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Eads Bridge

The Eads Bridge is a pioneering steel arch bridge that spans the Mississippi River, connecting downtown St. Louis, Missouri, with East St. Louis, Illinois, at Washington Avenue and Broadway, respectively.^[1]^[2] Completed on July 4, 1874, after construction began in 1867, it was the world's first major bridge constructed primarily of steel and the longest arch bridge of its era, featuring three spans each over 500 feet long.^[3]^[1]^[2] Designed and supervised by self-taught engineer James Buchanan Eads, the bridge represented a monumental post-Civil War engineering achievement, costing approximately $10 million and addressing the growing dominance of railroads over river trade.^[1]^[2] Its innovative triple-span design incorporates four pairs of tubular metallic arches per span, supported by two granite-faced mid-river piers and shore abutments, with two decks originally intended for combined rail and vehicular use—the upper for wagons and pedestrians, the lower for railroads.^[1]^[2] Eads introduced groundbreaking techniques, including the first extensive use of structural alloy steel, hollow tubular chord members for enhanced strength, true cantilever construction via temporary wooden towers, and pneumatic caissons sunk to a depth of 123 feet—the deepest at the time and the first such application in the United States—to combat challenging riverbed conditions.^[3]^[1]^[2] As the first bridge across the Mississippi at St. Louis and the inaugural structure to carry both railroad tracks and road traffic on separate levels, it revolutionized transportation infrastructure and symbolized American industrial progress, earning praise from poet Walt Whitman as a "structure of perfection and beauty unsurpassable."^[3]^[1]^[2] Designated a National Historic Landmark in 1964, a National Historic Civil Engineering Landmark in 1971, and a City Landmark in 1971, the bridge faced financial and structural challenges post-completion, including bankruptcy of its builders, but has endured as the oldest standing bridge on the Mississippi River.^[3]^[1] As of 2025, it carries four lanes of automobile traffic and pedestrians on the upper roadway deck, and the St. Louis MetroLink light rail system on the lower deck, owned jointly by the City of St. Louis and the Bi-State Development Agency.^[4]^[5]^[1]

Design and Engineering

Structural Features

The Eads Bridge is a three-span ribbed steel arch structure spanning the Mississippi River, with the central arch measuring 520 feet, the northern arch 502 feet, and the southern arch 502 feet. These arches utilize tubular chord members—large-diameter steel tubes forming the upper and lower ribs—representing the first extensive application of such elements in a major bridge design. Each arch comprises four parallel ribs spaced approximately 8 feet apart transversely, connected by steel bracing for rigidity. The structure rests on four masonry piers embedded in the riverbed bedrock, constructed of limestone below the high-water mark and granite above to withstand hydraulic forces and erosion. Including approaches on both shores, the total length extends to 6,442 feet.^[6]^[7]^[7]^[8]^[9] The arches incorporate chrome steel, an innovative alloy at the time that enhanced strength and corrosion resistance, marking its inaugural major use in bridge construction and sourced from Pittsburgh mills. Eads conducted rigorous tests on steel samples to confirm their elastic limits and durability. The tubular ribs measure about 18 inches in diameter and are segmented into 10- to 12-foot lengths, joined securely to form the continuous arch profile. This material choice, combined with the pier foundations reaching up to 103 feet below mean water level at the deepest point, provided the stability needed for the unprecedented spans over a navigable waterway prone to flooding and shifting sands.^[9]^[7] A distinctive dual-deck configuration accommodates both roadway and rail traffic: the upper deck supports vehicular and pedestrian use across an approximately 46-foot-wide surface originally intended for wagons, while the lower deck houses dual railroad tracks with adequate vertical separation provided by the arch depth of approximately 12 feet between chords. This arrangement ensures 88 feet of clearance above low water (50-55 feet above high water) for steamboat passage, integrating transportation needs without obstructing navigation. The piers anchor the ends of each arch, distributing loads evenly across the foundation.^[8]^[10]^[6]^[7]

Innovative Techniques

The Eads Bridge pioneered the use of cantilever construction for its arch spans, marking the first instance in bridge engineering where arches were built outward from the piers without temporary scaffolding or falsework over the river, thereby minimizing disruption to Mississippi River navigation. This method involved erecting the arch ribs in segments from each pier, supported by temporary timber towers and steel cables until the halves met at the center span. Hydraulic jacks were employed to precisely adjust alignment during closure, as demonstrated in the successful joining of the west arch rib on September 17, 1873.^[2]^[7] A key innovation was the introduction of pneumatic caissons for the pier foundations, the first such application in the United States, which allowed workers to excavate bedrock below the riverbed in a pressurized environment. These caissons, airtight chambers supplied with compressed air at pressures exceeding two to three atmospheres, were sunk to depths of 109 feet 8 inches at the east abutment, 86 feet at the west pier, and 95 feet at the east pier below the water surface. Eads's invention of a sand pump facilitated efficient removal of silt and debris, but the high pressures exposed workers to caisson disease, or decompression sickness, affecting over 100 laborers overall (approximately 80 on the east pier alone) with symptoms like paralysis and joint pain, resulting in 12-14 deaths; mitigation efforts included strict shift limits of one hour at the piers and 45 minutes at the deeper abutment.^[2]^[11]^[1] The bridge employed tubular steel members for both compression and tension elements in its arches, a design by James B. Eads that enhanced resistance to buckling through the inherent strength of cylindrical hollow tubes. These tubes, measuring 18 inches in diameter with walls up to a quarter-inch thick, were fabricated from chrome steel staves butt-riveted together and rigorously tested for elastic limits to ensure durability under load. Each arch rib consisted of four such tubes spaced approximately 8 feet apart, connected by steel bracing, totaling 1,036 tubes across the structure and enabling the unprecedented use of steel in a major bridge arch system.^[2]^[7] Wind bracing was integrated into the design to provide lateral stability, featuring diagonal steel members lacing the top and bottom chords of the arches at 12-foot intervals, a measure reinforced after a 1871 tornado damaged temporary supports and highlighted vulnerabilities. Decorative elements complemented the engineering, including granite-faced approaches quarried from Virginia, Maine, and Missouri to form durable, aesthetically pleasing piers and abutments, alongside ornate ironwork portals designed by architect G.I. Barnett that framed the entrances with elegant arches and arcades.^[2]^[11]

Construction

Planning and Challenges

Following the American Civil War, St. Louis faced urgent economic pressures from the decline of river-based commerce and the rapid expansion of railroads, which favored northern cities like Chicago that already had permanent Mississippi River crossings. Temporary ferries proved inefficient and costly for freight, exacerbating the city's isolation and hindering its growth as a rail hub; earlier attempts at a bridge, such as Charles Ellet's 1839 wire suspension proposal, had failed due to financial and technical issues.^[2]^[12] James Buchanan Eads, a self-taught engineer born in 1820 who had amassed a fortune in Mississippi River salvage operations and designed ironclad gunboats during the war, emerged as an unlikely proponent for the project despite lacking bridge-building experience. In July 1867, Eads submitted a bold proposal for a steel arch bridge to the Illinois and St. Louis Bridge Company, outmaneuvering competitors who favored traditional wire suspension designs and securing his appointment as chief engineer.^[1]^[2]^[12] The initial cost estimate stood at $6 million, to be funded through private investor subscriptions totaling $300,000, sales of $1.8 million in New York stock and $1.2 million in St. Louis stock, and federal land grants, though a proposed $4 million in municipal bonds was ultimately declined by voters. These efforts were complicated by the post-war economic depression, which strained capital availability, and fierce opposition from railroad companies that feared the bridge would divert traffic from their northern routes and from steamboat interests protective of river dominance.^[2]^[12] Legal and political obstacles further delayed progress, including lawsuits filed by the rival Illinois and St. Louis Bridge Company under Lucius Boomer, who sought to discredit Eads's plans and enforce exclusive rights to alternative designs, culminating in a 1868 merger to resolve the disputes. The U.S. Army Corps of Engineers initially expressed skepticism about the project's feasibility, viewing the proposed steel arches as unproven for such a span.^[2]^[12]

Building Phases

Construction of the Eads Bridge commenced on August 21, 1867, with the initiation of a cofferdam for the west abutment to facilitate pier foundation work.^[13] Temporary wooden trestles were erected to support ongoing activities while permanent piers were built, beginning with cofferdams for shallower foundations on the west side and transitioning to pneumatic caissons for the deeper east pier, which reached bedrock at 103 feet below the water level by February 1870.^[7] The piers were fully completed by early 1871, marking the end of the foundational phase.^[7] Steel superstructure work began in 1871, focusing on the three arches spanning 502 feet, 520 feet, and 502 feet, respectively.^[7] Arch construction employed the cantilever method, with arms extending from the piers and meeting at mid-span using extensible links; the arches were closed by September 17, 1873.^[7] The steel components, including numerous hand-riveted parts, were assembled on-site, culminating in the bridge's structural completion. The project employed a substantial workforce, with approximately 700 workers overall, including specialized teams for caisson operations and underwater tasks supported by divers.^[14] Construction faced significant challenges, including over 119 cases of caisson disease among workers exposed to high-pressure environments, resulting in 14 deaths and numerous severe illnesses.^[15] The bridge opened to the public on July 4, 1874, after seven years of work, with total costs reaching nearly $10 million due to overruns from technical complexities and delays.^[1]

History and Operation

Opening and Early Years

The Eads Bridge opened to the public on May 24, 1874, allowing initial pedestrian access across the Mississippi River, with over 15,000 people crossing on the first day.^[2] The formal dedication ceremony took place on July 4, 1874, attended by President Ulysses S. Grant, featuring a 15-mile-long parade, speeches by bridge engineer James B. Eads, and a fireworks display witnessed by an estimated half million visitors.^[2]^[16] Initial tolls were set at five cents for pedestrians and one dollar for a wagon with two horses, with fees scaled for other vehicles to support operations amid competition from established ferries.^[17] To confirm the bridge's structural integrity prior to full operations, engineers conducted stress tests on July 2, 1874, positioning 14 locomotives—totaling a 700-ton load—on the lower rail deck and running them back and forth for four hours, during which no signs of instability appeared.^[16]^[2] The first train crossed on June 9, 1874, with General William T. Sherman driving the final golden spike to mark the completion of the arch construction.^[2] Early operations revealed minor vibrations in the upper roadway deck under traffic loads, prompting adjustments to the decking and reinforcement of vertical supports to enhance stability without disrupting service.^[2] The bridge's dual-deck design facilitated immediate integration with St. Louis's expanding streetcar and railroad networks, enabling seamless connections to the East St. Louis rail yards and reducing reliance on ferry transfers for freight and passengers.^[2] This linkage boosted local commerce by streamlining transcontinental rail traffic through St. Louis, despite ongoing rivalry with ferry operators who lowered rates in response; by the late 1870s, the bridge generated substantial annual revenue, even as financial strains from construction debts led to receivership in 1875.^[18]^[12]

20th Century Changes

In the early 20th century, the Eads Bridge underwent adaptations to accommodate the rise of automobile traffic on its upper deck, which had originally been designed for horse-drawn vehicles and pedestrians. By 1947, the roadway was significantly widened to 41 feet and resurfaced with concrete-filled "I Beam Lok" flooring, replacing the original treated gum planks and wood stringers to better support modern vehicular loads.^[19] These changes reflected the bridge's evolving role in regional transportation, though streetcar operations on the upper deck ceased in 1935, with tracks fully removed by 1942.^[19] The bridge's rail operations intensified during World War II to facilitate military transport across the Mississippi River, leveraging its strategic position as a key link between eastern and western rail networks. Post-war, freight traffic declined as newer structures, such as the Municipal Free Bridge opened in 1917, diverted heavier loads and reduced the Eads Bridge's dominance in commercial rail service, rendering it less viable for large-scale freight by the mid-20th century.^[20] In 1949, the Terminal Railroad Association of St. Louis (TRRA), which had managed rail operations since the late 19th century, conducted strength tests using electromagnetic strain gauges, confirming the structure's capacity exceeded original design expectations and could handle substantially heavier loads.^[21] The TRRA retained ownership of the bridge's rail components until 1989, when it was transferred to the Bi-State Development Agency and the City of St. Louis in exchange for the MacArthur Bridge; the transfer facilitated the adaptation of the lower deck for the MetroLink light rail system, which began service across the bridge in 1993.^[21]^[4] By the 1980s, corrosion from decades of exposure to the river's harsh environment had deteriorated portions of the bridge's steel framework, prompting partial suspension of rail services on the lower deck to ensure safety while maintenance was assessed.^[2] The bridge also faced environmental threats, including near-flood conditions during the 1937 Ohio River flood, which affected the Mississippi Valley and tested the structure's resilience against high water levels.^[22] Similar risks emerged in 1993 amid the Great Flood, when rising waters reached critical stages near the Eads Bridge, but innovative levee and pumping strategies protected downtown St. Louis and preserved the landmark.^[23] Major rehabilitation efforts began in 1991, closing the upper highway deck to vehicles for over a decade to address seismic vulnerabilities and replace the corroded deck entirely, restoring safe passage for both road and rail traffic by 2003.^[24] These works included reinforcing the arches and approaches against potential earthquakes, underscoring the bridge's adaptation to 20th-century engineering standards while honoring its historic integrity.^[25]

Modern Usage

Following its reopening to vehicular traffic in 2003 after a decade-long closure, the Eads Bridge has served as a vital link for automobiles, pedestrians, and cyclists across the Mississippi River, accommodating both local commuters and regional travelers. The upper deck supports four lanes of roadway, while a dedicated pedestrian walkway allows for foot and bicycle access, enhancing connectivity within the St. Louis metropolitan area. This walkway integrates with broader regional networks, such as the proposed Chouteau Greenway trail system, which utilizes the bridge's infrastructure to create a continuous bicycle and pedestrian route linking Missouri and Illinois sides of the river.^[26]^[27] In 2014, coinciding with the bridge's 140th anniversary, ongoing rehabilitation efforts focused on structural preservation, including the replacement of aging support steel and upgrades to the MetroLink rail system on the lower deck, ensuring continued safe operation amid heavy daily use. These works, part of a larger project completed in 2016, extended the bridge's service life by an estimated 75 years through measures like blasting and repainting the superstructure to combat rust accumulation.^[28]^[29] The bridge marked its 150th anniversary in 2024 with a series of public events organized by the National Park Service and local institutions, including guided tours, ranger-led talks on engineering innovations, and an art program at Gateway Arch National Park from June 29 to July 7. Additional commemorations featured the "Eads Bridge at 150" exhibit at the Missouri History Museum (2024–May 11, 2025), which showcased historical artifacts and the bridge's impact on regional development, alongside July 4 festivities at Celebrate St. Louis that highlighted its architectural legacy.^[30]^[31]^[32] Currently co-owned by the City of St. Louis, which maintains the roadway deck, and Bi-State Development (operator of Metro Transit), the bridge undergoes routine inspections and repairs to address ongoing issues like corrosion on steel components and wear on expansion joints. The 2016 rehabilitation, costing $48 million with federal funding covering 91 percent, included comprehensive anti-corrosion treatments and joint replacements to sustain its dual role in vehicular and rail transport.^[29]^[28]

Connecting Tunnel

Construction and Design

The connecting tunnel beneath downtown St. Louis was authorized in 1872 through the establishment of the St. Louis Tunnel Railroad Company, tasked with constructing a cut-and-cover structure to link the Eads Bridge's rail deck directly to the Missouri Pacific Railroad tracks south of the city center, thereby avoiding major surface disruptions in the densely built urban environment.^[11]^[21] Designed by chief engineer James B. Eads, the tunnel extended approximately 4,460 feet (1,360 m) from the bridge's west abutment, turning south along streets like Eighth to reach the Mill Creek Valley rail yards, with provisions for future integration into broader rail networks including what would become Union Station.^[11]^[11] Construction proceeded from late 1872 through 1874, running parallel to the main bridge work, and involved excavating a 30-foot-deep open trench that was then lined with parallel brick arches supporting two tracks, approximately 25 feet in width, with the initial setup featuring one operational track, before backfilling over the structure to restore street level.^[11] Significant challenges arose from the unstable, boggy alluvial soils requiring continuous dewatering via pumps and extensive timber shoring to prevent collapses, compounded by urban interferences such as street closures that prompted lawsuits from disrupted businesses and led to contractors William Skrainka and Company handling the section south of Market Street and James Andrews the northern section, after Skrainka threatened to abandon the project due to escalating costs.^[11] Key design elements included gentle curves to facilitate safe rail navigation through the tight downtown alignment and basic ventilation provisions via access points, though the initial setup lacked a full system, causing smoke buildup issues during early test runs.^[11] The tunnel was completed in time for its first revenue train on June 9, 1874, just weeks before the bridge's public opening on July 4.^[11]

Historical Operation

The connecting tunnel for the Eads Bridge opened in 1874, concurrent with the bridge's rail deck activation on June 9, allowing the first freight and passenger trains to link the structure to Missouri Pacific Railroad yards in the Mill Creek Valley south of downtown St. Louis, thereby bypassing congested streets. This underground route, approximately 4,460 feet (1,360 m) long, immediately supported the city's growing rail network by providing a direct connection between eastern railroads arriving via the bridge and western lines terminating in St. Louis.^[2]^[33] In 1881, following financial reorganization under financier Jay Gould, the Missouri Pacific Railroad Company secured a 500-year lease on the bridge and tunnel, integrating them into a transcontinental system that connected the Wabash Railroad in the east with western networks. The tunnel's role expanded with the opening of Union Station in 1894, to which it provided underground access, facilitating increased passenger and freight movement through the terminal. Usage peaked from the 1880s through the 1920s as St. Louis solidified its position as a major rail hub, with the Terminal Railroad Association of St. Louis (TRRA) assuming operational control in the late 1880s to coordinate multi-railroad traffic efficiently. Maintenance efforts during this period addressed emerging issues like structural corrosion, though specific interventions for water seepage in the 1910s are not detailed in primary records.^[2] Economic challenges marked the tunnel's later years, beginning with the St. Louis Bridge Company's receivership in 1875 due to insufficient revenue and poor inter-railroad coordination, leading to an auction sale in 1878. Traffic declined sharply during the Great Depression amid broader rail industry contraction, though wartime demands in World War II temporarily revived freight volumes for industrial support. Post-war shifts toward highway transport contributed to a sustained drop-off, culminating in full closure to freight in 1974 owing to structural deterioration, operational inefficiencies, and evolving safety standards. Ownership transitioned formally to the TRRA in 1949 for continued bypass operations, but the tunnel was ultimately abandoned for rail use after the 1974 closure.^[2]

Current Role

In 1993, the Connecting Tunnel underwent a major rehabilitation as part of the launch of the St. Louis MetroLink light rail system, transforming it from disuse following its 1974 closure into a vital transit corridor. The project involved widening the tunnel to accommodate dual tracks, installing new stations such as Laclede's Landing and 8th & Pine, and integrating electrical systems including overhead catenary wiring for light rail operations. The rehabilitation enabled seamless connectivity with the Eads Bridge's lower rail deck, allowing MetroLink trains to cross the Mississippi River while navigating the downtown core.^[26]^[34]^[33] Since its reopening in July 1993, the tunnel has operated continuously as a key segment of the MetroLink Red Line, facilitating bidirectional light rail service from East St. Louis, Illinois, through downtown St. Louis to points west and north, including Lambert International Airport. The Red Line, which utilizes the tunnel and bridge, contributes significantly to the system's overall ridership of approximately 64,600 daily weekday passengers as of the second quarter of 2025, supporting commuter travel, tourism, and economic activity across the bistate region. No freight rail has used the tunnel since the light rail conversion, reserving it exclusively for passenger transit.^[34]^[35] Maintenance efforts have ensured the tunnel's resilience in the 21st century, including the integration of flood barriers following the Great Flood of 1993, which threatened the newly operational system. In the 2010s and 2020s, upgrades to the adjacent Eads Bridge—such as new rail ties, tracks, and overhead conductor systems completed in 2016—extended to the tunnel approaches, enhancing reliability and efficiency. Recent improvements in the 2020s have focused on accessibility features like platform enhancements and elevators at connected stations, alongside modern signaling technology to improve train control and safety. As of 2025, the tunnel is undergoing repairs, including updates to fire suppression equipment, which began in summer 2023. The tunnel remains actively monitored for seismic activity, given its proximity to the New Madrid Seismic Zone, with structural inspections tied to ongoing bridge evaluations to mitigate earthquake risks.^[28]^[36]^[37]

Significance and Legacy

Engineering Achievements

The Eads Bridge represented a pioneering advancement in steel arch bridge design, marking the first major structure in the world to utilize steel as its primary material for the arches, which spanned approximately 500 feet each. This innovation shifted civil engineering away from wrought iron toward the superior strength and durability of steel, enabling longer spans and greater load-bearing capacity over challenging waterways like the Mississippi River. The design's ribbed arch configuration, with tubular steel ribs and bracing, set a precedent for future steel bridges, influencing subsequent projects that adopted steel for enhanced structural efficiency.^[38]^[7] A key engineering milestone was the bridge's employment of true cantilever assembly, the first in the United States for a large-scale structure, which allowed the arches to be built outward from the piers without extensive falsework that would obstruct river navigation. This method involved suspending arch segments from temporary wooden towers using steel cables, with the halves meeting midspan and connected via adjustable wrought iron links to account for compression. By avoiding traditional scaffolding, the cantilever approach not only facilitated construction in a busy waterway but also became a model for later cantilever bridges worldwide, demonstrating scalable techniques for spanning wide gaps.^[7]^[1] In foundation engineering, the use of pneumatic caissons advanced deep-water pier construction by providing unprecedented efficiency over traditional cofferdam methods, allowing workers to excavate to bedrock—up to 123 feet below the river surface—under compressed air while building the piers simultaneously. This was the first application of large-scale pneumatic caissons in the U.S., reaching depths that established new standards for subaqueous foundations in major river crossings and reducing overall construction timelines through continuous operations. The technique's success directly informed subsequent projects, such as the Brooklyn Bridge, where similar caissons were deployed starting in 1870 to achieve comparable foundational stability.^[38]^[39]^[40]^[1] Contributions to material science were evident in the rigorous quality control protocols for the steel, where every component—totaling over 2,300 tons in the final structure—was subjected to testing for elastic limits and modulus of elasticity to ensure uniformity and reliability. This exhaustive verification process, which rejected substandard batches from multiple suppliers, established early benchmarks for alloy testing in infrastructure, emphasizing tensile strength and consistency to prevent failures under load. Such protocols influenced the standardization of steel production and inspection in civil engineering, promoting safer and more predictable material performance in large-scale builds.^[7]^[41] The connecting tunnel exemplified early urban rail solutions through its cut-and-cover construction, a trench-based method that built a brick and stone-lined passage to route trains from the bridge into downtown St. Louis without surface disruption. Predating comprehensive subway systems by decades, this approach served as a foundational model for integrating rail into dense urban environments, informing the cut-and-cover techniques later employed in pioneering subway constructions, such as New York's Interborough Rapid Transit lines opened in 1904.^[42]^[43]

Cultural Importance

The Eads Bridge emerged as a potent symbol of Gilded Age innovation and ambition, embodying St. Louis's determination to assert regional dominance amid fierce competition with Chicago for Midwestern trade and transportation supremacy.^[38] By spanning the Mississippi River with unprecedented steel arches, it represented a bold assertion of American industrial prowess during an era of rapid urbanization and infrastructural expansion.^[3] Economically, the bridge transformed commerce by eliminating reliance on ferries, thereby shortening freight transit times and bolstering St. Louis's role as a key rail hub, which spurred manufacturing expansion and population influx in the late 19th century.^[44] This connectivity helped sustain the city's growth against rivals, facilitating the movement of goods and people that underpinned the region's economic vitality into the 20th century.^[38] Recognized for its enduring historical value, the Eads Bridge was designated a National Historic Landmark in 1964 by the National Park Service, honoring its pivotal role in American engineering and transportation history.^[3] Today, it serves as an iconic draw for tourists exploring St. Louis's riverfront, integrated into the Gateway Arch National Park experience and contributing to the area's appeal as a destination for history and architecture enthusiasts. The bridge's construction also left a profound social imprint, as workers excavating the riverbed in pressurized caissons suffered from decompression sickness—known as "caisson disease" or "the bends"—with dozens affected and several fatalities, marking one of the earliest documented outbreaks of the condition in the United States and heightening awareness of occupational health risks in deep-water engineering projects.^[16]^[10] In 2024, commemorations of the bridge's sesquicentennial, including exhibits at the Missouri History Museum and programs by the National Park Service, highlighted its multifaceted legacy, from industrial triumphs to its place in broader narratives of American progress. The "Eads at 150" exhibit at the Missouri History Museum ran from April 2024 to May 2025.^[45]^[46]

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Eads Bridge is a deck arch bridge, road bridge, railroad (railway) bridge, steel bridge and truss arch bridge that was built from 1867 until 1874.<|control11|><|separator|>
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General Information. Total Passenger Boardings: 19,664,532. Rolling Stock: 72 MetroLink vehicles; 308 MetroBus vehicles.
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[37]
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The Victorian City-Transportation Structures - City of St. Louis, MO
The tunnel itself is constructed of brick and stone, with cast iron supports. Today, like Eads Bridge, the railroad tunnel is used by Metro-Link. Street Car ...
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[PDF] Subway-Construction-Then-and-Now.pdf - New York Transit Museum
Unlike cut and cover, these tunnels are deep underground and cannot be built by digging through the street. Drillers made holes for dynamite that helped explode ...
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Railroad growth - The Eads bridge story - Illinois State Museum
A bridge would reduce delays for moving freight westward then caused by the need to stop trains in East St. Louis and transport goods across the river by ferry.
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Building the Eads Bridge, a 150th Anniversary Tribute
Jul 4, 2024 · St. Louis's landmark bridge is turning 150 years old on July 4, 2024! Learn more about the amazing Eads bridge and the innovations in its ...Missing: 2014 | Show results with:2014