]
    Edison, the Electrical Engineer, Spearheaded Central Station ...
    May 20, 2016 · The Edison Machine Works manufactured dynamos at a factory in New York City. The Edison Lamp Company manufactured light bulbs at a factory ...
  24. [24]
    1882 - Thomas A. Edison Papers
    Jan 12, 2025 · Opens the Pearl Street central station in the Wall Street district of New York. Executes thirty-four patent applications covering electric ...<|control11|><|separator|>
  25. [25]
    Edison General Electric Company
    This company was incorporated in New York on April 24, 1889, in a merger of Edison's three electric light manufacturing companies.
  26. [26]
    [HM89AAR], Incorporation Record, Edison General Electric Co ...
    [HM89AAR], Incorporation Record, Edison General Electric Co, March 28th, 1889 ... The capital stock ... The capital stock of the company is $12,000,000 ...
  27. [27]
    Edison vs. Westinghouse: A Shocking Rivalry - Smithsonian Magazine
    Oct 11, 2011 · Edison vs. Westinghouse: A Shocking Rivalry. The inventors' battle over the delivery of electricity was an epic power play.
  28. [28]
    Edison Biography - Thomas Edison National Historical Park (U.S. ...
    Oct 10, 2025 · Edison's various electric companies continued to grow until in 1889 they were brought together to form Edison General Electric.Missing: formation | Show results with:formation
  29. [29]
    Samuel Insull | Businessman, Entrepreneur, Innovator - Britannica
    When the Edison General Electric Company was formed in Schenectady, N.Y., in 1889, Insull became a vice president. Three years later he became president of ...
  30. [30]
    Edison & the Elephant NOT in the Room - The Engineering Mind
    Aug 1, 2018 · Distracted by his new interest in ore processing, Edison gradually released control of his power company to the company's board, which in 1889 ...
  31. [31]
    Thomas Edison's Edison Electric Light Company began operations...
    Oct 15, 2020 · In 1890, the company would merge with By 1890, several other Edison companies to become the Edison General Electric Company, which then ...
  32. [32]
    GE Founders: Innovating Industry - Google Arts & Culture
    J.P. Morgan, Edison's chief financial backer, and Charles Coffin, president of Thomson-Houston, explored the merger to improve profitability. Charles Coffin ...
  33. [33]
    How The General Electric Company Changed Schenectady—And ...
    Oct 2, 2019 · Its state-of-the-art Schenectady headquarters consisted of a 600-acre Schenectady Works industrial campus, dotted with more than 240 buildings ...Missing: 1889 | Show results with:1889
  34. [34]
    Schenectady, New York Industrial History: The General Electric ...
    In 1887, Thomas Edison moved his Edison Machine Works to Schenectady. The document he signed is one of the most valuable records in the County Clerk's office.Missing: 1889 | Show results with:1889
  35. [35]
    Thomas Edison Arrived at Schenectady Historical Marker
    At this site Thomas Edison arrived at Schenectady Aug. 20, 1886 to found his Machine Works which in 1892 became the General Electric Company.Missing: 10 acre
  36. [36]
    https://www.hmdb.org/m.asp?m=4337
  37. [37]
    Decades of contamination at General Electric's main plant
    Jul 7, 2016 · General Electric's best-known legacy of environmental contamination is the estimated 1.3 million pounds of PCBs the company discharged for decades into the ...Missing: Machine | Show results with:Machine