Electrification of the New York, New Haven and Hartford Railroad

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A New Haven EP-1 electric locomotive, circa 1907. Note the small DC pantograph between the two larger AC pantographs. NH EP-1.png
A New Haven EP-1 electric locomotive, circa 1907. Note the small DC pantograph between the two larger AC pantographs.

The New York, New Haven and Hartford Railroad pioneered electrification of main line railroads using high-voltage, alternating current, single-phase overhead catenary. It electrified its mainline between Stamford, Connecticut, and Woodlawn, New York, in 1907 and extended the electrification to New Haven, Connecticut, in 1914. While single-phase AC railroad electrification has become commonplace, the New Haven's system was unprecedented at the time of construction. The significance of this electrification was recognized in 1982 by its designation as a Historic Mechanical Engineering Landmark by the American Society of Mechanical Engineers (ASME).

Contents

Initial experiments

NewHavenCatBridge.png

The New Haven tried several experiments with low-voltage DC electrification in the decade preceding their main line overhead electrification. These included:

The third rail system resulted, not surprisingly, in a number of accidents. It also resulted in a decree from the Connecticut Supreme Court on June 13, 1906 forbidding the use of third rail electrification within the state. [2] The New Haven was forced by this decision to design their main line electrification system using overhead catenary.

Several different systems combinations of voltage and frequency were considered in the initial design. Due to the relatively large distances involved, transmission at high voltages using alternate current was recognized as being unavoidable. An architecture similar to commercial DC utilities and urban railroads was considered using high voltage transmission lines, rotary converters, and overhead DC catenary. The studies of the time assumed an electrical efficiency of only 75 percent for this architecture.

The highest voltage for which generators could be reliably designed at this time was about 22 kV. An intermediate design was considered using 22 kV transmission lines, substations to reduce catenary voltage to between 3 and 6 kV, and transformers on the engines to the 560 V required by the traction motors. [2] The railroad realized that it could save significant capital cost if the intermediate substitution were omitted and locomotives received line voltage at around 11 kV.

Original 1907 direct-feed architecture

Direct-feed architecture implemented in 1907, and schematic of catenary bridge circuit breakers in the 1907 design. Interferencep962.png
Direct-feed architecture implemented in 1907, and schematic of catenary bridge circuit breakers in the 1907 design.

The New Haven's electrification was the first of its kind; no previous railroad had practical experience operating a high voltage distribution system above a steam railroad. Many of the system's ultimate specifications were the result of educated design decisions based on the state of the electrical technology in 1907.

Proposals were obtained from General Electric (GE) and Westinghouse. Both companies submitted a variety of AC and DC schemes, though GE favoured DC electrification. But New Haven chose single-phase AC at 11 kV, 25 Hz as proposed by Westinghouse, who had been researching AC electrification of railroads since 1895 and in association with Baldwin supplied Baldwin-Westinghouse locomotives. [3] Later GE also supplied some locomotives.

Voltage

The designers considered several voltages for the transmission segment of the system including 3–6 kV, 11 kV, and 22 kV. Ultimately, the transmission and catenary systems were combined into a transformerless system, that utilized the same voltage from output of generator to catenary to locomotive pantograph. As 11 kV was the highest voltage that could be obtained directly from the output of the generators of 1907, 11 kV was selected as the transmission and catenary voltage of the system.

Frequency

The New Haven had considered two different operating frequencies for use in their electrification: 15 Hz, and 25 Hz. Although 15 Hz was desirable from an engineering perspective, as it would afford a reduced motor size, lower inductive losses, and a higher motor power factor, choosing that frequency was viewed by the railroad as akin to a "break in gauge", thus limiting the commercial prospects of their system. 25 Hz had by 1907 already become a commercial standard, and the railroad already operated a number of trolley power houses at 25 Hz and had equipped many of its shops with 25 Hz motors; thus, the railroad selected the 25 Hz standard.

Catenary

Derelict catenary along the New Haven Railroad main line in Mount Vernon, New York. The segment south of Pelham now uses a third rail. Mount Vernon East-11,000 Volts.JPG
Derelict catenary along the New Haven Railroad main line in Mount Vernon, New York. The segment south of Pelham now uses a third rail.

The New Haven had no precedent to follow when designing its catenary system. Overhead catenary had previously been the domain of trolleys, except for a few three-phase railways in Europe. No prior experience existed with operating high-speed railways with an overhead contact system. The catenary designed by the New Haven was a unique, relatively rigid triangular cross-section.

The triangular cross-section of catenary used in the original electrification was only repeated by one other railway. The London, Brighton and South Coast Railway used a similar triangular catenary from 1909 until 1929. [4] The New Haven's 1914 extensions dispensed with the triangular catenary design.

Catenary support spacing was set at 300 feet (91 m). This was based on keeping the straight line deviation from center of track to within 8.5 inches (220 mm) with a curve radius of 3 degree, which was the tightest curve between the original system's termini at Woodlawn and Stamford.

Generators

The generators at the Cos Cob Power Station were designed to supply single-phase power directly to the catenary. They were also required to supply three-phase power both to the New Haven itself for use along the lines, [5] and to the New York Central's (NYC) Port Morris generating station to compensate the NYC for the power consumed by New Haven trains on the NYC's third-rail supplied line to Grand Central Terminal. [2] The Cos Cob generators were three-phase machines, but wired to supply both three phase and single phase power simultaneously.

Revised 1914 autotransformer architecture

Diagram of New Haven system following 1914 implementation of autotransformer substations. Interferencep962b.png
Diagram of New Haven system following 1914 implementation of autotransformer substations.

Although the railroad considered the 1907 electrification highly successful, two problems required an ultimate redesign of the transmission system. The first was electromagnetic interference in adjacent, parallel telegraph and telephone wires caused by the high currents in the traction power system.

The second was that the system's geographic growth and the evolving state of electrical technology created a need for higher transmission voltages. The railroad could have simply raised the operating voltage of the entire system, however this would have required all the catenary insulators to be upgraded to withstand a higher potential, and replacement of all the locomotive high voltage equipment. And while higher transmission voltages had become common in the seven years since the initial electrification, generators were still limited by economics to a maximum output voltage of around 11 kV.

The solution decided upon by the railroad, after several years of study, was a balanced autotransformer system.

Remarkably, the railroad changed transmission system architectures within four hours, although preliminary work had taken the preceding 18 months. On Sunday, January 25, 1914, the railroad shut down the entire power system at 2 am. Gangs of workers throughout the system reconfigured the transmission lines over the next 70 minutes. System startup was commenced and by 5:30 am, electric trains were running over the new, autotransformer supplied system. [6]

Substations

Schematic of catenary bridge circuit breakers and autotransformer after 1914 upgrade. Interferencep963.png
Schematic of catenary bridge circuit breakers and autotransformer after 1914 upgrade.
New York, New Haven, and Hartford Electrification System Substations [7]
Substation No.Catenary Bridge No.NameBuiltCoordinatesComments
New Haven Line
1114Cedar Hill
1104Mill River (Section Break)
1060Cedar St. 41°17′37″N72°55′50″W / 41.2937°N 72.9305°W / 41.2937; -72.9305 (Cedar St. Substation (New Haven))
962Woodmont
863Devon
814Bishop Ave
736Burr Road
633Green's Farms
524South Norwalk
465Darien 41°04′38″N73°28′07″W / 41.0773°N 73.4686°W / 41.0773; -73.4686 (Darien Substation (New Haven))
374Stamford
296Greenwich
245Port Chester 41°00′19″N73°39′21″W / 41.0053°N 73.6559°W / 41.0053; -73.6559 (Port Chester Substation (New Haven))
193Rye
126Mamaroneck 40°56′48″N73°44′41″W / 40.9467°N 73.7446°W / 40.9467; -73.7446 (Mamaroneck Substation (New Haven))
SS2272New Rochelle1914 40°54′46″N73°46′57″W / 40.9127°N 73.7826°W / 40.9127; -73.7826 (New Rochelle Substation (New Haven)) Converted to 60 Hz c. 1986
0Woodlawn
Hell Gate Line
ATK 47211HAmtrak New Rochelle1987 40°54′25″N73°47′24″W / 40.9069°N 73.7900°W / 40.9069; -73.7900 (New Rochelle Substation 47)
SS14149HBaychester/Pelham Bridge1914–1987
SS12139HWestchester/Pelham Parallel1914–1987 40°49′00″N73°53′36″W / 40.8167°N 73.8933°W / 40.8167; -73.8933 (Westchester Substation (New Haven))
ATK 46Amtrak Van Nest1987 40°50′31″N73°51′48″W / 40.8420°N 73.8633°W / 40.8420; -73.8633 (Van Nest Substation 46)
SS884HWest Farms Junction1914-1987. 40°50′05″N73°52′46″W / 40.8347°N 73.8794°W / 40.8347; -73.8794 (West Farms Substation (New Haven)(demolished)) Supplied from Sherman Creek; later from Con Ed Hell Gate GS. [8] The substation and adjacent passenger station have been demolished; an impound lot occupies the site.
SS458HOak Point1914–1987 40°48′27″N73°54′18″W / 40.8075°N 73.9049°W / 40.8075; -73.9049 (Oak Point Substation (New Haven))
SS342HBungay St1914?-1987NH 3ph power supplied to NYC's Port Morris GS [9] to compensate for NH's consumption on NYC DC lines.
SS12HHarlem River1914-19??
New York, Westchester and Boston Railway
Columbus Ave Mt Vernon
White Plains
New York Connecting Railroad
ATK 45C68Bowery Bay1918 40°45′51″N73°54′19″W / 40.7643°N 73.9054°W / 40.7643; -73.9054 (Bowery Bay Substation 45)
Long Island Rail Road Bay Ridge Branch
55Fresh Pond1927-19??
2 East New York (FC)1927-19??Connects the single phase to/from PT&T/LIRR's 3 phase 25 Hz.
54East New York Swg.1927-19??
53New Lots Ave1927-19??
52Manhattan Beach1927-19??
514th Ave Bay Ridge1927-19??

Hell Gate Line

Map showing substation locations along the New York Connecting Railroad. Electrification System of New York Connecting Railroad map.png
Map showing substation locations along the New York Connecting Railroad.
Schematic of the New Lots Substation along the New York Connecting Railroad. NewLotsSubstation.png
Schematic of the New Lots Substation along the New York Connecting Railroad.

The New Haven's system was extended across the Hell Gate Bridge to the New York Connecting Railroad upon the construction of the Hell Gate Line. The system of electrification was an extension of the New Haven's revised 11/22 kV autotransformer architecture. The original electrification extended from the New Haven's main line, across the Hell Gate Bridge, to the Bay Ridge yard. The line south of Bowery Bay Junction was de-electrified in the 1950s. The line between New Rochelle and the Harold Interlocking was transferred to Amtrak in 1976 upon dissolution of Penn Central. The electrification system continued to be controlled as a portion of the ex-New Haven system until the 1987 conversion to 60 Hz operation.

When the New Haven main line was converted by Metro-North to 60 Hz operation, the Amtrak section of the Hell Gate Line was also converted, but as an isolated system powered from the Van Nest substation. Control of the catenary system was transferred from Cos Cob to the Load Dispatcher at New York Penn Station. Although conversion occurred subsequent to the PRR-era electrification, Amtrak substation numbers 45–47 were assigned for consistency with the rest of the PRR numbering scheme.

Electrification extension to Boston

An AEM-7 electric locomotive brings an Amtrak train into South Station, Boston, in 2001 Amt930-bostonMA.jpg
An AEM-7 electric locomotive brings an Amtrak train into South Station, Boston, in 2001

Since 2000, Amtrak’s 60 Hz traction power system extends electrification along the Northeast Corridor between New Haven [note 1] and Boston, Massachusetts. This system was built by Amtrak in the late 1990s and supplies locomotives with power from an overhead catenary system at 25 kV alternating current with at 60 Hz, the standard frequency in North America. Its construction allowed all-electric passenger trains to operate the entire way between Washington, D.C. and Boston, completing the project begun in 1907 and eliminated a lengthy stop at New Haven station for locomotive changes.

See also

Footnotes

  1. "New Canaan Railroad History". www.vizettes.com. Retrieved 2024-01-07.
  2. 1 2 3 McHenry (1907).
  3. William D. Middleton (1974). When the steam railroads electrified. Kalmbach Books. p. 76. ISBN   0-89024-028-0.
  4. Savchak (1990).
  5. Westinghouse figure 19 shows three-phase substations at South Norwalk, Stamford, Greenwich, Port Chester, Van Nest Shops, and Oak Point Float Bridge
  6. Arthur (1914).
  7. based on Fig. 21 from Westinghouse Publication 1968.
  8. The Hell Gate Generating Station was located here: 40°47′55″N73°54′34″W / 40.7987°N 73.9095°W
  9. The New York Central's Port Morris Generating Station was located here: 40°48′17″N73°54′08″W / 40.8048°N 73.9021°W

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References

Early Experiments with Electrical Traction

1907 Electrification

1914 Autotransformer Upgrade

Later Articles

  1. Specifically, Amtrak's 25 kV system begins at the Mill River Interlocking about two miles north of New Haven Union Station 41°18′41″N72°54′42″W / 41.311281°N 72.911775°W