It is May 4, 1925. A great crowd of men, women, and children huddle together around the lanterns of their guides as they walk through a dark, stone hall beneath the earth. Somewhere under the arches, music begins to play as young men test their banjos and mandolins in the hallowed space. However, despite the arches and columns supporting the great stone roof, the place that they tour is no cathedral. It is not a cave, either. It is a reservoir, built underground and covered by 14 acres of concrete and dirt. The 4,000 people that will be ushered through the darkness this day will be some of the last to see the inside of this place. On July 1st of this same year, the plant and reservoir will be officially opened, and the reservoir will be filled with over a hundred million gallons of fresh, clear water. That water will then flow from the reservoir to the people that need it, all over Cuyahoga County. But, until June 7th, young and old alike will be able to stalk through what some have called a “temple”, and a modern marvel of engineering.

Part of the reason that the reservoir was such an attraction was its sheer size and the amount of material that went into its construction. The Baldwin Reservoir measures roughly 1,035 feet long by 551 feet wide by 39 feet high. Each half of the reservoir’s roof is 500 square feet and is held up by 1,104 arched panels. Each of these panels is about 20 square feet. The panels are themselves supported 1,196 concrete columns that are about 35 feet high and 30 inches in diameter. The reason that the roof is divided in half is because the reservoir itself is also divided. A wall splits the reservoir into two basins, which are fed water from the plant by flumes set 21 feet above the reservoir floor. The attached filtration plant covers an area of 268,000 square feet and was constructed in a Palladian style, according to the designs of architect Herman Kregelius. The front entrance is covered by bronze doors that are 8 feet tall, with a 27-foot-tall glass arch surrounding the doors. This arch, combined with the windows set a few feet apart close to the ceiling, allow in plenty of natural light to brighten up the plant during the day. The plant and reservoir were completed in 1925 at the cost of $5 million, the equivalent of several tens of millions of dollars today.

However, the reservoir and filtration plant have been more than just an attraction to see or a big cost to the city. They have also been a source of safe drinking water for thousands of people. Prior to the construction of the reservoir, three quarters of Cuyahoga County’s population lived in a low-service zone. For most of Cleveland, and the surrounding county, water was something that had to be rationed, and something that oozed out of the tap. It was often filthy and filled with random bits of debris and waste that had coated the pipes over the years. However, when the plant and reservoir were finished, and hooked up to a nearby pumping station, all of those people suddenly had fresh, clear water bursting out from their pipes whenever they turned on the tap. People could drink their fill, water their lawns, and bathe regularly, without fear of contracting any diseases or being poisoned by industrial runoff. And they could get this from their hookups at home, with no more need to go to contaminated neighborhood wells and pumps.

The true value of safe drinking water cannot be overstated. In the year 1900, more than twenty years before the reservoir was completed, 54 out of every 100,000 people in Cleveland died from typhoid fever. In 1915, four years after the city began disinfecting its water, that rate had dropped to 8 out every 100,000. By 1920, the total rate was less than 4 per 100,000. Most of those cases that still occurred were centered in low-service districts, where water quality and availability were lower. When the reservoir was completed, and its attached filtration plant was put into action, the rate of typhoid-related deaths went down to near zero.

Today, the Baldwin Reservoir and Baldwin Filtration plant are practically invisible and tend to stay out of the news. All that one can see, looking from beyond the fence along Woodhill Road, is a long stretch of lawn that extends to a line of hedges and trees, and some walkways leading up to the filtration plant and administration building. However, beneath that lawn is one of the world’s largest covered reservoirs, and one of the biggest water supplies in the city of Cleveland. Despite its invisibility, the Baldwin Reservoir has left a large impact on the city, its people, and its history. One that is still felt today, every time that someone fills a glass from their tap.

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Long before John Patton, one of the victims in the 1916 waterworks tunnel disaster, had ever thought about coming to Cleveland, the city had been digging water intake tunnels under Lake Erie. In the post-Civil War era, pollution of the Cuyahoga River and the lake into which it flowed had increased so rapidly as a result of an expanding industrial sector and urban population that, by the late 1860s, residents were already complaining of tainted water from the lake, which had been the city's primary source for drinking water since 1856, the year construction of the Kentucky Street Reservoir project had been completed. Responding to these complaints, the city, in 1874, constructed its first waterworks tunnel. Five-feet in diameter and located 40 feet below the lake bed, it extended from the shore near the old River Bed to a water intake crib in the lake a little over a mile away where, presumably, the water was untainted.

By the mid-1890s, however, this tunnel, and a second, larger one later built to the same crib, became inadequate, as pollution of the river and lake had worsened considerably. Therefore, in 1898, the city undertook to construct a new tunnel leading to a new water intake crib three miles out in the lake. (Still visible from Cleveland's shoreline today, this crib eventually became known as the 5-mile crib, because, while located three miles from the shore, its tunnel stretches a distance of five miles to the east side Kirtland pumping station.) The project was completed in 1904, but by 1910, with questions raised regarding the new tunnel's integrity and a rising typhoid fever rate in the city, plans were soon made to construct a fourth tunnel, larger in diameter and extending further out into the lake than any of the previous ones. The new tunnel would be constructed from the old west side crib, which was abandoned when construction of the new tunnel to the Kirtland station had been completed, to a new water intake crib nearly four miles out into the lake.

Construction of this newest lake tunnel began in March 1914. It was initially lauded for its safety record, especially when compared to that of the last tunnel's construction, which had taken the lives of a total of 33 workers in four separate accidents occurring between 1898-1901. But the praise quickly ended on July 25, 1916, when Clevelanders woke up to learn that there had been a terrible accident the night before in the tunnel. In the evening hours of July 24, Harry Vokes, a 27-year-old Case Institute graduate, who was serving as acting foreman, led a work crew of eight men, including John Patton, down into the tunnel from the new crib known as Crib No. 5. Shortly thereafter, when natural gas vented up from the lake bed and somehow ignited, an explosion occurred, which buried Vokes and his entire work crew under hundreds of feet of mud and tunnel debris.

As often happens in the midst of tragedy, a number of men, including African American Garrett Morgan, inventor of a new type of gas mask, and later of other patented products including the first three-position traffic signal light, exhibited extreme courage and bravery in descending into the tunnel to search for survivors that night and the following morning. The first two rescue attempts led by Crib superintendent John Johnston and Construction superintendent Gus Van Duzen rescued none of the work crew and resulted only in the deaths of ten of the rescuers who were overcome by the gas in the tunnel. Several additional efforts in the early morning hours of September 25 by Van Duzen's stepson Tom Clancy resulted in the successful rescue of one or two members of the second rescue team lying unconscious on the tunnel floor, but it was not until Morgan, and his brother Frank, arrived with their gas masks that they, tunnel workers, firefighters and others at Crib No. 5, were able to descend into the tunnel relatively safely and bring out the remaining surviving rescuers, including Van Duzen, as well as the bodies of the rescuers who had not survived.

Once all of the rescuers, alive or dead, were removed from the tunnel, sandhogs began to dig through the mud, and sometimes patiently wait for gas in the tunnel to dissipate, in a renewed effort to reach and retrieve the bodies of the work crew. As this was slowly progressing, Cleveland City Hall launched a probe to determine who was at fault for this disaster. Fingers were initially pointed at Van Duzen, Johnston and Vokes, as well as at a city chemist who had failed to timely test an air sample from the tunnel. But, when witnesses began to fault city officials for safety shortcomings at Crib No. 5, including lack of resuscitation equipment, a telephone, and an attending physician, Mayor Harry L. Davis quickly ended the probe, concluding that no one was at fault and that "every man did what he thought best." Meanwhile, digging for the work crew continued. By August 21, all nine bodies were recovered, including that of John Patton. His body was identified by his brother-in-law James Masterson. During the recovery effort, another sandhog, Italian immigrant Luigi Bucciarelli, fell from Crib No. 5 into the lake and drowned, becoming the twentieth victim of the tragedy.

Work soon resumed on construction of the tunnel, which was finally completed in 1918. Afterwards, the two west side cribs were submerged under Lake Erie's waters, leaving only the 5-Mile Crib still visible to Clevelanders today. The west side tunnel was destined to be the last waterworks tunnel ever constructed under the lake bed. When the city initiated its next water intake project in 1948, the project was constructed by digging a trench in the lake bed from a crane mounted on a barge, and then laying prefabricated pipe into the trench. Certainly, this was a better and safer method of constructing a water intake system in Lake Erie, but it unfortunately was developed three decades too late for Irish immigrant John Patton and the other 19 men who died with him four miles out in Lake Erie.

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Present-day Amherst is located within what was once the Western Reserve in the Northwest Territory. This land belonged to the Connecticut Land Company who surveyed the land between 1796 and 1806 and divided Amherst, which was five square miles, into 100 lots. The first known permanent settler who purchased the land from the Connecticut Land Company in 1811 was Jacob Shupe. Shupe settled in northern Amherst on Beaver Creek. Using the area's sandstone and the creek's waters, he developed the first saw mill, grist mill, and whiskey distillery in the area. Many other early settlers to Amherst were veterans of the War of 1812 who had been given tracts of land by Congress for their military service. Each family settled on or near Beaver Creek and used its waters to develop their farms. Josiah Harris of Massachusetts arrived in 1818 and purchased the land where the Old Spring stands today. At the time, the area of Amherst was known as "The Corners," as the five main streets converged near the spring on Beaver Creek.

As the village grew in population through the mid-nineteenth century the spring became the center of economic activity. By the early 1900s the water was pumped into storage tanks, and later the spring was used by a brewery. In 1914, a free running pipe was installed for easier access to the drinking water from the spring.

By the 1930s both local and federal money helped restore the spring. In 1930, August Nabakowski, a local roofer whose business was located across the street from the spring, built an archway at the entrance to the spring with recycled materials, including broken tiles, pebbles, sandstone and cement. In 1936, workers from the New Deal's Works Progress Administration (WPA) built stone tables and a fireplace at the site, and reinforced a guard wall in the area between the Old Spring and Beaver Creek.

Since the rejuvenation of the public space in the 1930s, families have often picnicked or simply spent time down the small steep hill behind Town Hall to enjoy the scenery, the sound of rushing water or a fresh drink. Although most houses had indoor plumbing, some families who lived on the outskirts of town could not drink their running water and still had to rely on the Old Spring for drinking water. By the 1960s the water from the Old Spring was deemed unfit for human consumption because of the high level of bacteria. Some Amherst residents blamed people who put chemicals on their lawns, which became a popular practice in the 1950s. A sign today still warns visitors to the spring not to drink the water.

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The Division Street Pumping Station was the originally planned site for the Cleveland Municipal Light Plant, when the first talks about where the theoretical plant would be placed arose in 1906. The plant has been around in various incarnations since 1850 although the City of Cleveland did not officially form a public water system until 1856. It was rededicated as the Garrett A. Morgan Water Treatment Plant in 1991, due to the rescue of several men trapped underneath Lake Erie in 1916 thanks to Morgan's invention of the gas mask.

The idea of having a complete single municipal plant that would provide water, heat, and electricity to the city had been around for some time before the plans for a pumping station were even discussed. The original plans for the small municipal electric plant in Glenville were initially considered to be built in this combined manner, though it never was considered practical. The idea for the design of the plant was claimed to be taken from a unique plant with this design already in operation in Berlin, Germany, by 1895.

The idea for this combination plant persisted into early 1912, just months before ground was broken on the Muny Light in October of that year. The plans for the plant were then changed into a filtration and pumping station shortly afterwards, and the final product was finished in 1918. Cleveland soon developed two additional pumping stations too meet the demand for fresh water. All of the stations ensured that there would be adequate water pressure throughout the nearly 1,000-mile system that had formed by 1920. This distance of piping nearly tripled by 1940, though no new pumping stations had been added. The Garrett A. Morgan Water Works was the forerunner for the Cleveland water system, which is currently the tenth largest in the United States. It has survived to this day, where it aids the city in serving some 68 municipalities throughout Northeast Ohio.

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