Joseph Tomlinson III

Joseph Tomlinson III (June 22, 1816 – May 10, 1905) was an English American engineer and architect who built bridges and lighthouses in Canada and the United States. In 1868, he co-designed and oversaw the construction of the Hannibal Bridge, the first permanent crossing of the Missouri River. He was the first person to hold the position of General Superintendent of Lighthouses for the new Dominion of Canada, holding that position beginning in January 1870. For eight years, he worked building railroad bridges for the Canadian government, and designed one of the most impressive bridges on the Canadian Pacific Railway where it crossed the Fraser River. He designed a railroad bridge over the Ashtabula River in Ohio, but was fired from the project after he refused to make supervisor-ordered changes to the design with he considered unsafe. The bridge failed on December 29, 1876, killing 92 people in a train derailment.

Joseph Tomlinson III
Joseph Tomlinson about 1900
Born(1816-06-22)June 22, 1816
Ruskington, Lincolnshire, United Kingdom
DiedMay 10, 1905(1905-05-10) (aged 88)
Resting placeWoodland Cemetery, Cleveland, Ohio, U.S.
NationalityEnglish American
Alma materThe Mechanics' Institute
OccupationBridge builder, lighthouse engineer, cabinetmaker
Spouse(s)Ann B. Northrup (m. 1843-1852; her death)
Sarah A. Wyles (m. 1853)
Children7

Early life and education

Tomlinson was born June 22, 1816, in Ruskington, Lincolnshire, in the United Kingdom to Joseph and Ann (née Shearwood) Tomlinson.[1][2][3][lower-alpha 1] His father was a land owner and farmer,[1][2] and the family was related to Canadian politician Nicholas Sparks.[4] Joseph was one of 14 children.[1][4]

Tomlinson showed a strong interest in mechanical design as a child,[1] but his parents sought to give him a classical education.[4] When he proved disinterested in the classics,[2][4] he was allowed to apprentice to a cabinetmaker.[1] Tomlinson spent seven years as an apprentice,[5] and soon his work surpassed even that of his teachers.[2] During this time, he also enrolled at the Mechanics' Institute in Newark, Nottinghamshire.[6] He studied draughtsmanship and mathematics[4] and was considered an outstanding student.[5]

Career

Tomlinson emigrated to the United States in 1840.[7] During the ocean voyage, he met a man from New Milford, Connecticut, who persuaded him to settle in that town.[8] Although trained as a mechanic,[9] Tomlinson discovered the practice mechanical construction in the United States was much different than that in the United Kingdom, and he found himself unemployed.[10]

Early bridge work

Shortly after his arrival in New Milford, Tomlinson observed a bridge being constructed near the town. Concerned that the bridge had not been properly designed, he informed the builder only to have his opinion disregarded.[8] Tomlinson then informed his new friend, Rev. Noah Porter (later President of Yale University), about his misgivings.[2] The bridge partially collapsed under its own weight as Tomlinson had predicted, and he was employed to help repair and strengthen it.[8][2]

Tomlinson turned to the practice of engineering on the advice of Rev. Porter.[10] To learn his new trade, he found work as a rodman with the Housatonic Railroad.[8][lower-alpha 2] He also worked for several bridge construction firms, learning the trade and principles of American bridge design.[8] In his spare time, he drafted and designed bridges for himself, seeking criticism and advice from Housatonic Railroad bridge engineers he worked under.[8][5] In time, the Housatonic asked him to study bridges designed by other engineers and make reports about them.[5][6] He was eventually employed as a bridge construction worker and supervisor for the Housatonic Railroad, the Harlem Railroad in New York, and the Rutland and Whitehall Railroad in Vermont.[10] Although most railroad bridges at the time were made of wood, Tomlinson foresaw that iron and steel would swiftly supplant wood as the primary construction material.[5] A lifelong self-learner who studied and read widely,[2] he learned the principles of iron and steel construction and engineering.[5]

The first bridge to be built to a Tomlinson design was a railroad bridge in Pittsfield, Connecticut. It was constructed in 1844, and Tomlinson himself acted as the general contractor.[10]

In 1849, the Saratoga and Washington Railroad resolved to build a tunnel through a hill in the village of Whitehall, New York.[12][13] The tunnel was to carry a branch line of the railroad, which would terminate on the shores of Lake Champlain. This would give the railroad a connection with Great Lakes passenger steamships, and connect the lake by rail to the Hudson River.[13] Several previous attempts to dig a tunnel had failed due to the presence of quicksand. When Tomlinson received the commission to design the dig and completed tunnel, he worked on his plans for 72 hours without a break or sleep.[10] The tunnel, which ran partly beneath Church Street in Whitehall, was 682 feet (208 m) long,[13] with walls of stone and arches of brick.[14][lower-alpha 3]

New Brunswick work

The Grand Falls Bridge, the first bridge designed by Tomlinson to collapse.

Tomlinson took a job as a bridge engineer with the government of the British colony (now Canadian province) of New Brunswick in 1854.[10] Tomlinson later estimated he built 13 or 14 bridges a year during his eight years in New Brunswick.[9] Nearly all the bridges he built in New Brunswick were made of wood. His designs were so sturdy that most of the bridges were still standing a half century later.[10] The first bridge he designed and built[16] was a 250-foot (76 m) long structure over the Hammond River,[9] finished in 1855.[17] The following year he built a 100-foot (30 m) long drawbridge with a 40-foot (12 m) draw span over the Musquash River at Musquash, New Brunswick.[17]

The first Tomlinson-designed bridge to collapse was a lenticular truss bridge over the Grand Falls of the Saint John River at the recently founded city of Grand Falls. The New Brunswick Board of Works argued against a suspension bridge,[lower-alpha 4] and forced Tomlinson to design a lenticular bridge. The bridge opened on December 1, 1858. At 7 AM on December 18, the bridge collapsed after the tension-bar chain snapped in two places. Two men were killed.[18] The cause of the collapse was defective iron, which became brittle in cold weather.[10][18] The Board of Works assumed complete responsibility for the failure of the bridge, and Tomlinson declined to charge the government for his work.[19] He designed a 630-foot (190 m)[9] suspension bridge as a replacement; that bridge remained standing for decades, and became the best-known of his bridges.[19]

Ohio and Missouri

After purchasing a farm on the Cedar River in Putnam Township[20] near Cedar Rapids, Iowa, Tomlinson moved there in 1862 and briefly took up farming.[5] He moved to Cleveland, Ohio, later that year and began designing bridges for the Lake Shore and Michigan Southern Railway (LS&MS).[16] He designed and built between 12 and 15 bridges a year for the railroad.[21] Tomlinson moved into architecture as well, designing a number of buildings in Cleveland.[16][lower-alpha 5] Among the most important of Tomlinson's commissions was the Central Market,[16] an indoor market space located at Ontario Street and Eagle Avenue.[23] Built in 1867[23] at a cost of $20,000 ($366,000 in 2019 dollars),[24] the facility contained space for 200 vendors.[23] Tomlinson also won the contract to build all the marble-topped meat and vegetable stalls inside the market.[25][lower-alpha 6] Tomlinson also designed the Central Way drawbridge over the Cuyahoga River, which was built in 1866.[26]

His efforts on behalf of the LS&MS garnered him widespread notice in the railroad industry, and he signed several contracts to build railroad bridges in Indiana. He sold these contracts to others when the railroads failed to fund construction.[5] From 1848 to 1849, he worked for Schulyer Bros.[5], designing and overseing some of the early construction on the Illinois Central Railroad during this time as well.[6] He left this work after the railroad encountered financial difficulties.[5]

Tomlinson got word in 1867 that civil engineer Octave Chanute was attempting to build a railroad bridge (the Hannibal Bridge) across the Missouri River at Kansas City, Missouri. He communicated with Chanute, expressing his interest in working on the bridge. Canute hired him as one of the bridge's co-designers[lower-alpha 7] in October 1867.[7] Tomlinson relocated to Kansas City from Cleveland to work on the bridge.[16] Tomlinson designed the bridge's superstructure,[16] and supervised the overall construction of the bridge.[6] When the piers in the river were washed out, Chanute asked Tomlinson to rebuild them. Tomlinson created entirely new designs for the piers and their foundations, and then oversaw their construction.[16] The bridge opened on July 4, 1869, with a ceremony in which Chanute presented Tomlinson with a gold watch.[28] The bridge was the first permanent crossing of the Missouri River.[28]

Ashtabula River railroad disaster

Wood engraving published in Harper's Weekly January 20, 1877

In 1863, officials of the Cleveland, Painesville and Ashtabula Railroad (CP&A; one of the predecessors of the Lake Shore and Michigan Southern Railway),[lower-alpha 8] decided to replace the wooden bridge over the Ashtabula River just east of the village of Ashtabula, Ohio with an iron structure.[30] Amasa Stone was president of the CP&A.[31][32] His construction firm had built the CP&A main line from 1850 to 1852,[33] and Stone had purchased the patent rights to brother-in-law William Howe's truss bridge[34] in 1842.[35] Stone resolved to construct a Howe truss bridge, a commonly used type of railroad bridge,[36] and personally designed the new bridge.[30][31] At 154 feet (47 m) long and 20 feet (6.1 m) high,[37] it would be the longest and highest Howe truss bridge in the nation.[38][lower-alpha 9] Stone also decided to award the contract for the ironwork to the Cleveland Rolling Mills, an iron and steel company based in Cleveland, Ohio, run by his older brother, Andros Stone.[30][41]

Amasa Stone's bridge was, by his own admission, experimental.[42] He had constructed only one all-iron Howe truss bridge before, a 5-foot (1.5 m) high, 30-foot (9.1 m) long railroad bridge over the Ohio and Erie Canal in Cleveland.[lower-alpha 10] Tomlinson fleshed out the bridge design for Stone. He was alarmed when Stone demanded that the bridge be constructed completely of iron, rather than a combination of wood and iron.[lower-alpha 11] An all-iron bridge would have a much greater deadweight, reducing the bridge's live load (its ability to carry trains).[38] He also concluded that the beams Stone intended to use were undersized.[31][lower-alpha 12] Stone demanded that Tomlinson make the changes he required. Tomlinson refused, and was fired.[31][38] Stone then ordered the CP&A's chief engineer, Charles Collins, to make the desired changes to the bridge design. Collins refused, and was fired.[43] Stone himself then made the changes to the design.[44][lower-alpha 13][lower-alpha 14]

The Ashtabula River bridge was erected in 1865 using Stone's design and partly under his supervision.[39][lower-alpha 15] When the temporary wooden trestle supporting the new bridge[40] was removed, the bridge buckled where the chords were connected to the deck.[44][41] To correct this problem, Stone added more iron I-beams to brace the chords.[48] This worsened the bridge's deadweight problem.[39] Because the angle blocks were not designed to accommodate the braces, Stone ordered workers to cut away portions of the I-beams to make them fit. This further weakened the braces.[39] During the repair work, workers inadvertently installed the I-beam braces sideways rather than vertically, weakening the ability of the braces to reinforce the bridge.[44] There is evidence that some I-beams were then installed correctly, but that the angle blocks were damaged in the process.[49] Furthermore, in every other joint, the diagonal chords were fitted to the angle blocks using shims rather than tightening the vertical beams and putting the diagonals under compression. Rather than rely on the truss design to carry live loads, the shims carried this weight by themselves.[50][lower-alpha 16] At the ends of the bridge, where Stone used only a single diagonal, only half of the angle block received load. This put enormous shear stress on the angle block.[52]

At 7:30 PM on December 29, 1876, the Ashtabula River bridge collapsed in what came to be known as the Ashtabula River railroad disaster. Two locomotives hauling 11 passenger railcars of the Lake Shore and Michigan Southern Railway plunged 150 feet (46 m) into the ice-clogged river below. The wooden cars burst into flame when their kerosene-fed heating stoves and oil lamps overturned,[36] and rescue personnel made no attempt to extinguish the fire.[34] The accident killed 92 people and injured 64.[49][34][36]

An investigation was immediately begun into the cause of the bridge's collapse. This took two months.[53] The proximate cause of the bridge collapse was the failure of the two angle blocks on the west end of the bridge due to fatigue (caused by bending and shear stress), friction, thrust stress from improperly fitting chords and vertical beams, and low temperatures (which caused the cast iron to become brittle). This caused the horizontal deck beams to buckle, and the bridge to collapse.[51] State investigators later concluded that the bridge had been improperly designed.[54] However, faulty materials were also use in its construction.[51][lower-alpha 17] There was also extensive evidence that the bridge had been poorly constructed: Vertical beams were not in the correct place, chords were not tied together, the bearings had been improperly laid,[54] and horizontal beams did not meet the angle blocks straight.[55] The railway had also inadequately inspected and maintained the bridge.[54][53][lower-alpha 18] Stone categorically denied that there were any design or construction flaws,[54] and blamed the collapse on the derailment of one of the two locomotives pulling the train.[49]

Return to Canada

Culminating an almost 17 year effort, the British North America Act confederated the British colonies of Canada, New Brunswick, and Nova Scotia into a new self-governing, autonomous dominion, Canada, on July 1, 1867.[56][lower-alpha 19] Departments of the Province of Canada became ministries in the new federal government. Since the Province of Canada had no fisheries or marine departments, the new dominion government absorbed and amalgamated those from New Brunswick and Nova Scotia.[63] Peter Mitchell, the former Premier of the Colony of New Brunswick, was named to the inaugrual Senate of Canada and appointed Minister of Marine and Fisheries.[64]

The Cisco Bridge

Mitchell was well-acquainted with Tomlinson's work in New Brunswick, and asked him to join the new Department of Marine and Fisheries.[16] Tomlinson agreed, and began working for the department on January 1, 1870.[65] He was formally appointed General Superintendent of Lighthouses and Constructive Engineer on May 5, 1871.[66][65] His duties in regards to new lighthouses were to select sites, visit sites prior to construction, prepare plans and specifications, visit sites during construction, and examine and report on the lighthouses once finished. He was also to inspect existing lighthouses, report on their condition, and recommend needed repairs.[66][lower-alpha 20] Tomlinson initially faced the difficult job of integrating the policies and practices of more than a dozen local, provincial, and regional lighthouse boards into a common code. He then had to develop designs for lighthouses. This project was especially difficult, as almost no plans for existing lighthouses existed to help inform best practices in lighthouse construction.[16] By 1872, the department had erected 93 lighthouses with another 43 under contract. All of the structures were wooden, and each cost less than CAD$10,000.[68] The number of lighthouses expanded so rapidly in the first five years of Tomlinson's work that in 1876 the Department of Marine and Fisheries established six regional agencies to take over responsibility for their operation and upkeep.[69] Among the hundreds of lighthouses designed by Tomlinson, the East End Light and West End Light on Sable Island and Greenly Island are examples of his best work.[70][lower-alpha 21]

Tomlinson transferred to the Department of Railways on February 9, 1880, taking a position as inspector of bridges in railways.[65] During his time with the department, he created standardized designs for wooden bridges and trestles for those portions of the Canadian Pacific Railway being built by the federal government.[76] In 1882,[76] the department sent Tomlinson to Newcastle upon Tyne in England[77] to supervise the manufacture and prefabrication of the metalwork[78] Cisco Bridge.[79] The 535-foot (163 m) long[80] cantilever truss bridge over the Fraser River, this was the first balanced cantilevered truss bridge in the world to be built with a steel deck.[81] Tomlinson also served as a construction superintendent[82][6] for general contractor John McMullen.[77] Completed in 1884, this bridge has been called "one of the most imposing engineering works on the Canadian Pacific Railway's transcontinental main line" by rail historian Michael Batten.[83][lower-alpha 22]

Tomlinson left the employ of the Department of Railways on either October 16, 1886[85] or February 9, 1888.[65][lower-alpha 23]

Retirement and death

Grave of Joseph Tomlinson and his second wife, Sarah Ann Wyles Tomlinson, at Woodland Cemetery in Cleveland, Ohio

Tomlinson retired to a home at 217 North 13th Street in Cedar Rapids, Iowa,[82] leaving the Department of Railways. After the American Civil War, he purchased another 1,280 acres (520 ha) of farmland for $800 ($14,000 in 2019 dollars).[4] Tomlinson sold a portion of his land at some point, because by 1878 he only retained about 816 acres (330 ha).[20] His eldest son managed the farm for him.[86]

In the last years of his life, Tomlinson suffered from declining health, which included cerebrovascular disease.[5] He retained his mental faculties, however. In the months just before his death, Tomlinson began working out the design for an extremely long suspension bridge. He received three patents for his design.[86] Joseph Tomlinson died of a stroke on May 10, 1905, while gardening at his home.[5] He was buried in Woodland Cemetery in Cleveland, Ohio.[4]

Personal life

Tomlinson was quite strong, and when younger often engaged in manual labor and construction work. He was an easy-going and kind supervisor, and much admired by his work crews.[87] When others were still erecting bridges primarily from experience and rules of thumb, Tomlinson calculated load limits and strain using advanced mathematics.[86]

Tomlinson was a skilled carpenter, and built furniture for his own home throughout his life. From his farming father, Tomlinson learned a love of farming and gardening. Until the end of his life, he remained an avid home gardener, and had a deep fondness for flowers.[5] Influenced by the Chartist movement, Tomlinson became a socialist in adolescence and continued to advocate for socialist political goals throughout his life.[10] Tomlinson was also a Freemason, a supporter of the Republican Party, and a lifelong member of the Episcopal Church.[82] He was a member of Grace Episcopal Church in Cedar Rapids at the time of his death.[5]

Wives and children

Joseph Tomlinson married Ann R. Northrop of New Milford[8] on December 10, 1843.[88][lower-alpha 24] The couple had three daughters: Ida, Ione, and Maria (who died in childhood). The Tomlinsons moved to Iowa City, Iowa, in 1852, where Ann Tomlinson fell ill and died[8] on January 15, 1853.[88] He moved to Brooklyn, New York, shortly after his first wife's death. He married Sarah A. Wyles (also an emigrant from Lincolnshire) on September 10, 1853. The couple had five children: Ann, Joseph, Alfred, Fannie (who died at the age of five), and Frances.[8]

Legacy

The Engineering Record called Tomlinson "a pioneer designer and builder of steel bridges in this country."[6] The Cedar Rapids Gazette called him one of the most preeminent bridge designers of the last half of the 19th century.[5]

Tomlinson was inducted as an honorary member of The Pi Eta Scientific Society.[89]

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References

Notes
  1. His mother's maiden name is also listed as "Sherwood".[1]
  2. A rodman is a surveyor's assistant. The rodman usually holds the level staff, calling out readings and identifying the places where it will be used. He also holds the range pole, assists the levelman in identifying landscape contours, and makes computations for the levelman.[11]
  3. The tunnell was turned into an open cut spanned by bridges. Work on this project began in 1927.[15]
  4. Three reasons were given: (1) That the spray of the falls would, in cold weather, form ice on the bridge and cause it to collapse; (2) That the extreme heat of summer and intense cold of winter would cause the tie rods that formed the chain beneath the bridge to expand and contract and become damaged; and (3) That too many suspension bridges had collapsed, rendering their design too uncertain.[18]
  5. Most architects in the United States trained as carpenters and builders, as there were no formal apprenticeships or educational programs until late in the 19th century. Only a handful of American architects engaged in formal study at the École des Beaux-Arts in Paris, France.[22]
  6. The Central Market survived until 1949, when it burned down in a fire.[23]
  7. The other designers were Chanute and George S. Morison.[27]
  8. The Lake Shore & Southern Michigan Railway was formed on April 6, 1969.[29] Many sources say that the LS&MS built the bridge over the Ashtabula River, but these sources appear to be using a form of literary shorthand—using the company's better-known later name.
  9. The bridge was 19.5 feet (5.9 m) wide.[39][40]
  10. This bridge was Ohio's first all-iron bridge.[38]
  11. The patented Howe truss bridge design used wooden beams for the diagonal and horizontal members, and iron beams for the vertical members.[40]
  12. Each I-beam was 6 inches (150 mm) thick and 8 inches (200 mm) wide.[39]
  13. Brockman says that the design changes were made with the assistance of A.L. Rogers, a carpenter who had never built a bridge before.[44] Amasa Stone, however, said in 1877 that Rogers only had supervision of construction.[45] Rogers himself denied designing any of the bridge.[46]
  14. Stone made additional changes to the design as well. The Howe truss bridge chords (the outside members of the truss) extended upward to the support truss. The deck on which the train traveled hung from these chords. Amasa Stone inverted this design so that the chords hung downward, supporting the truss. Inverted Howe truss bridges had a tendency to buckle where the chords where attached to the deck with cast iron angle blocks.[44] Nearly all Howe truss bridges had two diagonal chords in each "panel", with vertical beams on each end. End panels had three vertical beams. Only five Howe truss bridges ever built by 1863 had just one diagonal chord and more than two vertical beams in the end panels. These were known as "Single Howe" bridges. Amasa Stone used the "Single Howe" design for the end panels.[39] Thus, the bridge's entire structure relied on just six beams (three at each end).[39][47]
  15. Amasa Stone fired Tomlinson for "inefficiency" at some point during the bridge's construction. Tomlinson was replaced by carpenter A.L. Rogers.[45]
  16. It is also possible that the shims created uneven contact, causing angle blocks to under go both bending and shearing.[51]
  17. At least one of the broken angle blocks had a void in the center. The void itself weakens the integrity of the block. Voids also encourage the formation of large grains and can accumulate impurities like slag, both of which increase the brittleness of the iron.[51]
  18. Locomotive engineers reported hearing "snapping sounds" as they crossed the bridge for some years prior to the collapse. This likely indicates that some shims had broken and fallen off, creating space between the diagonals and horizontal beams.[55]
  19. The Province of Prince Edward Island did not enter into confederation until July 1, 1873.[57] The Colony of Vancouver Island (established January 13, 1849)[58] and the Colony of British Columbia (established August 2, 1858)[59] merged into a new Colony of British Columbia on November 19, 1866,[60] but did not confederate with the Dominion of Canada until July 20, 1871.[60] The Colony of Newfoundland acquired dominion status on September 26, 1907.[61] Labrador had been under the jurisdiction of Newfoundland since 1809,[61] but it was not until March 1, 1927, however, the British government settled a long-running border dispute with the Dominion of Canada (and its predecessors, the Province of Quebec and Lower Canada) to settle Labrador's current boundary.[62] The Province of Newfoundland and Labrador confederated on March 31, 1949.[61]
  20. The department oversaw 251 existing lighthouses at the time of Tomlinson's initial employment.[67]
  21. The West End Light, erected in 1873,[71] was dismantled in 1888 due to erosion and replaced.[72] The East End Light, also built in 1873,[71] was destroyed by weather in 1917.[73] The Greenly Island Lighthouse was erected in 1876,[74] and was destroyed by fire in 1947.[75]
  22. The bridge was moved slightly from its original location in 1911 and heavily reinforced in 1940, but remained otherwise unaltered as of 1985.[84]
  23. The date of his retirement is the source of some confusion in other sources. The Cedar Rapids Gazette and the Biographical Record of Linn County, Iowa reported he retired in 1883.[82][5] Anderson and Waddell and Heydon both claim he retired in 1885.[86][4] The 1883 date seems unlikely, as Tomlinson was at work on the Cisco Bridge until 1884.
  24. Heydon lists Ann's middle initial as "B", and spells the last name as "Northrup".[88]
Citations
  1. Biographical Record of Linn County, Iowa 1901, p. 170.
  2. Anderson & Waddell 1905, p. 321.
  3. Heydon 1980, pp. 174, 180.
  4. Heydon 1980, p. 174.
  5. Cedar Rapids Gazette 1905, p. 3.
  6. The Engineering Record 1905, p. 64.
  7. Short 2011, p. 47.
  8. Biographical Record of Linn County, Iowa 1901, p. 173.
  9. Tomlinson 1877, p. 326.
  10. Anderson & Waddell 1905, p. 322.
  11. Ives & Hilts 1906, pp. 6, 54, 105-108, 115-116.
  12. Johnson 1878, p. 474.
  13. Shaughnessy 1997, p. 106.
  14. Public Service Commission, Second District 1909, p. 737.
  15. Delaware and Hudson Company 1927, p. 9.
  16. Anderson & Waddell 1905, p. 323.
  17. General Assembly of New Brunswick 1856, p. 132.
  18. Smith, S.T. Vernon (January 21, 1859). "The Grand Falls Bridge". The Engineer. p. 48. Retrieved January 20, 2020.
  19. Anderson & Waddell 1905, pp. 322-323.
  20. Linn County Historical Society 1878, p. 783.
  21. "The Ashtabula Accident". The Plain Dealer. January 12, 1877. p. 4.
  22. Selcer 2006, pp. 362-363.
  23. Becker 2004, p. 81.
  24. "City Council—Regular Meeting". The Plain Dealer. June 27, 1866. p. 3.
  25. "Meeting of the City Council". The Plain Dealer. April 24, 1867. p. 4; "City Council". Cleveland Leader. May 8, 1867. p. 4; "Meeting of the City Council". The Plain Dealer. May 8, 1867. p. 4.
  26. "Regular Meeting of the City Council". The Plain Dealer. October 3, 1866. p. 3; "City Council—Regular Meeting". The Plain Dealer. October 17, 1866. p. 3; "Council Proceedings". The Plain Dealer. October 24, 1866. p. 3.
  27. Short 2011, p. 50.
  28. Short 2011, p. 51.
  29. Ohio Commissioner of Railroads and Telegraphs 1874, pp. 92-93.
  30. Brockmann 2005, p. 207.
  31. Bianculli 2003, p. 86.
  32. Ashcroft 1865, p. 88.
  33. Orth 1910, pp. 738-739.
  34. Griggs, Frank Jr. (November 2014). "Springfield Bridge for Western Railroad". Structure. Retrieved January 24, 2020.
  35. Gasparini, Dario (Winter 2003). "Historic Bridge News" (PDF). Society for Industrial Archeology Newsletter: 14. Retrieved January 19, 2016.
  36. Åkesson 2008, p. 19.
  37. Brockmann 2005, pp. 207, 210.
  38. Brockmann 2005, p. 208.
  39. Brockmann 2005, p. 210.
  40. Åkesson 2008, p. 20.
  41. Åkesson 2008, p. 24.
  42. Dutka 2015, p. 49.
  43. Brockmann 2005, pp. 208-209.
  44. Brockmann 2005, p. 209.
  45. Stone 1877, p. 76.
  46. Rogers 1877, pp. 121-133.
  47. Åkesson 2008, pp. 21-23.
  48. Brockmann 2005, pp. 209-210.
  49. Bianculli 2003, p. 87.
  50. Åkesson 2008, pp. 25, 26.
  51. Åkesson 2008, pp. 27-28.
  52. Åkesson 2008, pp. 26-27.
  53. Åkesson 2008, p. 26.
  54. Dutka 2015, p. 52.
  55. Åkesson 2008, p. 27.
  56. Browne 2009, pp. xii-xvi.
  57. Sharpe 1976, p. 122.
  58. Fisher 1992, p. 49.
  59. Panton 2015, p. xxvii.
  60. Panton 2015, p. xxviii.
  61. Panton 2015, p. 359.
  62. Chadwick 1967, p. 132.
  63. Buckner 1995, p. 385.
  64. Smith, William (February 1873). "Sable Island, Nova Scotia". The Nautical Magazine. p. 109. Retrieved January 22, 2020.
  65. Department of Public Works 1887, p. 220.
  66. Department of Marine and Fisheries 1872, p. 2.
  67. Department of Marine and Fisheries 1872, p. 3.
  68. Bush 1974, p. 29.
  69. Bush 1974, p. 31.
  70. Anderson & Waddell 1905, pp. 323-324.
  71. Gray, David H. (2016). "Bringing Old Mapping of Sable Island Into a Modern Geographic Reference Frame" (PDF). Proceedings of the Nova Scotian Institute of Science: 310. Retrieved January 23, 2020.
  72. "Nautical Notices". The Nautical Magazine. July 1888. p. 718. Retrieved January 23, 2020; "Nautical Notices". The Nautical Magazine. November 1888. p. 1002. Retrieved January 23, 2020.
  73. De Villiers & Hirtle 2004, p. 157.
  74. The Year Book and Almanac of Canada for 1879. Montreal: MacLean, Roger & Co. 1879. p. 38.
  75. Ney, C.H. (1948). Triangulation in Newfoundland: West Coast and Strait of Belle Isle. Geodetic Survey of Canada Publication No. 64. Ottawa: Department of Mines and Resources. p. 62.
  76. Anderson & Waddell 1905, p. 324.
  77. Batten 1985, p. 44.
  78. Sessional Papers of the First Session of the Fifth Parliament of the Dominion of Canada. Volume 16, Issue 6. Ottawa: MacLean, Roger & Co. 1883. p. Appendix 3–10. hdl:2027/iau.31858029286790.
  79. Biographical Record of Linn County, Iowa 1901, pp. 173-174.
  80. Batten 1985, p. 43.
  81. Unsowrth 2010, p. 25.
  82. Biographical Record of Linn County, Iowa 1901, p. 174.
  83. Batten 1985, p. 40.
  84. Batten 1985, pp. 44-45.
  85. Department of Public Works 1887, p. 240.
  86. Anderson & Waddell 1905, p. 325.
  87. Anderson & Waddell 1905, pp. 321-322.
  88. Heydon 1980, p. 180.
  89. Rensselaer Society of Engineers (1879). Papers Read Before the Pi Eta Scientific Society. Troy, N.Y.: Rensselaer Society of Engineers. p. 63.

Bibliography

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