Our Water Story
With sweeping hills, idyllic land and access to the Ovens River, Harrietville is a beautiful town close to the Alpine National Park.
In the early 1800s Harrietville was a settlement that was reached by rough horse tracks, and the surrounding hilly country was thickly wooded. The discovery of gold in 1852 resulted in miners rushing to the area. Within ten years, the number of miners had grown to 2,850, almost exclusively of Chinese descent. The Chinese Mining Village still exists largely undisturbed today, with mine workings, water races, building foundations and gardens.
Harrietville was never short of water, but given its location at the base of the Alpines, it was also prone to flooding. There were no less than four floods between 1905 and 1917, the last of which wiped out the bridge and left the town stranded. But with more gold to be found, the town didn’t stay stranded for long.
Harrietville’s Water Supply
Originally Harrietville’s urban supply was from individually owned groundwater bores.
In times of drought, such as the droughts of 1967-68 and 1982-83, the Ovens River flow was augmented by pumping from the Harrietville Dredge hole. The pump used was owned by the Tobacco Leaf Marketing Board.
In 1985 a public meeting was held in Harrietville to discuss a proposed reticulation water supply for the town, with more than 60 people attending.
Harrietville’s residents hospitalised due to water borne-diseases
The Health Surveyor urged the Council Shire of Bright to test the water supply, as a number of residents had been hospitalised due to water-borne diseases. The Council appointed the Bright District Water Board to carry out investigations into a suitable water supply. Consulting engineer, John Scroggie, was engaged to assist with the investigations. Tests undertaken proved conclusively that Harrietville’s water was not fit for consumption, with 70% of the underground supplies in Harrietville failing to meet World Health Organisation standards.
A New Water Supply for Harrietville
In March 1985, the Harrietville Urban District and Construction of Works for Supply of Water to the township of Harrietville was proclaimed, allowing for the construction, maintenance and continuance of water supply works for Harrietville.
The new scheme involved extending the Mt Smythe system – this saw water being diverted from Simmons Creek by gravity throughout the year, with supplementary pumping from the Ovens River during peak demand and periods of low flow in Simmons Creek.
Dredge hole at Simmons Creek, photographed in 2007
Works commenced on 3 March 1986 and were carried out by the Bright District Water Board’s Day Labour Gang. Harrietville’s initial water scheme cost $400,000, with one third of the costs provided by the Government. The works took two years to complete and involved the construction of a 0.4 megalitre storage tank. There were 2,900 metres of supply and reticulation pipelines, a pumping station and chlorination unit. The system considered Harrietville’s varying demand for water due to tourism, and had the capacity to serve a population of 200 residents, with a seasonal population of 900.
Construction of the Harrietville Pump Station
On 11 September 1986, tenders were called for the construction of the Harrietville Pump Station. The 400 kilolitre concrete water storage tank was completed off Alpine Road in February 1987, as well as the pump station on the east arm of the Ovens River.
Harrietville’s Water Supply is Officially Opened
The Harrietville water supply was officially opened in the Spring of 1989. The chlorination of the water supply meant that Harrietville’s water was now able to meet with World Health Organisation standards.
The town was subject to water restrictions over the years. These lasted for 21 months from the 2007 ongoing drought. However, with an upgrade of the water treatment plant and a change of the primary source to the Ovens River in 2013, there have been no restrictions applied since.
Devastating Bushfire
Harrietville has been left devastated by bushfire on a number of occasions. In January 2013, a bushfire burned at Harrietville for 55 days. North East Water was faced with a doubling in water demand as residents fought to protect their homes. Unfortunately, this came at a time of extremely low flow in the Ovens River due to drought. In addition, North East Water was dealing with water quality challenges, with the unfiltered water supply being impacted by firefighting activity and several vehicle crossings occurring above the raw water offtake daily. North East Water was faced with the reality of not being able to guarantee the safety of the water, and was obliged to issue a Boil Water Notice to customers. Boil Water Notices were later lifted and replaced with full time water carting, with customers asked to conserve their water use for domestic purposes.
New Water Filtration Plant for Harrietville
In April 2013 North East Water completed a temporary water filtration plant for Harrietville. The fully automatic plant alleviated the need to cart water from Bright and enabled water to be drawn from the Ovens River and treated in Harrietville, before being supplied to residents.
The temporary water filtration plant during construction
The temporary water filtration plant being lowered to site
The Harrietville water treatment plant uses water taken from the Ovens River. Water treatment includes coagulation, flocculation, granular media filters and chlorination.
The treated water is pumped to the Alpine Road tank and then gravity fed to the Harrietville reticulation.
Harrietville’s Water Supply Today
Harrietville has its own water supply system and the town is subject to high seasonal peaks in demand when tourists visit the town.
Water is sourced from the east branch of the Ovens River and gravitates to the nearby water treatment plant. There was a previous supply from Simmons Creek to Harrietville, but this was taken offline and is no longer used.
Centralised Sewerage System Explored for the Town
Harrietville relies on septic tanks for its domestic wastewater. In 2014 North East Water looked into a centralised sewerage system for the town. After carrying out an ecological risk assessment it was determined that the septic tanks were not having a negative impact on the waterway. A sewerage system was also found not to be an affordable option for the town.
The traditional inhabitants of Rutherglen have been subject to some debate over the years, largely as the region would appear to fall on tribal boundaries. The generally accepted understanding is that the Bangerang were the most populous tribe in the surrounding district, with the Wiradjuri tribe to the north of the Murray River.
Lake Moodemere, just a few kilometres west of the town was an important gathering place of Whroo, a branch of the Bangerang people. Aboriginal tribes along the Murray were considered to enjoy a relatively easier life than those in sparser inland areas with the river and dense tracts of bush providing a varied and reliable source of food.
Renowned explorer Major Thomas Mitchell’s promising account of the region in 1836 is thought to be responsible for attracting early settlers to the area. The first two – John Foord and John Crisp – took up the ‘Wahgunyah Run’, some 3,500 acres that encompassed the modern day townships of Wahgunyah and Rutherglen.
Not that it was always called Rutherglen. The township, originally known as the Wahgunyah Diggings, then Calico Town, then Barkly, would be named after the hometown of its most prolific publican, John ‘Seven Star’ Wallace, who was offered naming rights if he shouted the bar.
Though winemaking in the district preceded it, gold was the making of Rutherglen. Gold was found in what is now the main street of Rutherglen, and when the handful of lucky miners bragged of their fortune, a few thousand others joined them.
Thanks once again to steady waters and fertile soil of the Murray River, pastoralists kept the local prospectors watered and fed and by the mid-1860s, Rutherglen had a population in excess of 10,000. As dry leads were spent, within a year, less than 800 remained.
Following the merger that led to North East Water, one of the more unique items we inherited was the wine bottle water tower in Rutherglen. Though it hadn’t been an integral part of the water supply system for a number of years, the tower represented a significant landmark within the local community when, in 1969, a community project saw the addition of a steel framed network to the top of the tank to provide a ‘wine bottle’ appearance to the overall structure.
In early 2012, inspections of the steel tank revealed the onset of significant corrosion to where the ongoing safety of the tank was a growing concern. As such, North East Water engaged a structural engineer to assess the overall condition of the tower and tank and recommend remedial actions. This included the removal of the tank and associated steel frame from the top of the tower, though the overall structural integrity of the tower was considered acceptable with the addition of some support bracing and minor remedial actions. We set to work correcting these failures.
Once work was completed, the tower was sold to Indigo Shire council for the princely sum of $1.
Cork Tower, Rutherglen
Rutherglen receives it water via the Wahgunyah Water Treatment Plant, where raw water is extracted directly from the Murray River.
Rutherglen also shares Wahgunyah’s Wastewater Treatment Plant (WWTP) located 5kms north-west of Rutherglen. Wastewater is collected in three small catchments that pump to an additional catchment before being transferred to the WWTP. As if often the case for large industrial customers, Uncle Toby’s have their own dedicated main and treatment lagoon.
The Rutherglen/Wahgunyah wastewater system produces general reclaimed water which is supplied to multiple agricultural and urban customers. Reclaimed water is used for irrigating pasture and public open spaces in Rutherglen, including a schools, parks and a golf course (irrigation is also undertaken on 15ha of land at the WWTP).
It’s thought that Kiewa is an Aboriginal name meaning “sweet water”.
We know that the Lagoon Hotel was constructed in 1859 and farm selectors arrived five years later, attracted to the numerous lagoons and anabranches that sprung from the Kiewa River.
The river flats were suited to dairy herds and in 1893 the Kiewa Butter Factory was opened (it later became the North Eastern Dairy Company and then part of the Murray Goulburn dairy conglomerate). A large orchard and cool store were established in 1908 and 1913, and the irrigated Kiewa Valley orchards were established in 1924, one of the first in Victoria.
When the Kiewa Murray Region Water Authority was constituted in 1994 it became responsible for Kiewa and Tangambalanga’s water and wastewater services. By 1994 the Authority was providing untreated water to a population of 690 in the Kiewa / Tangambalanga area but was not yet providing wastewater services.
During the 1995-96 financial year, Kiewa Murray Water constructed a 1.5 megalitre water storage. The following year, the North East Region Water Authority became responsible for Kiewa’s water and wastewater service and began looking into a water treatment facility, with commissioning due by 1999.
Kiewa’s Water Supply
Kiewa/Tangambalanga was connected to the Wodonga reticulation in November 1999 through a supply pipeline from Wodonga. Water is treated at the Wodonga water treatment plant and flows through the supply pipeline to a 10 megalitre tank at Baranduda. From there, the water flows through a 14 kilometre long pipe to a 1.5 megalitre tank at Tangambalanga.
The Tangambalanga tank is filled to a seasonal set point, at which supply is shut off through the closure of an automatic control valve. The valve is located on the supply line between the towns of Kiewa and Tangambalanga; when the valve is closed Kiewa is supplied from Baranduda and Tangambalanga is supplied from the storage tank. The valve re-opens when the Tangambalanga tank falls to a pre-determined level.
Wastewater
During its first year of operation, the North East Region Water Authority formed the Kiewa / Tangambalanga Sewerage Scheme Consultative Committee. The Committee assisted with the exchange of information between the community, contractors and the Authority during the construction of the sewerage scheme. The wastewater reticulation scheme was commissioned in November 1998, and was completed during the 1998-99 financial year.
Over time the Wodonga sewerage system was expanded to include Kiewa-Tangambalanga. Wastewater from the gravity reticulation in Tangambalanga is pumped through a wet well submersible arrangement across the Kiewa River to the Kiewa pump station. The pump station transfers wastewater from Kiewa and Tangambalanga along 12 kilometres to a large gravity main upstream of the Baranduda lagoons. The Baranduda wastewater treatment plant receives the domestic waste from Kiewa, where it is partially treated through a two lagoon system. From the Baranduda wastewater treatment plant, the wastewater is sent to the West Wodonga Wastewater treatment plant for full treatment, after which it is either used for reuse or discharged to the river.
Eskdale is a small, rural town in the Mitta Mitta valley, approximately 55 kilometres south-east of Wodonga. It’s thought that the town’s name came from the River Esk in a place called Eskdale, Cumbria in England.
From around 1860, early settlers came to the area in search of gold, which was discovered at Pioneer Creek in Mitta Mitta and Mount Elmo; a tributary of Little Snowy Creek.
Eskdale’s amenities were developed to accommodate the early settlers, with the first school opening in 1881. The town was officially surveyed by G H Lavery in 1887 and was the Mitta Mitta valley’s first town.
Once mining declined, cattle farming and dairying became important industries for Eskdale, supplying the Mitta Mitta valley, with the town’s river flats and land providing farming excellent conditions.
Eskdale’s Butter Factory opened in 1903 and the construction of Dunstan’s timber saw mill, drying yards and kilns attracted a great deal of people to the town, who came in search of work. With the Butter Factory closing down in 1968 followed by a merger with Murray Goulburn, and the saw mill burning down in a fire in 1975, the population of Eskdale declined to just under 250 people.
While the Little Snowy Creek provided Eskdale’s community with a great spot for swimming, releases from the Dartmouth Dam soon after the dam’s construction in 1979 made the river hazardous. The Eskdale swimming pool was opened in the early 1980s to provide a safe place to swim.
Since the 1950s, the Eskdale community relied on water pumped from Little Snowy Creek and into a storage tank. A key driver for the water supply was the fact that the town would run out of water during drought. When the creek ran dry (not for the first time) in February 2009, residents had to rely on water that had been trucked in by North East Water.
Eskdale is Connected to Town Water
In 2009-10, North East Water installed a new water treatment plant and Eskdale was officially connected to town water. Treatment includes coagulation and filtration, pH correction and chlorination. Following treatment, pressurised treated water is fed to two tanks. From there, water is gravity fed to the Eskdale distribution system.
Eskdale’s water treatment plant, photographed in 2015
Today, Eskdale’s water is from the regulated Mitta Mitta River downstream of Lake Dartmouth. Raw water is pumped 1.8 kilometres from the Mitta Mitta River to the Eskdale water treatment plant.
Eskdale’s Wastewater
The Eskdale community relies on septic tanks for treatment of its domestic wastewater.
Bundalong is a small town located on the Murray River, 15km east of Yarrawonga. It overlooks the river where it is joined by the Ovens River and widens to the east of Lake Mulwala. It is thought that the name Bundalong is derived from an Aboriginal word meaning ‘joined together’.
An article from the Ovens and Murray Advertiser dated 2 July 1898 provides insight into the Bundalong Settlement Village that was created for settlers in the area. It appears that the good farming land, an abundance of wheat and Bundalong’s proximity to the Murray River and Ovens River were a major draw card for settlers. A good system of farming management was introduced by one of the settlers, a Mr Lee, who is described as ‘progressive and prosperous’. We know that the Bundalong Post Office opened on 2 October 1876, followed by two schools, in 1878 (Bundalong South School) and 1884 (Edmond School). The village settlement also had a congregational church and a hotel.
In 1898 there were 60 allotments; married men were allocated 15 acres while single men were allocated 10 acres. There were numerous young children who would travel three miles to the Edmond school. Both the schools would later close down; with the Edmond School closing in 1936 and the Bundalong South School closing in 1970. By 1903 Bundalong’s population was about 90.
Today, Bundalong has a number of houses, boat launching ramps, a general store, a tavern / restaurant, a caravan park and a State Forest to the east and south along the rivers. Wheat plantations remain a feature of the town’s farming sites. At the 2011 consensus, Bundalong had a population of 604.
Bundalong’s residents originally accessed their drinking water through a community scheme. The scheme used an offtake at Lake Mulwala to access water, while other residents sourced their water using private groundwater bores.
The Ovens Region Water Authority became responsible for Bundalong’s sewerage services when the Authority was constituted on 19 December 1994. By 1998, the North East Region Water Authority recorded that there were 20 properties in Bundalong. However, there is no record of the Authority providing water services to Bundalong at this time. Given the size of the town and the small number of residents, it’s likely that drinking water was obtained from Lake Mulwala.
Records from 2002 show that by this stage Bundalong’s water was chlorinated and then stored in a roofed tank, before being supplied to the township of Bundalong. At the time, 24 properties were supplied with chlorinated water directly from Lake Mulwala. Bundalong’s water system did not receive full treatment and would experience high turbidity in the water following heavy rainfall events.
North East Region Water Authority constructed the Bundalong water treatment plant, which used a dissolved air flotation and filtration treatment process. This plant was in use until February 2013.
Dual Water Supply
In November 2011, the Board of North East Water approved the next stage of the upgrade to the Bundalong water supply scheme. The upgrade would provide a dual water supply, with one pipe supplying high quality potable water for indoor uses, and a second pipe to supply river water for outdoor use. The provision of a dual water supply was a first for North East Water and enabled more than 220 residents to connect to a reliable and safe water supply, with the bonus of an alternative supply for outdoor use.
Construction of the $5.7 million project commenced in the middle of 2012 and included the installation of more than 15 kilometres of pipeline, as well as a new raw water pump station. The new scheme sees Bundalong’s potable water treated at the Yarrawonga water treatment plant and transferred to Bundalong along a 10.5 kilometre pipeline.
The Dual Water Supply Scheme was officially declared on 1 March 2013, with water made available to approximately 300 properties. The first customer to connect to the new supply in February 2013 was a Mr Keith Patterson, who was happy to have a constant supply of safe drinking water, after previously relying on a well and pump.
With the introduction of water supply via the Yarrawonga pipeline, the Bundalong water treatment plant was no longer required. North East Water built a new concrete storage tank and the water treatment plant was decommissioned. The old treatment plant was repurposed and is now used as the chlorine set and pump booster for Bundalong’s non-potable water supply.
The location of the old potable water treatment plant, which is now used as the chlorine booster and pump set for Bundalong’s potable supply.
Bundalong’s Water Supply Today
Today, Bundalong receives treated water through the Yarrawonga reticulation and pipeline to Bundalong. The treated water receives a booster treatment in the form of chlorination before it enters the clear water storage at Bundalong. From there, the treated water is sent to the Bundalong reticulation.
The raw water supply, provided to Bundalong residents for outdoor use, is supplied from Lake Mulwala.
Bundalong Sewer Scheme
In its first year of operation, the North East Region Water Authority completed the Bundalong Sewer Scheme. The Honourable Patrick McNamara, Deputy Premier of Victoria and Minister for Agriculture and Resources, officially opened the Sewer Scheme in October 1998.
The wastewater treatment plant is located on Playfairs Road, south west of Bellbridge. Today the wastewater treatment plant consists of two primary lagoons and an 88 megalitre winter storage. The system includes approximately 6.5 kilometres of gravity sewerage, four pump stations and 6.4 kilometres of sewer rising mains. The wastewater is pumped to the lagoon wastewater treatment plant where. Due the low inflows of wastewater that are received by the treatment plant, there is no reclaimed water produced.
One of the Bundalong lagoons at the wastewater treatment plant
The area that is today known as Bright was explored by Hamilton Hume and William Hovell in 1824, who were the first Europeans to discover Mt Buffalo on 24 November 1824. Prior to this the High Country was occupied by Aboriginal people for thousands of years. It’s thought the traditional owners of the land would visit the High Plains during the warmer months to hold ceremonies and to gather the nutritious Bogong moths.
The arrival of European settlers and pastoralists in the late 1820s had a devastating effect on the lives of the traditional inhabitants of the land. It’s understood that Aboriginal people were forced out as their land was cleared to make way for cattlemen and stock grazing, destroying the cultural traditions and way of life that had been enjoyed over thousands of years.
The discovery of a rich goldfield in the Buckland Valley just 10 kilometres from Bright in 1853 attracted a great deal of settlers to the area, with people arriving from Europe, China and America. Disputes and robberies were commonplace. The settlers busied themselves with mining and the building of water races. Shanties appeared along the road side to house the miners, although many slept under the stars. Evidence of the town’s mining history can be seen along the riverbeds today in the sluicing races, rock stacks and open mines.
On 25 January 1860 the Post Office was opened and the area was named Morse’s Creek. The Morse’s Creek goldfield was chosen for the town’s survey in 1866 and the town was renamed Bright, in honour of the British politician and reformer, John Bright. Streets were also named after politicians and lawyers of the era.
Gold was discovered in the Buckland Valley in 1853 by a Mr W. H Pardoe, after the gold rushes in Beechworth had eased. The discovery of gold attracted a great deal of settlers to the area, who travelled from Europe, China and America. The first form of gold mining was alluvial mining; this often involved using a shovel and sieve to dig and sift through the alluvial deposits of gold from the sediment on the bed of the river. Alluvial gold washed out of the river gravel was taken from the Buckland Valley first, followed by other discoveries along the Ovens River to Harrietville.
Goldmining in Bright 1890, photo courtesy of Bob Padula
Bright sluicing operation – 1890. Photograph courtesy of Museum Victoria
Hydraulic sluicing was introduced in Victoria around 1855, with around 6,000 diggers mining for gold. Hydraulic sluicing continued at the Ovens River in Bright during the 1870s and 1880s.
‘The Valley of the Shadow of Death’
The flocking of miners to the area created a settlement ridden with disease. Some miners brought wives and children with them and they had to battle with extreme summer heat trapped in the Buckland valley followed by harsh, cold winters. Miners would spend many hours each day waist deep in freezing cold water, protected from the elements at night only by canvas tents. Pneumonia and other illnesses were common. With no hospital or medical assistance, women and babies would often die during childbirth. It was also common for young babies to die before reaching their first birthday.
There was no sanitation and the only water available for drinking purposes was sourced from the rivers and creeks, which quickly became polluted by the thousands of miners and animals. Within six months, an outbreak of ‘colonial fever’, which was most likely typhoid, meant that most diggers, as well as a number of women and children, had soon either died or fled the area.
For years the Buckland River was known as ‘The Valley of the Shadow of Death’ and it remained abandoned until a great number of Chinese miners arrived in 1857.
The Buckland Riot
Robberies and disputes were common between miners, with Chinese miners believed to have received the worst treatment. It’s understood that Chinese miners were willing to work the abandoned claims and their success provoked jealousy amongst the European miners. Their building of a Chinese Temple and Joss House only intensified the divide. Racial tensions escalated and resulted in the Buckland Riots that took place on 4 July 1857 in the goldfields of the Buckland Valley.
A plan was formed during a public meeting to have the Chinese miners removed from the goldfields. The original plan was to lead the Chinese miners out of the Buckland Valley at gunpoint. However, what started as an orderly operation escalated into a violent attack on the Chinese miners by around 100 rioters, who viscously beat the Chinese miners before throwing them into the river. Some Chinese miners were forced into trenches, shot and buried. The dwellings and stores of the Chinese miners were destroyed, as well as the Joss House. It is said that English and the Scottish miners helped some of the Chinese miners escape. The riot only ended when Beechworth Police arrived, under the leadership of Robert O’Hara Burke, by which time the estimated 2,000 Chinese miners had either been killed or had fled the area. A police camp was set up and 12 men were charged over the riot. Three men were found guilty of unlawful assembly and one of riot. Chinese miners later returned to the area after the discovery of reef mining in 1860, with 2,000 Chinese miners among the 2,500 miners in the Upper Ovens / Buckland goldfield in 1864.
By the end of 1866 the Buckland workings were all but exhausted, and the value of the most sought after sluicing grounds fell by 50%.
Hydraulic Sluicing
The Buckland River Hydraulic Gold Sluicing Paddock was one of several sluicing sites along the Buckland River and dates back to the mid-1860s. The site is an area of 100 metres by 50 metres, containing a small sluiced open cut, pebble dumps and a tail race. Water for sluicing would have been brought to the site through a high pressure pipeline from higher up the river and then directed at the gold bearing deposits above the river.
The Canyon Gold Hydraulic Gold Sluicing Site is a large excavation containing pebble dumps and tail races. The tail races were cut through a ridge of bedrock from the open pit to the Ovens River. Water for sluicing was delivered to the site by water races and then directed at the gold bearing deposits. Today a signed walking track follows the Ovens River past the sluice site, reached from the Star Bridge.
Reef quartz mining
Once the sedimentary gold had been obtained, miners turned to reef mining. This involved the digging of shafts and tunnels to reach the quartz rock underground. In 1857 a rich quartz reef was discovered and was mined heavily until the 1900s.
In 1860 quartz mining was underway on the Ovens River and at Morse’s and Growler’s Creeks. However, with only nine of the roughly 1,200 miners being experienced in reef mining, there was still a great deal of sluicing the beds and banks of the river. Large sluice boxes were used for the higher flats, aided by a strong head of water from the water races. Small waterwheels were used to drive ‘Californian’ or ‘elevator’ pumps in the lower claims.
Today the walking paths that were used by miners can still be seen, as well as the old tail races that transported tailings and wastewater into the Ovens River.
The Pioneer Reef Mine was a large quartz mine in operation from 1905 until 1948 and produced between 20,000 and 25,000 ounces of gold. Water was taken from the Ovens River through a race to the edge of Rifle Range near Germantown, to supply the machinery. The water continued through an 18 inch diameter pipe to the battery along a distance of 1,418 feet. A Mine Manager’s Residence was built in 1900; this was later converted to a Bed and Breakfast and is still used today. Rifle Range Road still exists in the pine plantations and the remains of the old battery can be found next to Wandiligong Road.
Dredge mining
From the 1900s there was a revival of gold mining, with miners turning to bucket dredging to extract gold. The main areas for gold were in Bright along Morse’s Creek, in the Ovens River Valley and several dredges were used on the river near Freeburgh and Germantown.
1905 Germantown, Dredge on the Ovens River, photograph courtesy of Bob Padula
Between the years 1900 and 1959 around 60 enormous dredges were in operation, with huge buckets used to extract gold in and along the river. The dredges used wood fired steam power engines. The Racecourse Dredge was in use from 1909 to 1918 and produced 8,000 ounces of gold. Two other dredges at Bright extracted more than 11,700 ounces of gold.
However, it came at an environmental cost, with the mining practice destroying the river bed and local forests. The topsoil from the dredged areas would be swept away, leaving huge areas of gravel behind and the effects were visible for half a century. In an attempt to improve the devastated landscape, conifers were planted and would go on to form softwood plantations. During the First World War the first pine plantation was established, using the dredge tailings from mining. The pine plantation was also made in an attempt to combat the spread of St John’s Wort. Forestry is still a significant industry today.
While dredging ended in 1922, evidence of the town’s mining history can still be seen along the riverbeds today in the sluicing races, rock stacks and open mines.
The role of Water in Mining
Water played a significant role in the success of gold mining. In the late 1800s water played a vital role in hydraulic sluicing operations. High-pressure water was used in ‘elevators’; these used high-pressure suction lifters to raise the broken down gravel that contained gold into the sluice boxes.
By 1857 it is believed that 100 miles of water races had been created in the Buckland Valley, at a cost of £300 per mile.
In the late 1800s long, high-level water races were constructed to supply high-pressure water to the larger hydraulic sluicing operations.
Water wheels would power the stamp batteries that were used to crush the gold-containing quartz rock that was mined from underground.
A water wheel driven gold stamp battery in the Buckland, 1880-1890. Water was delivered via a ‘flume’ from higher up the hill to turn the water wheel.
Water was highly valued by the miners and there was a great deal of disputes that arose regarding the ownership of water. The introduction of a licence system for diversion in 1852 enabled the setting of fees, privileges and conditions.
Race holders benefited from selling their water to claim holders, and this including the selling of water to commercial enterprises. During the 1860s it was common for Buckland miners engaged in ground or hydraulic sluicing to rent what were called ‘ground sluice heads’ from race owners for £2 to £3 per week. This was later replaced by a share agreement towards the end of the 1860s, with the race holder becoming a partner in the claim and receiving a quarter of the gold that was mined (after working expenses).
By 1903 the population of the town was 500, with the population of the Shire sitting at 4,500. Bright was described in the Australian handbook as ‘a post and mining town’. Residents had access to a money-order post office, savings bank and telegraph station. With the arrival of the railway in 1890, Bright became a terminal station on the extension from Everton, with daily coaches running to Wandiligong and Harrietville.
The Bright Waterworks Trust was responsible for supplying the town with water, which was sourced from Baker’s Creek. Gold mining was the town’s chief industry and many tourists visited the town during the summer. Bright also boasted three hotels, two banks, a school, four churches, the Salvation Army, an Athenaeum, police buildings, a fire station, court house, a brewery and a saw mill.
Farming
When settlers first grazed their stock in the 1820s, mutton and in particular beef were very popular produce. When the majority of grazing land was destroyed by bushfire in the 1850s, local cattlemen moved to the high plains and produced high country beef.
Chinese miners brought their vegetable and fruit growing skills to the area, providing a much needed addition to the diets of miners. Farmers made a good living supplying their produce to the miners, with farmers making more money selling their produce to miners than some of the miners made themselves.
As mining declined, many miners turned to farming, with the rich soil providing ideal growing conditions for hops, tobacco, oats, maize, nuts and fruit.
After both world wars, immigrants brought their farming skills to the region. Italians introduced tobacco to the area and this industry was very successful until 2006.
Today the region has a reputation for its soil and ideal climate for producing excellent produce, which includes nuts, apples, wine grapes and berries.
The Railway
The arrival of the railway in Bright played a significant role in the development of the town. The new railway to Bright was completed in 1890, as a branch from the existing line to Beechworth. The line followed the Ovens Valley and facilitated the movement of people and produce, with easier access between Mt Buffalo, Bright and the High Plains. As a result, Bright became a hugely popular tourism destination, and well known for its excellent produce. The railway also facilitated the introduction of gold dredging in the early 1900s, transporting the required heavy machinery to the goldfields.
First train arriving in Bright in 1890, photograph courtesy of Bob Padula
The railway ran until 1983 when the line between Bright and Myrtleford closed, followed by the closing of the line towards the junction at Bowser. During the late 1990s the line became the “Murray to Mountains Rail Trail”, which is still enjoyed as a cycling and walking track today. The Bright Railway Station is now a museum.
The Bright Waterworks Trust was constituted on 23 May 1890, with the purpose of constructing, maintaining and continuing waterworks for domestic supply to the township of Bright.
The Trust’s first tender called for the construction of the Bakers Gully Reservoir, on 26 July 1890.
Construction of the Bakers Gully Reservoirs
Bright’s water supply was originally sourced from two reservoirs in Bakers Gully. The first Bakers Gully Reservoir (the lower reservoir) was constructed in 1891 and had a capacity of 9.1 megalitres. This was followed by the construction of a higher reservoir in 1912, with a greater capacity of 13.6 megalitres. The reservoirs were connected to the town reticulation system by a 250mm main. However, the creek in Bakers Gully didn’t flow for several months of the year, therefore it was necessary to pump from the Ovens River directly into the reticulation system during the drier months of the year.
First Reservoir Bakers Gully, Built in 1891
Initial Pipeline from Bakers Gully Reservoir, approximately 1891
Bakers Gully Creek 1909
Bright Waterworks Trust Constructs new Pump Reservoir
In the early 1960s there was a decrease in the storage capacity of the Bakers Gully reservoirs, partly due to silting from the effects of forestry operations and from the fires of 1939. This was occurring at a time when the permanent population and tourist population of Bright was increasing. To alleviate the decreasing storage capacity and to meet the requirements of a growing population, a pump reservoir was installed on the Ovens River in 1983.
The Bright Waterworks Trust employed local contractors Huggins and Kewish to construct a new weir at the off-take in the Ovens River alongside the pumping station. The pump reservoir had a capacity of 200 megalitres and was connected to the town’s distribution system by a rising main. The new reservoir bypassed the two Bakers Gully reservoirs, which became disconnected from the town water supply, to be used only as an emergency supply.
The stop board design of the weir meant that the river level could be raised in times of low flow, to enable the new pump to operate at its optimum efficiency.
The pumping facility at the offtake was expanded and became the sole water supply for the town.
The Bright District Water Board
On 5 June 1984 the Bright Waterworks Trust was replaced by the Bright District Water Board, which assumed control of all constituted water supply districts in Bright.
In times of drought, the Bright District Water Board would use two dredge holes at Harrietville for additional water supply. The dredge holes stored water, which would then be pumped directly into the Ovens River to boost supply.
New Gravity Water Supply Scheme for Bright
A new gravity water supply scheme from Bakers Gully was implemented by the Bright District Water Board and was in operation from August 1992. The diversion of the Bakers Gully Creek to the 2 megalitre storage tank enabled the Bright township to gravitate water, as well as having the pumped supply.
The scheme cost approximately $100,000 and consisted of a nine inch pipe running 2.5 kilometres across Bakers Gully Road. An offtake from the creek ran through two sanitation pits, with chlorination at a very low rate of 1 part per million.
Bright’s water supply would now operate on a dual system. During times of adequate flow, supply would occur by gravity to the two megalitre tank. In the event of flow falling below demand, a pumped supply would be sourced from the Ovens River, to occur automatically.
The second supply would further improve the quality of Bright’s water supply and significantly reduce pumping costs. The life of the pumps would also increase as they were only required to operate in summer.
A link-up water main was also installed in Hawthorne Lane to assist in improving Bright’s chlorine detention time.
Ovens Region Water Authority and Bright
The Ovens Region Water Authority assumed responsibility for Bright’s water supply and wastewater services when it was formed on 19 December 1994. Bright’s water was sourced from the Ovens River system, and while compliance with the World Health Organisation standards for bacteriological quality was not 100%, it was still high.
In its first year of operation, the Authority commenced discussions with the Bright Golf Club, with a proposal to use treated wastewater to irrigate the golf course.
By the time the North East Region Water Authority was constituted on 1 July 1997, the Bright water supply was still prone to experiencing ‘dirty water’; while the supply was disinfected it did not receive other forms of treatment.
Temporary Water Filtration at Bright
Historically water for Bright was taken from the Ovens River and was treated with chlorine disinfection. The Bright water supply also provided drinking water to the towns of Porepunkah and Wandiligong. While the quality of the water supply met the Australian Drinking Water Guidelines for turbidity, the bushfires that occurred in 2003, 2006 and 2007 negatively impacted the river, resulting in extremely high turbidity levels and sediment.
North East Water had to issue ongoing Boil Water Notices as a temporary measure to ensure the quality of the drinking water. This was compounded by the devastating impact of the drought on the Ovens River during 2005 and 2006, with the river at risk of drying up during 2007. In order to access water, North East Water drilled additional bores. However, the groundwater came with potential health risks in the form of Iron, Manganese and Arsenic. North East Water came up with the solution of implementing temporary water filtration at Bright, to be able to effectively treat the groundwater and ensure the quality of the water supply for customers.
North East Water commissioned Amiad to deliver four containerised filtration plants. The selected site for the plants was a tree reserve close to the chlorination facility.
The project included a raw water pump, coagulation, filter media selection, construction of the filtration units, pipework, electrical components and security fencing.
Day one of the commissioning proved to be incredibly challenging, with more than 50 millimetres of rainfall taking turbidity levels in the Ovens River to greater than 140 NTU! However, the plant was able to reduce turbidity levels from 140 NTU to 5 NTU. With optimisation of the plant, the drinking water was produced with turbidity levels lower than the acceptable 0.3 NTU.
North East Water was able to lift the Boil Water Notices that had been in place for six months, which was a great outcome for the community.
Bright water treatment plant at Hawthorn Lane, photographed in 2016
Construction of the Bright Off-River Storage and Bright Water Treatment Plant
The need for a water storage for Bright was officially confirmed in a special report commissioned by Mr David White, the Minister for Water Resources in 1983.
By March 1988 the level of concern regarding the security of Bright’s water supply was rising. Stage 1 water restrictions were required at Bright, Porepunkah and Harrietville. Water was also being pumped direct from the Harrietville Dredge Hole into the Ovens River to try and keep the flow up to the permitted minimum. The river flow was thought to have fallen as low as 11 megalitres per day. There was also concern that the river wouldn’t be able to meet needs of irrigators and diverters further downstream.
The proposal for an off-river storage was first considered in the Bakers Gully area by the Bright District Water Board in 1989. An alternative proposal for the development of a lake in the Hawthorn Lane area was also considered, however the Bakers Gully proposal had the additional benefit of being an elevated site that would enable water to be gravity fed to the town water system.
In 2007 North East Water identified that a more secure and reliable water supply was needed for the communities of Bright, Wandiligong and Porepunkah.
Following consultation with the community, the Bright District Advisory Group and the Bright Off River Storage Stakeholder Liaison Group, Freeburgh was agreed as the most suitable site for the storage to meet the needs of customers and the environment.
Construction of the 520 megalitre off-river storage reservoir commenced in early 2014. On 17 November 2014 the pumps were switched on and the filling of the storage commenced.
Water cascades in to the off-river storage for the first time
The $14 million project included a new pumping station on the Ovens River to pump water to the off-river storage, a 520 megalitre off-river water storage reservoir, a new water treatment facility and additional treated water storage tank and a new pipeline to Bright.
The project has enabled the provision of a more reliable and secure water supply to our customers. Benefits to the environment have also been realised, with more water in the Ovens River during periods of low flow, leading to improved river health and aquatic life.
Executive Anthony Hernan, Kevin Freeman, Ann Telford and Managing Director, Craig Heiner, witness the filling of the Bright Off-River Storage
The Bright Off-River Storage
The Bright Storage tank and Off-River Storage
Construction of the Bright Water Treatment Plant
The Bright Water Treatment Plant was officially opened by North East Water on 8 March 2017. The dissolved air flotation-filtration plant has a capacity of five megalitres per day.
The Bright Water Treatment Plant during construction
Board Director Gayle Lee and North East Water’s Managing Director Craig Heiner, at the official opening of the Bright Off-River Storage and Water Treatment Plant
North East Water staff and members of the community at the opening
Bright’s water supply today
Today Bright’s water is supplied by the Ovens River at Freeburgh, upstream of Bright. The raw water is then diverted into the 520 megalitre raw water storage. The raw water is then treated at the water treatment plant before being distributed to the Bright reticulation.
Bright is connected to sewer
Before being connected to sewer, the township of Bright relied on septic tanks and pan services to dispose of its domestic waste. Up until as late as 1980, 35 towns in Victoria were not connected to sewer. The absence of a sewer scheme posed a serious health risk to the Bright community and this risk increased significantly during the peak season for tourism, with up to 250,000 visitors travelling to the town each year.
A sewerage scheme for Bright was initiated in 1974, followed by the constitution of the Bright Sewerage Authority in September 1978. The principal works to be carried out as detailed in the Victorian Government Gazette included reticulation sewers, manholes, main sewers, pumping stations, rising mains, outfall sewers and treatment works, at an estimated cost of $1,870,000.
At the time, residents were anxious and concerned about the cost of the sewerage scheme; the average connection per house cost $1,500, on top of annual rates of around $120 to $130. Residents felt that they were being asked to bear the financial burden of a scheme that was required to cope with the peak tourist population of 10,000 and the 250,000 visitors to the town each year.
The commencement of the scheme was delayed due to a lack government funding available. Fortunately, the Authority was able to secure loans from the State Bank and the State Insurance Office.
In 1981 The State Rivers and Water Supply Commission allocated $800,000 to commence construction of the Bright Township Sewerage Scheme.
In January 1982 contractors James A. McMahon constructed the sewerage ponds on the Back Porepunkah Road.
The reticulation construction was then carried out by Prentice Bros & Minson Pty Ltd on 8 February 1982 and involved approximately 17.5 kilometres of piping. The first pipeline, 225mm in diameter, was installed to the bowling green, with another branch to be installed to the Alpine Hotel.
B. M Contractors constructed the rising main and stage 1 of the treatment works, oxidation ponds as well as 4.3 kilometres of pipeline. This was followed by the construction of treatment ponds. The scheme included a treatment plant that was situated in pine plantations along the Back Porepunkah Road, covering an area of around 26 acres. All plumbing works were carried out by plumbers licenced with the Bright Sewerage Authority.
The Bright Sewerage Scheme was designed to service a population of 12,000 but also had to be able to cope with tourism, with around 250,000 visiting the town each year. The scheme was unique for its use of treated effluent to spay-irrigate 120 acres of pines in the plantation by the treatment site. There was also a screen of pines used to enclose the treatment site.
The first property was connected to Bright’s sewerage scheme on 2 March 1983. By October 1986 422 connections to sewer had been connected (56% of the town).
Bright was officially connected to sewer in 1986. On 27 November 1986 the Minister for Water Resources, the Honourable Andrew McCutcheon officially opened the Fraser’s Lane Wastewater Pumping Station, to celebrate the completion of major construction for sewering the township of Bright. At the time of the opening, the Bright Sewerage Scheme was at a cost of $5.861 million.
Bright’s Wastewater Treatment Plant
The Bright-Porepunkah wastewater treatment plant is located within a pine plantation. The plant consists of a primary aerated lagoon, an offline lagoon (which has not been used since 2002) and a maturation lagoon.
Bright Wastewater Treatment Plant
In March 2018 works commenced to upgrade the wastewater treatment plant. Works will include the construction of a new aerated primary lagoon and two secondary facultative lagoons.
Today, the Bright-Porepunkah sewerage scheme comprises 57 kilometres of sewerage reticulation. Bright’s wastewater is collected at a wet well pump station in Frasers Lane, before being transferred along a 2.7 kilometre rising main to the Bright-Porepunkah wastewater treatment plant.
Reclaimed water is returned to stream through gravel beds, with some of the reclaimed water used for third party irrigation at the Bright golf course.
Running alongside Indigo Creek, a settlement of what would come to be known as Barnawartha was formed in the early 1840s. The name is derived from an Aboriginal word, variously recorded as meaning ‘tall rushes’ or ‘parting of the storms’. East of the hilly, forested township of Chiltern and north towards the Murray River, Barnawartha had extensive open land suitable for grazing and cultivation . Cereals, fodder, potatoes and dairy goods were the primary produce until a successful vineyard was planted in 1858. Wine would win out over potatoes, and the region established itself as a land of vineyards.
Unlike many other towns in the north east, Barnawartha wasn’t known for its gold. However, its rich pastoral land supplied the miners nearby, and in this way Barnawartha supported the goldrush. The town also has a link to Ned Kelly; the original Bogong Winery was established by Gustav and William Baumgarten, but only after William served prison time for supplying Ned Kelly with horses.
Barnawartha’s Water Supply
Kiewa Murray Water Region Water Authority became responsible for Barnawartha’s water supply and sewerage services when the Authority was constituted on 1 December 1994. During its second year of operation, the Authority provided water to a population of 510 and wastewater services to a population of 110.
Barnawartha’s supply was untreated and was sourced from two bores, with an additional back up bore also available. Water was fed to a roofed service basin, before being provided to the Barnawartha reticulation.
New Water Treatment Facility for Barnawartha
A new disinfection plant for Barnawartha was completed in November 1999. This allowed the water supply to be chlorinated, which brought Barnawartha’s water in line with the World Health Organisation Guidelines.
The new water treatment plant during construction
Barnawartha is connected to the Murray System
During the 2008-09 financial year, North East Water constructed the Wodonga to Chiltern pipeline. The project involved the construction of a $2.7 million pipeline that stretched 16 kilometres from the Logic Centre inland port at North Barnawartha, to the Chiltern reticulation system. The pipeline was completed in March 2009, and in June 2009 Barnawartha began receiving water from the Murray system via the new pipeline.
Today, Barnawartha’s water continued to be sourced from the Murray system, through the Wodonga Creek. Raw water is pumped 5.5 kilometres, from the Wodonga Creek to a 32 megalitre raw water storage at the Wodonga Water Treatment Plant. From there the treated water is transported through the Wodonga to Chiltern pipeline, leaving the pipeline at North Barnawartha, where it’s distributed to the Barnawartha reticulation system.
New Sewer Scheme for Barnawartha
During North East Region Water Authority’s first year of operation in 1997, the Barnawartha Sewerage Consultative Committee was formed. The Committee assisted with the exchange of information between the community, the Authority and contractor during the construction of the Barnawartha Sewerage Scheme.
The Barnawartha wastewater scheme was established in 1998 and was officially opened on 11 October 1998, by the Honourable Patrick McNamara, Deputy Premier of Victoria and Minister for Agriculture and Resources. The scheme used PVC pipework, with wastewater transported to a local lagoon treatment plant.
The old Barnawartha wastewater lagoons – now being developed into a conservation site, photographed in 2017
In 2012, a 4.2 kilometre PVC rising main to the Logic gravity sewerage system in Barnawartha North was constructed. Sewage is transported and treated at the West Wodonga wastewater treatment plant.
When the Devenish Hotel was on the verge of closure in 2004, the locals put their heads and their wallets together to save it. Now managed as a co-operative, the Devenish Community Hotel tells you everything you need to know about the history of this town – they roll up their sleeves and they get the job done.
A little short of half way between Benalla and Yarrawonga, Devenish was part of a district known as Major Plains and one of the many surveyed regions by Major Thomas Mitchell. Much to the chagrin of the squatters who had set up camp several years earlier, farm selection along Broken Creek began in the early 1860s, with four separate schools established by the mid-1870s.
Despite being one of the few north east Victorian towns denied a gold rush, the town survived thanks to the railway from Benalla to Devenish. After a series of miscalculations saw the official site of the town moved no less than three times, the establishment of the Railway Hotel in 1874 – now the Devenish Community Hotel – ensured the future of the town.
Devenish’s Water Supply
The Ovens Region Water Authority became responsible for Devenish’s water supply from 19 December 1994. Devenish’s supply came from the Broken Creek system and as at 30 June 1996, 59 properties were supplied with water. The water source was problematic as the creek was effectively an open stock and domestic channel, with no coverage or protection from the elements. Approximately 90 per cent of water was lost through evaporation and the creek water was also of very poor quality at that time.
Raw water was diverted from the channel to a 25 megalitre storage and then to a water treatment plant from where it was stored to a 35 kilolitre clear water storage. A 135 kilolitre standpipe then provided water to the town.
The Devenish Water Treatment Plant, photographed in 2001
Devenish is connected to the Yarrawonga Water Supply
In 2006, Devenish was connected to Yarrawonga’s water supply, through the Tungamah pipeline project. This involved the construction of a 360 kilometre long pipeline to connect Devenish, St James and Tungamah to the Yarrawonga water supply.
Today, Devenish’s water is supplied from the Yarrawonga system, and sourced from the Murray River (Lake Mulwala). The water is treated at the Yarrawonga water treatment plant and flows through the pipeline to Devenish. When the treated water reaches Devenish it’s stored in a half megalitre tank, where it receives booster hypo chlorination before being pumped to the Devenish water tower. From there it’s gravity fed to the Devenish reticulation.
The Devenish water tower, photographed in 2014
There are no wastewater services provided to Devenish, with residents using septic tanks for their domestic waste.
When the region’s most prolific explorers, Hamilton Hume and William Hovell, discovered what we know today as Benalla, they originally referred to its river as ‘Swampy River’. The river was renamed ‘Broken River’ 16 years later when a temporary bridge was constructed over it, (this ‘broke’ the river), to allow overland access.
Following the devastating Faithfull Massacre in 1838, a police border post was established, and with that followed settlement. Pastoral overlanders took full advantage of the grazing and pastoral lands along the river, growing wheat, orchards and vines.
It’s believed that poor penmanship lead to the naming of the town when Edward Grimes, completing the application for the pastoral run, neglected to cross the ‘t’ in ‘Benalta’ and Benalla was born. It is thought the town’s name is derived from an Aboriginal word meaning ‘water hole’.
Securing Benalla’s Water Supply
Before the Second World War, Benalla’s water supply was sourced from the Broken River. Water was pumped from deep holes in the bed of the river into two 40,000 gallon steel tanks at Riverview Road. This resulted in Benalla’s residents experiencing dirty water, as well as water shortages.
Benalla’s Water Tower
The T V Cowan Tower, named after the Trust Chairman of the time, Thomas Vaughan Cowan, was constructed in 1935. The concrete tower was 30 metres high and could hold 454 kilolitres of water to supply the town.
Construction of the Loombah Reservoir Secures Continuous Water Supply
The Benalla Waterworks Trust (established in 1882) wanted to provide Benalla with a continuous water supply. The Trust purchased just over 129 square kilometres of land in the Toombullup and Archeton area, as the site for a new reservoir. This was to become known as the Loombah Reservoir.
The Loombah Reservoir was constructed between 1940 to 1945, under the Chairmanship of William McCall Say. The reservoir had a holding capacity of 680 megalitres and enabled a continuous water supply to be secured for Benalla. Residents were invited to attend a mother’s day picnic by the reservoir to celebrate its completion, with around 600 people attending.
The Kelfeera Service Basin
The Kelfeera Service Basin was constructed next, in 1950. The basin, which is lined with concrete and has a capacity of 3.64 megalitres, was situated 11.5 kilometres from the water tower and acted as a break pressure tank.
A pipeline was then constructed from the Loombah Reservoir to the water tower. There was also a pipeline connecting the Kelfeera Basin to the water tower and a pipeline connecting the Kilfeera Basin to Loombah Reservoir.
The above diagram shows Benalla’s Storage Supply Arrangements as at 1988
Growing Demand for Water
While this system served Benalla well for several years a growing population, together with higher consumption and dry years, meant that the Benalla Waterworks Trust had to impose water restrictions. In an effort to alleviate the need for restrictions, a cast iron main was installed into the Kelfeera Service Basin during 1963 to 1964 to supplement the water supply.
F R Harrison Basin (South Street Basin)
By 1968 the pipeline from the Kelfeera Basin was no longer able to meet Benalla’s demand for water so it was decided to install a low level storage basin in South Street.
The South Street Basin was constructed in 1969-70 and was connected to the Kelfeera Basin by a 375mm steel cement lined pipe. The basin, with a capacity of 4.5 megalitres, filled overnight, and water was pumped directly into the water tower to augment the supply. Water inflow to the basin was controlled by a keystone butterfly valve and two pumps were controlled from the water tower by a non-float electrode system.
The Basin was officially named in October 1981, after the former Chairman of the Benalla Waterworks Trust, the late Commissioner Frank Harrison. Frank was Trust Chairman for a total of 17 years and a Trust Commissioner from 1943 to 1980.
Construction of the McCall Say Reservoir
It was still apparent to the Benalla Waterworks Trust that an additional reservoir was needed to meet ensure adequate water supply for Benalla. In 1971 works commenced on the construction of the McCall Say Reservoir. Construction was with the State Rivers and Water Supply Commission, under the supervision of the Trust’s Engineer, Mr K D Borley.
The reservoir was completed in December 1973, with a capacity of 1,100 megalitres and at a cost of $750,000. The additional reservoir enabled the Benalla Waterworks Trust to successfully provide water to its population of 17,000.
The McCall Say Reservoir was named in honour of William McCall Say, which is very fitting in light of the significant role William played in securing a continuous water supply for Benalla. William was originally a pharmacist who lived and worked in Benalla. He went on to become a Commissioner of the Benalla Waterworks Trust from 1928 to 1966, leading the Trust as Chairman for a total of 23 years. William was also the Mayor of Benalla from 1951 to 1954.
The McCall Say Reservoir was officially opened by the Governor of Victoria, Sir Rohan Delacombe, on Monday 3 December 1979, with more than 300 people attending the opening.
It is worth noting the foresight of the Benalla Waterworks Trust in securing a continuous water supply through the construction of two major reservoirs. Benalla has one of the highest rainfall catchments in North East Water’s service area, with the reservoirs taking full advantage of the rainfall to provide a continuous supply of water to Benalla’s residents.
Lake Benalla
Lake Benalla was formed during 1974-1975, by damning the Broken River. The lake is usually full but is drained on occasion; including in winter or in the event of flooding.
Ovens Region Water Authority
On 19 December 1994, the Ovens Region Water Authority assumed control of Benalla’s water supply and wastewater services. At the time, Benalla’s water was sourced from the Ryan’s Creek system and serviced a population of 9,000. The Benalla system was 100% compliant with World Health Organisation standards for bacteriological quality but was subject to issues with turbidity and colour following heavy rainfall events.
One of the Authority’s first steps was to introduce the pay-for-use principle as a two part tariff in Benalla on 1 October 1995. This lead to the new system being gradually implemented across other towns in the region and meant that customers paid only for the water they used.
The addition of Chlorine to the Water Supply
In 1979 the Victorian Government requested that all water boards adopt the World Health Organisation standards, which did not allow for any E.coli readings. This led to the introduction of chlorine to Benalla’s water supply.
A chlorine plant was constructed six kilometres from Benalla, and chlorine was added to the system at a rate of three parts per million.
The Brian Greed Water Treatment Plant
Benalla was one of the last towns in North East Water’s service area to receive a water treatment plant.
Benalla residents had been experiencing poor water quality for many years. Customers’ concerns regarding the quality of the water led to water quality improvements two years ahead of the original plan, with the opening of the Brian Greed Water Treatment Plant in 1999. Pleasingly, the plant was completed without the need to increase water charges for customers.
The plant was constructed next to the Kelfeera Service Basin, which enabled the energy saving features of the gravity fed system to be retained. The plant was of conventional design and the only pumping required was to move water from the treatment area to the clear water storage tank.
The Brian Greed Water Treatment Plant was officially opened on 5 February 1999, by the Honourable Patrick McNamara MLA, Deputy Premier of Victoria and Minister for Agriculture and Resources. The plant was opened under the chairmanship of Dr Brian Greed, with Jim Martin as the Chief Executive of North East Region Water Authority. Guests were invited to tour the new $4 million facility the day after the opening.
The Benalla Water Treatment Plant, photographed in 2001
New ‘Piano Key’ Dam for Benalla
In early 2013 works commenced to upgrade the Loombah Dam Spillway. The $1.8 million project used ‘piano key’ technology to increase the capacity of the dam to safely pass flood flows. The project was the first of its kind in Victoria and means the spillway can increase the flow by four times that allowed by a conventional spillway. When the dam spills, the water cascades through the ‘piano key’ design.
The project included the excavation and removal of 12.500m3 of rock and earth fill, which is enough to fill five Olympic sized swimming pools. 2,000 tonnes of concrete was laid and 95,000 tonnes of steel reinforcement was used. The upgrade was completed in July 2013.
North East Water’s Miguel De Oliveira outside the new spillway
The Loombah Dam Spillway, photographed in 2014
Benalla’s Water Supply Today
Benalla’s water is supplied by Ryan’s Creek, Whiskey Creek and other minor water courses, with raw water stored in the McCall Say Reservoir and Loombah Reservoir.
At the Benalla Water Treatment Plant, treatment includes coagulation and flocculation, dissolved air flotation, a granular media filter, pH correction, chlorination and fluoridation. The treated water is stored in a 10 megalitre roofed clear water storage, before being provided to the Benalla reticulation.
Interestingly, the reticulation system still includes pipework that dates back to the 1940s and 1950s. North East Water is currently replacing pipes that date from the 1940s to the 1970s.
Above is a photograph of a wooden pipe that was used in the Benalla reticulation system. Wooden pipes were made out of random lengths of timber that were made into staves (similar to those used in a wine barrel). The staves were bound together by galvanised steel wire, then coated heavily with bitumen. It would take a few days for the wooden pipes to swell or ‘proof’ once filled with water, after which the pipes became leak proof. It was not uncommon for wooden pipes to be left underground when new, modern pipes were installed.
Benalla’s Sewerage System
The Benalla Sewerage Authority was constituted in 1934, with the sewerage system constructed in the 1930s. We know the Benalla Sewerage Treatment Plant was in operation as far back as 1941. Thomas Putt managed what was known as the “sewerage farm” from 1941 to 1958. At this time there was the No 1 pumping station in operation at Shepparton Road and the No 2 pumping station in operation at Wedge Street.
The Benalla sewerage treatment plant – as it was when Thomas Putt was Manager, circa 1950. Photograph courtesy of the Benalla Ensign
The Ovens Region Water Authority operated a lagoon wastewater treatment plant at Benalla, with the plant treating domestic sewerage and trade waste. In its first year of operation, Ovens Water adopted a strategy for the wastewater discharge policy, in line with the Environment Protection Authority’s State Environment Protection Policy. The policy for Benalla led to the total reuse of Benalla’s wastewater on land.
The Benalla Wastewater Treatment Plant is located on Holdsworth Road, with the winter storage located on the Midland Highway. The treatment plant includes a fully mixed aerated lagoon, a maturation lagoon and a 320 megalitre winter storage. Irrigation land includes 62 hectares using centre-pivot irrigation and 82 hectares using flood irrigation.
The aerated lagoon
The 320 megalitre winter storage was constructed by North East Water during the 2007-08 financial year at the Scholes Lane site. The storage reduces discharges from the site to the Broken River, with treated water discharged from the winter storage lagoon into a small wetland. The treated water then overflows from the wetland into the Broken River through an open channel.
The maturation lagoon, photographed in 2018
Bellbridge was built from a single farming property on the eastern side of the Hume Reservoir in the 1960s. One of the youngest townships on our map, the farming property was subdivided in the early 1970s and is identified by the 752 metre-long Bethanga Bridge.
Bellbridge’s water system was developed in the mid-1970s using Asbestos Cement pipes.
During its first year of operation in 1994, the Kiewa Murray Region Water Authority provided drinking water to a population of 430 in Bellbridge, and provided wastewater services to a population of 305.
At the time, Bellbridge’s water supply was disinfected with chlorine but received no other form of water treatment. Following heavy rainfall events, high turbidity in the raw water would result in ineffective disinfection. The North East Region Water Authority recognised that works were required to improve the water supply for Bellbridge and made plans for a new water treatment plant.
The Bellbridge Water Treatment Plant
The Bellbridge Water Treatment Plant was completed in December 1999 and was officially opened on 8 March 2000, by Dr Brian Greed, O.A.M, Chairman of North East Water.
The plant uses coagulation and flocculation, a granular media filter, pH correction and chlorination. It can treat half a megalitre of water per day.
Kala Kalaroopan – Senior Engineer, Brian Greed – Chairman, Jim Martin – Chief Executive Officer, at the official opening of the Bellbridge Water Treatment Plant
Bellbridge’s Water Supply Today
Bellbridge’s water supply is sourced from Lake Hume on the Victorian side of Bethanga Bridge. Raw water is taken directly from Lake Hume and then pumped through a 1.1 kilometre long pipeline to the Bellbridge Water Treatment Plant. The treated water is then pumped from the plant into two low level clear water storage tanks. Water from these tanks is gravity fed to the low level reticulation, while water is pumped to two high level tanks before being gravity fed to the high level reticulation.
Bellbridge’s low level pumping station and chlorinator
Bellbridge’s Wastewater System
Bellbridge’s sewerage system was established in the mid-1970s using vitrified clay pipework. Today the system includes both vitrified clay and PVC pipework that was installed after 1990. There are three main pump stations; the stations that serve the Hillcrest Avenue and Bellbrae estate catchments pump wastewater into the main gravity reticulation system, which feeds into a third pump station at Mitta Avenue. Wastewater is then transferred from the Mitta Avenue pump station to the Bellbridge Wastewater Treatment Plant.
The Bellbridge Wastewater Treatment Plant
The Bellbridge Wastewater Treatment Plant was constructed in the late 1970s. The plant had a rotating biological contractor upstream of a lagoon, which was taken out of service in 2007.
The lagoon photographed in 1997
In 2001 a 19 megalitre winter storage was constructed; this is also used as a maturation pond. The storage holds treated water for beneficial agricultural reuse within the Bellbridge area and eliminates the need to discharge to Lake Hume.
Today the Wastewater Treatment Plant consists of a primary lagoon, which is split into an aerated section and a facultative section (essentially a waste stabilisation pond which reduces organic content in wastewater).
In 2001 a reclaimed water irrigation system was constructed for Bellbridge. The system is set on five and a half hectares of pasture that is leased by North East Water and uses reclaimed water that is pumped from the winter storage.
Dartmouth is the little town that could. Named after the Dart River, now cut off by Lake Dartmouth, gold was officially reported as being discovered in 1874. A short-lived but vast goldfield was created, with five steam crushing mills. An allied mining settlement was established at Zulu Creek, and a school was established in 1909, but closed within three years. It would several decades to put Dartmouth on the map.
Dartmouth came to the fore in 1970 when approval was reached under the River Murray Agreement for the building of the Dartmouth dam where several streams (including the Dart) converged at the Mitta Mitta’s headwaters. An earlier proposal for a storage near the borders of South Australia, New South Wales and Victoria (Chowilla) had been abandoned on the grounds of cost and high evaporation. It had been proposed chiefly to safeguard water for South Australia, and the Dartmouth project was conceived for holding water for slow release to the Murray River and downstream supply to South Australia. Its primary purpose became the storage of water for irrigation, and domestic and livestock supply in Victoria and New South Wales.
Construction of Lake Dartmouth began in 1973. A planned township for the contractors and workforce was provided including a shopping centre, a hall, a primary school, sports facilities and a caravan park. In 1976 the town’s estimated population was 1,650 people.
When completed in 1978, Lake Dartmouth had a hydroelectric power station and a capacity of 4 million megalitres. The town was sold after the project’s completion, and by 1991 the town had been sold again. Today there remains a hotel, motel units and a caravan park. The Mitta Mitta River has been widened by weirs to form Lake Banimboola, adjacent to the former township.
Dartmouth Dam, photographed in 2015
Dartmouth Dam was constructed between 1973 and 1979, and has felt the effects of the decade-long drought that occurred in the late 1990s. This was followed by incredibly low storage levels in 2007, when the dam was only 11 per cent full. This provided a grim and desolate picture, especially compared with the 2.8 million megalitres held by the dam in October 2014.
Kiewa Murray Region Water Authority became responsible for Dartmouth’s water and wastewater services when the Authority was constituted in December 1994. By 1995 the Authority was providing water and wastewater services to a population of 100.
Dartmouth’s water network was completed in the mid 1970s, as part of the construction camp for Dartmouth Dam. There are approximately 8 kilometres of Asbestos Cement potable water mains that were installed around 1974, with a small amount of PVC mains.
Dartmouth didn’t have a water treatment plant and the supply was not fully treated. Water was sourced from the Mt Tabor Creek, into the Mt Tabor Creek reservoir.
Mt Tabor Reservoir, photographed in 2010
Lake Tabor, photographed in 2004
Incidentally, Lake Tabor was built to support the town whilst the Dartmouth Dam was being constructed. After the water was extracted from the Mt Tabor Creek reservoir, disinfection in the form of sodium hypochlorite was applied, before the water was provided to Dartmouth’s customers.
However, the storage wasn’t able to meet the demands of the summer months during dry periods. During the 1998-99 financial year, the North East Region Water Authority invested in an alternative supply for Dartmouth, from the Mitta Mitta River. Water was then pumped to a small disinfection plant that was installed the same year.
The town would experience varying water quality at times, including discolouration of the water supply due to the system being unfiltered.
In 2010, North East Water installed a temporary filtration plant – up until this point the supply was chlorinated only.
A Secure Water Supply for Dartmouth
On 27 July 2012, North East Water’s Deputy Chair, Frank Burfitt, officially opened a new Water Treatment Plant for Dartmouth. The plant was built in-house by Brian Scobie, an employee of North East Water. The fully automated treatment plant uses treatment barriers consisting of coagulation / flocculation, pressure filtration and chlorine disinfection, to provide a high quality of water to Dartmouth’s residents all year round. The benefits to the Dartmouth community also included the secure water supply increasing Dartmouth’s appeal for tourists.
North East Water acknowledged the input received from the Dartmouth community when the treatment plant opened, and thanked local resident John Scales, who operated the previous water treatment system for many years. Incidentally, John is also a third generation mountain farmer who helped to construct the Dartmouth Dam in the 1970s.
Dartmouth’s Water Treatment Plant, photographed in 2015
Today Dartmouth’s water supply is drawn either from Lake Tabor, which is fed by Mount Tabor Creek or from the Mitta Mitta River. The water is then treated at the Water Treatment Plant, moved to the clear water storages and then sent to the Dartmouth reticulation.
Dartmouth’s Sewerage System
Dartmouth’s sewerage system was constructed in the mid-1970s from vitrified clay pipes. Today the system is almost entirely vitrified clay piping from around 1973. There are two gravity catchments; sewage from the Jitema Street catchment is pumped into the second catchment, before being gravity fed the 420 metres to the Wastewater Treatment Plant.
Dartmouth’s Wastewater Treatment Plant, photographed in 2015
The Dartmouth Wastewater Treatment Plant was constructed in 1973, to cater for the workers constructing the Dartmouth Dam. The same wastewater treatment plant is still used today. Given that the population of Dartmouth decreased significantly following the construction of the dam, the wastewater treatment plant is now surplus to the requirements of the town. The plant consists of an imhoff tank (which removes solids) and sludge lagoon, a primary and secondary lagoon and two maturation lagoons. Following treatment, the water is discharged into the Mitta Mitta River.
The imhoff tank at Dartmouth Wastewater Treatment Plant, photographed in 1997
Corryong was named after the Kuriong pastoral run, taken up in 1839 by a pastoralist from New South Wales. It’s thought that the name was derived from Aboriginal expressions referring to red body painting clay or a possum skin garment.
Though it would take until the relatively late 1860s for settlers to arrive, Corryong flourished thanks to a location in a wide valley watered by the Corryong Creek (which is joined by Thougla Creek). Farm selections began in 1867, with a school opening in 1872. In 1875 and 1876 a store and a hotel were constructed – or, more accurately, picked up and carried from declining gold settlements and replanted in the burgeoning town.
Corryong proved to be a viable dairying district. A butter factory that opened at Cudgewa was transferred in 1899 to Corryong which was found to be nearer the centre of Upper Murray dairying, turning out about five tons (about the size of a heavy-duty truck) of butter a week.
According to the Australian Handbook in 1903 Corryong was home to three wine saloons, a rare ‘coffee palace’ and ‘a police station that was lighted with kerosene’.. The handbook also informed readers they could reach Mt Kosciusko in one day by horse.
Corryong and North East Water
Kiewa Murray Region Water Authority became responsible for Corryong’s water supply and sewerage services when the Authority was constituted on 1 December 1994. In the 1995-96 financial year the Authority provided water services to a population of 2,160 and wastewater services to a population of 2,040. Corryong’s water supply was untreated and remained so until 1999.
In its second year of operation Kiewa Murray Water completed a 500 kilolitre water storage, which increased the reliability of supply.
The North East Region Water Authority was constituted on 1 July 1997. During its first year of operation, CEO Jim Martin was responsible for achieving a set of expectations by the Minister. One of these expectations was to achieve improved reliability and quality of service. With the Corryong water supply not disinfected at the time, there would often be high turbidity in the raw water, resulting in turbidity targets being exceeded. The Corryong Drinking Water Consultative Committee was formed to look at ways to ensure compliance with Government Drinking Water Quality Standards by 1999.
Construction of the Corryong Water Treatment Plant
Construction of the Corryong Water Treatment Plant commenced during the 1998-99 financial year. The new Corryong Treatment Plant was completed in December 1999, and allowed for UV and chlorine disinfection. Consistent with the wishes of the community at that time, only the UV disinfection was in use.
A new $5.2 million Water Treatment Plant for Corryong
In March 2013 North East Water completed a new Water Treatment Plant for Corryong. The new plant enabled a significant improvement in the quality of the water provided to customers in Corryong and Cudgewa. The new plant uses a dissolved air flotation and filtration (DAFF) process, which effectively removes contaminants that the previous system was not able to remove. This new process, combined with the addition of chlorine disinfection, ensures a safe, high quality water supply for the Corryong and Cudgewa community well into the future.
The Corryong Water Treatment Plant, photographed in 2014
The new plant was officially opened by the Minister for Water, the Honourable Peter Walsh and Chair of North East Water, Joanne Anderson.
Former Minister for Water, the Honourable Peter Walsh and former Chair of North East Water, Joanne Anderson
Members of the Corryong community also attended the official opening ceremony, along with Mr Bill Tilley MP, Towong Shire Mayor Mary Fraser and Councillors, Towong Shire Council CEO Juliana Phelps and North East Water Board members.
North East Water’s Managing Director, Craig Heiner, speaking to members of the community at the opening
North East Water’s Simon Edwards giving members of the community a tour of the plant
The Water Supply Today
The Corryong / Cudgewa system’s water is drawn from Nariel Creek. From there the water is pumped to a 90 megalitre Hamilton Hill Basin, which was constructed in 1984. The Basin provides protection to water quality conditions in the creek, such as high turbidity levels following heavy rainfall events. From the Basin, raw water is gravity fed to the Corryong Water Treatment Plant. Following treatment the water is transferred to a clear water storage before being provided to the Corryong and Cudgewa reticulation system.
The raw water offtake at Nariel Creek
Treating Corryong’s Wastewater
Corryong’s wastewater collection system was developed around 1960 and today includes 29 kilometres of sewerage reticulation.
When Kiewa Murray Water assumed responsibility for Corryong’s wastewater services in 1994, the Wastewater Treatment Plant, which is thought to have been constructed in the 1960s, was already in operation.
By the time the North East Region Water Authority took over Corryong’s water and wastewater services, wastewater performance was below the target compliance. The Authority planned an upgrade of the Wastewater Treatment Plant, to enable compliance with discharge licences to be achieved by December 2001. There were licence exceedances for E.coli, which were likely due to the prolific bird life in the lagoon system at the time.
The Wastewater Treatment Plant was upgraded during the 2014-15 financial year, with an aerator added to provide increased treatment capacity for future growth. The reuse was also upgraded, to include automated flood irrigation.
The upgraded Wastewater Treatment Plant and flood irrigation, photographed in 2016
The lagoon at the Wastewater Treatment Plant, photographed in 2002
Today the wastewater system includes the collection system and the Corryong Wastewater Treatment Plant and storage. Reclaimed water is used for irrigation on the land adjacent to the treatment plant.
The ‘Old Tallangatta’ was situated where the Mitta Mitta River and the Tallangatta Creek meet. The land was the home of the Pallanganmiddang and Dhudhuroa people, with the word Tallangatta derived from an Aboriginal word describing currawong trees.
The town was settled by Europeans in 1838 when pastoralists took up the Tallangatta pastoral run. As farming grew in popularity the town was provided with amenities, including The Victoria Hotel in 1856. The town was officially opened in the 1870s, with a post office and school opening in 1871, followed by churches, a library, state school, government receipt and pay offices, banks, a court house, private hospital, coffee palace, two breweries, and butter and cordial factories. The impressive 52 bedroom Tallangatta Hotel (pictured below) was built in 1888.
The old Tallangatta Hotel. Photo: Supplied by Ray Crispin
Gold and tin mining was popular in the late 19th and early 20th centuries; whilst this venture was initially profitable it came to an end because the deeper reefs contained other metals as well as gold and the technology didn’t allow gold to be extracted in a profitable way.
‘Old Tallangatta’, which was colloquially known as ‘Toorak’, was split into two sections; the township and a housing area situated higher up across the Tallangatta Creek.
With no centralised rural water supply department, Towong Shire Council was responsible for the town’s water supply. Water was sourced from springs and tanks and there was no sewerage system in place. Former resident Ray Crispin remembers the ‘old dunny can’ that was used at his home.
Construction of the Wodonga to Cudgewa railway began in 1887, reaching Old Tallangatta in 1891. The railway transported livestock to Wodonga and also served the Mitta Mitta valley. Due to a labour shortage, Cudgewa was not reached until 1921, and with the arrival of the motor car Cudgewa became the terminus. During the 1960s the railway was used to transport goods for the construction of the Snowy Mountains Scheme, as well as to transport cattle and regular goods. The last regular goods train ran in 1978 with the line officially closing in 1978. Today the line is enjoyed as a cycling and walking trail.
Following successive years of severe drought in the 1890s and then a record dry year in 1902, it became clear that a water storage was needed to enable the winter flows to be stored and released as required during the drier summer months. A secure water supply was needed to provide for settlement along the Murray River and to support the extension of irrigation.
A conference was held in Corowa in 1902 to discuss an irrigation scheme for northern Victoria and southern Riverina. A Royal Commission on the River Murray was set up with input from Victoria, New South Wales and South Australia resulting in the report ‘Concerning the Conservation and Distribution of the Waters of the Murray and its Tributaries for the Purposes of Irrigation, Navigation and Water Supply’.
The Government envisioned that the construction of the dam would secure a reliable water supply, thereby encouraging settlement and bringing prosperity to the region. It would also create a land ‘fit for heroes’, specifically for veterans returning from the First World War.
It took 10 years for New South Wales, Victoria and South Australia to reach an agreement for the regulation and sharing of the waters of the Murray River. In November 1915 the River Murray Water Agreement was ratified by Acts of Parliament and passed by the Commonwealth, New South Wales, Victoria and South Australia.
In 1916, the spot where the Murray and Mitta Mitta Rivers met was chosen as the site for the major water storage that is Lake Hume. The storage was to serve the needs of river navigation and to provide reliable water for annual irrigation downstream.
The dam was designed by engineers E M De Burgh (of the Department of Public Works NSW) and J S Dethridge (of the State Water Supply Commission of Victoria). The joint contracting authorities under the River Murray Commission were the New South Wales Department of Public Works and the Water Supply Commission of Victoria. There was a very clear divide between the two States with each setting up a construction camp on either side of the river. The discrepancies in the wages paid and the working conditions on either side of the river resulted in disgruntled workers and strikes.
Construction of Lake Hume commenced in 1919 and at the peak of construction 1,100 men were employed. The temporary township of Ebden was erected to house 500 workers and their families. Soldiers returning from war were given preference for the work, with hundreds of war veterans arriving in 1920 and helping build the dam.
Photo: www.mdba.gov.au
Without the technology and machinery that exists today, the dam was built using very manual labour. This included the hand to hand passing of rock and picks, shovels and bare hands to fill the drays. Workers spent 48 hours each week undertaking this very physical manual labour.
Steam power was widely used, with two steam grab cranes used in the early excavation of the quarry. Crushed rock was used rather than the smooth river gravel, and rocks were individually added to produce cyclopean concrete. The bricks were huge, some weighing up to 10 tonnes, and had to be cleaned with a high pressure hose and individually craned into wet concrete.
While the initial stage of the dam completed in 1936 left the town of old Tallangatta untouched, residents lived with a great sense of uncertainty for the future which ultimately impeded the future growth of the town. It was well known by residents that any expansion of Lake Hume would see their town, their homes and businesses submerged.
Discussions to move the town of Tallangatta began in the late 1940s. Toorak was the area preferred by locals as it would leave the town more or less in the same spot but this was rejected by government in case the Hume Dam needed to be expanded, therefore flooding the town. Bolga was chosen as the new area for the town, with it being well above the water level of the enlarged dam.
Between 1950 and 1961 the size of the dam was increased to accommodate increased water flowing into the Murray River and to accommodate water from the Snowy Mountains Scheme. To make way for the expansion of the dam, more than 100 houses and 950 people were moved and relocated 8km west of the old site. Hotels, churches and other brick buildings were demolished. The moving of Tallangatta began in 1954 and was completed on 29 June 1956, at a cost of two and a half million pounds.
Photo: www.mdba.gov.au
Former resident and local historian Ray Crispin was 13 years old at the time of the move. Ray recalls that the relocation of the town was a great adventure for many of the town’s children. He and a friend earned two pounds a week crawling under the houses and digging stump holes.
At the time, many of the homes were traditional Australian homes consisting of two rooms with an additional ‘lean-to’ added to the back of the home when children arrived. When the town of Tallangatta, was moved these houses were literally picked up, put on the back of trucks and moved to their new location. The extension to the house often fell off during transportation, but it was known that some residents didn’t mind as it meant they would receive a new kitchen or bathroom as part of the compensation deal. Most houses were also given a new coat of paint and gardens.
The Crispin family home being moved from old Tallangatta. Photo: Supplied by Ray Crispin
The move was a huge undertaking and a very stressful process for residents and business owners. Ray Crispin recalls the arguments regarding compensation and residents were concerned with what they would have in the new town. Ray recalls 50 business owners arguing over where their moved businesses would be located. Several people died during the process of the move, believed to be due to stress and worry. Ray’s father died of a heart attack a week after the move.
The moved town of Tallangatta was designed by Laurie Cullen, who was the Resident Engineer for the State Rivers Water Supply Commission. The town officially opened on 29 June 1956 by Sir William Slim, the Governor General. A rising Mitta Mitta River threatened to disrupt the opening. Almost 2,000 people witnessed the opening of the town and watched on as Sir William Slim laid the foundation stone of the new Shire offices. Mr Rylah, Deputy Premier, re-laid the foundation stone of the old Shire Hall and Cr Sutherland re-laid the foundation stone of the original Roads Board Hall, one of the first civic buildings in the former town. President of Towong Shire, Councillor Fraser, unveiled a plaque to commemorate the opening.
An aerial view showing the new town of Tallangatta circa 1956. Photo: State Library of Victoria
As it was a planned township there was the opportunity to introduce water reticulation. Tallangatta was also one of the first towns to get sewerage, as detailed in an extract from The Argus on Saturday 30 June 1956:
“While many other towns in the State have poor water supply and no sewerage, residents of Tallangatta will have a 1 million gallon storage and an up-to-date sewerage system.”
For the first time houses would have indoor bathrooms with an indoor-sewered toilet. The new town also boasted electric light, a civic square, modern homes, ‘one of Australia’s most modern camping grounds’, kerb to kerb sealing of streets and a new sports centre.
There were only a small number of cars in the town and bicycles were a popular mode of transport. At the town’s two hotels, men and women were segregated with a ladies lounge and main bar. Hardware stores, butchers, hairdressers and barbers, garages and plumbers served the town.
The shops and businesses of Old Tallangatta were relocated to the main road in the new Tallangatta, called Toowong Street. Photo: Culture Victoria
New brick houses were built and the majority of businesses and civic buildings were rebuilt in the 1950s style. The architecture of that era remains today and is celebrated with the annual Fifties Festival.
As North East Water took over the reins for Tallangatta, it also inherited a storied history of inconsistent drinking water quality. After being asked to move to allow Lake Hume greater storage, the town struggled with securing quality drinking water, an issue North East Water set about to rectify. A new water treatment plant was constructed and opened in June 1999.
Over the following two years, significant investment was made into Tallangatta’s wastewater services, with plant upgrades ($340K), an 84ML winter storage ($806K) and a pipeline for irrigation use ($268K). The winter storage – a clay lined lagoon for storing treated wastewater for reuse – both assisted the area’s agricultural needs and reduced the need for discharge into Lake Hume.
It’s understood the Traditional Owners of the town that’s now known as Beechworth were the Min-jan-buttu people.
It is thought that Hume and Hovell entered the hills south-east of Stanley in 1824. In May 1839, former naval officer Lieutenant David Reid was exploring Eldorado Creek when he came across the hills in the present town of Beechworth. It is said that Lieutenant Reid was so impressed by the beauty of what he saw on that glorious day in May that he named the area ‘May Day Hills’. Lieutenant Reid built a woolshed which was to become known as the Woolshed goldfields.
Beechworth’s history was shaped by the discovery of gold in 1852. The discovery brought thousands of settlers to the area, including noteworthy politicians and businessmen.
On 1 July 1853 the ‘May Day Hills’ were surveyed by a Mr Smyth and Beechworth was declared a town. Beechworth was later declared a district in 1856 and elections were held for the first Council. A land grant was received from the Government for what is now the location of the Shire Hall and Visitor Centre. The first Post Office, which was essentially a rough slab hut, was opened at Spring Creek diggings in 1853.
By 1857 the population of the town and immediate goldfields had reached 16,000 (for comparison, the current population of Beechworth is 2,789). A new gaol was built in 1859 to house the many criminals that had been working on the goldfields and a powder magazine was built in 1860 for the storage of gunpowder.
Beechworth went on to be proclaimed a municipality in 1863 and in 1865 the layout of roads and footpaths was formalised. A mental asylum was built in 1867, and its original water supply consisted of seven underground cisterns, each 23 feet deep and 12 feet in diameter. Each cistern could hold 12,000 gallons of water and they were filled with rainwater collected from roofs and fed into the cisterns through hollow veranda posts.
Today the history of Beechworth is evident in the streets that were named after former Councillors and other notable figures. The achievements of pioneers of the past still stand today in Lake Kerferd and Lake Sambell, and sites filled with gold mining history, including the powder magazine and Woolshed Falls, are enjoyed by many today.
Photo Courtesy Indigo Shire Council and David Kirkland
When settlers flocked to Beechworth in search of gold, the township was without an adequate water supply.
After its formation on 20 September 1856, the town’s first Council was tasked with achieving a secure water supply for the town.
Beechworth’s water scheme took 19 years to come to fruition. The years between the proposal of a water scheme in 1855 to the eventual official supply of water in 1874 were filled with setbacks and disputes, all at a substantial cost to the fledgling Council.
The initial proposed water scheme consisted of bringing water from Little or Ovens Rivers with a canal to be cut from the Ovens River, via Stanley and through to Beechworth. Although the Ovens Diggings Water Co. was formed specifically to undertake this work, the scheme did not eventuate.
In 1857 Council sank and installed a well and horse-driven pump at the bottom of Short Street. In November 1858 the Beechworth Municipal Council appointed a special water committee to plan a water supply for the township.
Next came what was later known as ‘Brown’s Folly’ (named after Councillor Frederick Brown). An iron tank was set up on the highest point of Church Street, near the Ford Street intersection, to store water that was pumped from the well. The tank was 20 feet by 25 feet by 6 feet and held 22,500 gallons of water. The tank and well were connected by pipes, with pipes also connecting the tank to the centre of town. However, the size and positioning of the tank impacted on the room available for vehicles to pass and this, together with negative public opinion about the aesthetics of the tank, resulted in the tank being removed within two years.
In 1859, following the failure of the water scheme, the Council accepted a recommendation from Surveyor Henry Grimes to build a dam at Hurdle Flat Swamp. However, this was fraught with issues. The area contained a number of private springs and was under the control of the Mining Board, with a number of leases already sold. After making the area into a reserve, Council’s application was turned down.
Council’s next attempt to secure the water supply was to have a private Bill passed through Parliament to assist with the construction of a dam. This took two years and cost the Council £1,256 (including legal expenses) and was known as the “Beechworth Water Rights Bill”. The Bill provided Council with the water rights – the option to borrow money to finance the scheme and the right to sell any excess water. However, there was a significant obstacle in the requirement for water rights to be settled by arbitration; this would cost the Council a huge amount of money.
There was an agreement that the Government would grant Council £5,000 on the basis that Council would raise a similar amount. Council was so confident they could raise the funds by selling water to the goldfields that they called for tenders for the construction of the dam.
The Honourable George Briscoe Kerferd, who moved to Beechworth as a brewer and wine and spirit merchant, played a significant role in securing the water supply for Beechworth. He was a great advocate for the construction of the dam and in this way facilitated Beechworth’s water storage. The Council named the dam ‘Lake Kerferd’ in his honour.
The contract for the construction of the dam was let to a Mr James Parker for £7,281 in December 1861. Work began in early 1862 and was completed by the end of that year.
A key objective of the dam was to retain the waters of the Hurdle Creek Swamp for gold mining activities. Initial plans for the dam were for a dam height of 35 feet, providing a storage capacity of 46 acres. The plans also included that the bank could be raised by 12 feet when more funds became available.
When completed at the end of 1862, the first filling of the dam produced 20 acres of water. The dam was 17.5 feet deep, and had cost £12,000 to date. There were additional costs of £2,000 due to a dispute with a contractor.
Following construction of the dam, the Council was on the verge of being bankrupt. Before they had run into extreme financial hardship, Council had developed a scheme to provide water to the town. The scheme involved building a small reservoir, to be augmented by a race from Lake Kerferd, with water to be reticulated by pipes into town. Council had planned to provide water to 75 sluiceheads at the adjacent diggings but this didn’t eventuate. Instead, Beechworth had to take its water from the municipal wells.
Between 1862 and 1872 Lake Kerferd was unused, apart from for regattas that were held on the Lake in the 1860s, with teams from all the nearby Murray towns competing. The water of Lake Hume was sold to mining companies, but this was fraught with disagreements. A significant amount of ratepayers’ money seems to have been spent on fighting legal action.
The Council encountered opposition to the Lake Kerferd scheme from the beginning. People felt that Lake Kerferd interfered with their right to water, the most well-known example of this being Connolly & Co who had a mine at the One Mile Creek. The famous case of ‘Connolly and Others versus the Beechworth United Shire’ was held at the Supreme Court in Melbourne in July 1875. The decision was made in Connolly & Co’s favour and Council was required to pay them £3,500 for their right, title and interest in the two sluiceheads of water, plus £1,000 to cover costs.
By 1873 contracts had been let to cut a race from Lake Kerferd into the town, as well as contracts for the filter beds and settling dam. By Labour Day in 1873 pipes had been laid from Lake Kerferd to the town, with Ford St, Camp St and High St being the first to be connected. This work was completed in 1874.
Beechworth’s water was officially turned on by the Honourable George Kerferd on 2 April 1874. The Honourable Councillor Frederick Brown held the hose that sent water over the Post Office tower. It is said that Cr Brown also took the opportunity to spray water over those in the crowd who had criticised him over ‘Brown’s Folly’…
Over the next two years the water was reticulated to the more remote areas of the town at an additional cost of £5,000. This was a great outcome for Beechworth but by the end of 1876 the Council was in debt by a staggering £30,489.
In 1897 the water supply was further augmented when Council purchased Trahair’s race. Later in 1900 the open race into Beechworth was replaced with iron pipes at a cost of £3,500. This was followed by the construction of the Europa Gully Tunnel in 1908, at a cost of £1,030. Following a drought in 1917, Council purchased Lorimer’s race at a cost of £1,030.
The formation of the Rocky Mountain Tunnel was one of the greatest engineering feats in Australian history. It is believed that without the tunnel, goldmining in Beechworth would have come to a halt.
The beginnings of the Rocky Mountain Company can be traced back to 1856 when a small group of miners sought the right to run a tail race from Newton Falls to the flats at Spring Creek. Over the course of 18 months and at a cost of £3,500, the miners were able to cut a tail race through solid granite rock that gave a fall of 2 inches in 12 feet. However, they weren’t able to drain the lower part of the flat with the race’s current depth.
The miners sold their rights to Messrs Telford and Ransome in 1863, who bought the three adjoining leases. A new company was formed, the Rocky Mountain Company, with a capital of £6,000 in 600 shares of £10 each.
Between October 1867 and July 1869, the existing tail race was cut to a depth of 8 feet, through 450 yards of solid rock. Tragically, a contractor was killed during the blasting operations.
Over the next seven years, the Rocky Mountain Company obtained 6,500 ounces of gold from its claim. Next, the Rocky Mountain Extended Mining Company was formed to cut a tunnel under the town of Beechworth. The courage and determination of the pioneers of the time saw them go against the advice of others and to forge ahead with cutting the tunnel, resulting in a claim 45 feet deep. Work commenced by the Rocky Mountain Extended Mining Company on 10 June 1876, using hand drills. In September 1877 equipment arrived from New Zealand, including the first boring machines in Victoria. The lack of water to operate the air pumps hindered productivity and working hours were reduced to 10 hours a day.
Following the call for new tenders, Mr John Stevens won the new contract at a price of £4 per foot and works resumed on 8 February 1877. Advances in technology included the use of compressed air to create pneumatic pressure to drill holes, a steam engine to drive the compressor, and an air extractor.
The extension of the tunnel continued over the next three years and the Rocky Mountain Tunnel was completed on 24 January 1880. The total length of the tunnel was 2,611 feet, with 2,100 feet of the tunnel being cut through rock. It took 98,280 drills and 18.5 miles of fuse to fire the 32,760 shots to bore holes totaling a length of 18 miles. A total of 8,628 tons of stone were removed.
The tunnel cost a total of £14,600 and succeeded in draining the centre of Beechworth, which enable mining to continue. The tunnel was later used by Zwar Brothers Tannery. Today the tunnel provides for drainage for the lake and for the town.
Beechworth was the first district township to emerge as a result of gold, with gold first discovered in Beechworth in February 1852. The discovery was made by a prospecting party organised by a shepherd named Meldrum above the old stone bridge at the foot of Newtown Hill. This area was to become known as Spring Creek goldfield.
Later that year thousands of diggers made their way to Spring Creek goldfield. It is said that a claim could yield 30 pounds per week. Digger Peter McCann was considered the field’s luckiest digger, washing £800 worth of gold in two weeks.
Gold was discovered at Reid’s Creek in November 1852 by one of Mr Reid’s shepherds. By this time a population of approximately 8,000 diggers had travelled to the area and were camped on the Spring Creek and Reid’s Creek goldfields.
The Community at Beechworth Goldfields, Photo courtesy of Beechworth Visitor Information Centre
Hurdle Flat and Europa Gully were added to the number of rich fields in 1853. The rush to Madman’s Gully occurred in March 1853, followed by Nine Mile Creek in April 1853. Nine Mile Creek became famous for the number of Scotsmen who moved there and for its richness of gold.
In the second half of 1853, attempts were made to obtain gold at Woolshed, just below Reid’s Creek diggings, but due to excess water preventing diggers from reaching the bottom, they weren’t successful. Success at Woolshed occurred in early 1854 thanks to the efforts of a determined American named Jack Barton. He used wood slabs from Reid’s old woolshed to timber brace his claims and was able to access gold. Jack Barton later became known as “Woolshed Jack”. Incredibly rich claims were worked here, with one digger discovering 200 ounces of gold.
One, Two and Three Mile Creeks reached their peak in 1855 when Chinese miners came to the previously worked One and Two Mile Creeks. By 1857 there were 2,000 miners at Three Mile Creek, with many miners washing up to 17 ounces of gold a day.
After the discovery of gold at the Woolshed came the discovery at Sebastopol. Then Canadian diggers discovered the Napoleon, with Eldorado being established in 1855.
By 1857 at least 14,000 ounces of gold was leaving Beechworth for Melbourne each fortnight on the gold escorts.
Between 1852 and 1866, it is believed the Ovens goldfield had yielded 3,121,918 ounces of gold.
Photo courtesy of the Beechworth Visitor Information Centre
Life on the goldfields has been described as ‘rough and often crude’ and ‘very colourful’.
The journey from Melbourne to the goldfields was a difficult one that took approximately three weeks for those who could afford the coach journey. Those without transport or the money to pay the fare had no other option than to make the journey by foot.
A Council report dated 27 November 1856 provides insight into the landscape of Beechworth at the time, with tenders called for the removal of all logs, stumps and rocks from the town’s four main streets. Shops and dwellings were largely made from canvas and wood. In his memoirs, Superintendent Sadlier refers to the ‘very unfurnished state’ of the town.
The thousands of miners erected canvas tents along Spring Creek. One of the Council’s earliest by-laws was to prohibit the erection of canvas built shops and dwellings, which as well as being unsightly were easily destroyed by fire.
There was a lack of an adequate water supply, sewerage, sanitation or basic conveniences on the goldfields and this led to an outbreak of typhoid. Doctor Harry Green was the first doctor to arrive in Beechworth. As a result of the lack of hygiene and the prevalence of disease, Doctor Green died only four months after his arrival. Between 1853 and 1860 an average of one child per week died of diseases such as measles, scarlet fever, dysentery, diphtheria and typhoid; this paints a very grim picture of the quality of life on the goldfields.
Reid’s Creek was well known for the number of criminals amongst its population, with 15 murders occurring there in the first six months.
The Reid’s Creek Riot took place in early 1853 and was the result of growing dissatisfaction and unrest regarding the system of mining licences and the method used to calculate licences.
An example of a mining licence
There was a particular dispute over a licence which led to a digger being shot by a police trooper. While the shooting was said to have been accidental, the armed miners rebelled and only the arrival of police enforcement put an end to the riots.
The Ovens diggers belonged to one of two parties, known locally as the “Punchers” or the “Monkeys”. The “Punchers” were “dry” diggers who worked the banks and gullies and wore moleskins.
The “Monkeys” were “wet” diggers who worked the streams. The Monkeys believed themselves to be superior to the Punchers and wore black woollen trousers, Napoleon boots, a silk sash and brightly coloured handkerchiefs. The leader of the Monkeys was “Big” Johnston of the Woolshed and owner of the field’s richest claim.
There was great rivalry between the two parties. Disputes between the Punchers and the Monkeys were common and kept police on their toes, especially as all diggers carried firearms.
In the early discovery of gold, lone diggers would use picks, pans and cradles to search for alluvial gold. However, with technological developments and advancements came new mining methods such as hydraulic sluicing and the use of explosives for hard rock mining.
Beechworth was famous for its use of hydraulic sluicing. This was the process of moving dirt and sediment using water. Large quantities of water were required and this involved cutting deep tail races through solid rock, which was an engineering feat at the time.
By 1880 it is thought that 900 miles of water races had been cut through soil and rock in the district of Beechworth.
The ‘Chinese Section’ at Beechworth
It is believed there were around 7,000 Chinese miners on the Beechworth goldfields at their peak. The Chinese brought vegetable and tobacco growing to the area. A separate Chinese camp was established above where Lake Sambell is situated today. The camp was essentially a miniature town with restaurants, shops, Chinese theatres, boarding houses and a Joss House (a Chinese Temple).
Chinese miners were regarded very unfavourably and with suspicion by other miners. This was largely due to their willingness to work the claims that had previously been abandoned by others. Also contributing to their hostile treatment by other miners was the fact that Chinese miners also tended to be there for the short-term, earning money to take home to their families.
In 1859 the Chinese Protector’s Office was established. The role of the Chinese Protector was to ensure good relations between Chinese miners and other miners, and to collect the miners’ rights and business licenses. The Chinese Protector’s Office later became the Mining Registration Office in 1864.
The Chinese Burning Towers were used by the Chinese to make offerings to the spirits of the dead; these included food offerings, paper money, paper prayers and burning incense.
Chinese ceremonial burning towers
Today around 2,000 Chinese miners are buried in the ‘Chinese section’ of the cemetery at Beechworth.
The Golden Horseshoes Legend
The Golden Horseshoes Legend dates back to the State’s first election for Legislative Council in 1855. The election was held during a time of great political turbulence with huge rivalry between the two miners groups, the Punchers and the Monkeys. Longtime activist for miners’ rights, Daniel Cameron, was strongly supported by the Monkeys, including “Big” Johnston who owned the Woolshed field’s richest claim. Legend had it that “Big” Johnston supplied the gold horseshoes fitted to Daniel Cameron’s horse. It is said that the Monkeys marched to Beechworth from the Woolshed falls carrying banners and waving flags embellished with gold in support of Cameron. When they reached the Old Vine Hotel, one mile from Beechworth, the golden horseshoes were fitted. Legend has it that the golden horseshoes were one ounce lighter by the time the procession reached Beechworth.
There was great passion displayed by all involved, partly thanks to the free beer that was being handed out during the procession. Both candidates appeared on the balcony of the Star Hotel and by a show of hands, Daniel Cameron was announced the elected candidate.
A recount was ordered by the Punchers and was held the following day at the Courthouse, with Cameron again declared the successful candidate. It is said that “Big” Johnston celebrated by ordering £300 worth of champagne.
The Golden Horseshoes Festival has been held in Beechworth over the Easter weekend every year since 1873 and is still celebrated today.
Ned Kelly has a strong connection with Beechworth’s history. The son of an Irish ex-convict, Ned was born in December 1854. Ned Kelly’s father died when Ned was only 12 years of age, with Ned having to leave school to become the breadwinner for his family.
Ned served a six month sentence in the Beechworth Gaol at the age of 16, for receiving a stolen horse. He was an apprentice under bushranger Harry Powell and later formed the Kelly Gang, consisting of Ned, his brother Dan, Joe Byrne and Steve Hart.
After shooting and killing three police troopers near Mansfield the Kelly Gang went on the run. The Kelly Gang was supported by sympathisers, 22 of which were arrested and placed in the Beechworth Gaol in 1879. They were released after just over three months due to a lack of evidence against them.
The Kelly Gang was spotted by an informant at the house of Aaron Sheritt on Sheen Station Creek a few miles from the centre of Beechworth. There was, however, a delay of three days as the informant stopped off for drinks on his way to Beechworth, became speechlessly drunk, and was arrested and locked up.
The Kelly Gang had left Sheritt’s house and police spent years searching for the Kelly Gang in the surrounding hills. It is believed that the Kelly Gang used what are known today as the ‘Kelly Caves’ to hide at various times.
The famous Glenrowan Shootout occurred on 28 June 1880 with a violent battle between the Kelly Gang and Victoria Police. The Kelly Gang wore their homemade metal suits of armour, acquired with the proceeds from bank robberies. Ned was severely wounded and captured by police. The rest of the Kelly Gang members were killed during the shootout.
Ned Kelly’s initial hearing was held at the Beechworth Court House. He was later sent to trial at the Melbourne Supreme Court and was sentenced to death by hanging at the Melbourne Gaol on 11 November 1880. Ned Kelly’s body was buried in a mass grave.
Four-horse coaches ran between Beechworth and Melbourne during the 1850s. By 1856 there was a daily service, with coaches run by Green & Connelly and by Foster’s (later to become Fosters & Vinge).
Journeys were hazardous thanks to the risks that included being bogged, flooded rivers and falling victim to bushrangers. It was said that bushranger Harry Powell was known for felling a tree in a spot just after the coach turned a sharp bend (said to be at Buckland Valley) so that he could hold up passengers and rob them.
The coach journey to Melbourne took three days and cost between £5 to £8, depending on the condition of the road. The journey time was later reduced to 36 hours.
By May of 1856 there was a two-hourly coach service between Sebastopol, Woolshed and Beechworth. By 1857 coaches ran twice a week between Beechworth and the Buckland and daily to Nine Mile, Stanley. Later coach journeys extended to Albury, Yackandandah and Chiltern.
Crawford & Connelly became the main coaching line throughout north east Victoria.
The first train arrived in Beechworth on 13 July 1876. The ceremony for the official opening was overseen by His Excellency Sir George Bowen on 29 September 1876. It was a grand affair with a banquet attended by the Minister for Railways, Mr Jones, the Honourable George Kerferd, the Mayor of Melbourne, mayors of the surrounding towns and the French and American consuls. This was followed by a ball for 350 couples, ending with a moonlight train ride to Everton and back to Beechworth.
Beechworth’s desire to be connected to the railway is evidenced in a petition that was sent to the New South Wales Government in 1862, requesting that Beechworth be connected to Albury by railway. The Honourable George Kerferd was instrumental in having Beechworth connected to the railway. After becoming Minister for Mines and Railways in 1869 he had the branch line to Beechworth included in the Railway Construction Bill. He told his opponents “the advancement of Beechworth means more to me than my political career.” In 1874 tenders were called for the first section of the railway line. The contract was awarded to Messrs A & J Overend for £33,000 and work began in August 1874.
The Honourable George Kerferd, Premier of Victoria, was one of the first passengers to travel on this first section when it was officially opened on 1 July 1875. Councillor Frederick Brown, the then President of Beechworth Shire, met Mr Kerferd when he arrived at Everton.
The contract for the second section of the railway line was awarded to Messrs Fishburn & Moreton on 18 June 1875 for £70,018. Work began on 23 June 1876 and was completed by September of that year. A miniature town was created to house the 500 workers who constructed this section of the railway, complete with stores, hotels, workshops, contractor’s offices and stables. Canvas and bark dwellings were erected to house the men. The workers used horses, bullocks and mules to manoeuvre the earth scoops and to pull the drays and wagons. Bricks were made in kilns to create 33 bridges and 45 culverts.
Due to a decline in freight and passengers, the Beechworth to Yackandandah section closed in 1954 and the section between Everton and Beechworth was withdrawn in 1987. In the 1990s the line between Bowser and Beechworth became part of the Murray to Mountains Rail Trail.
The Kiewa Murray Region Water Authority became responsible for Beechworth’s water supply and wastewater services when the Authority was constituted in 1994.
Beechworth Water Treatment Plant
The Beechworth Water Treatment Plant dates back to the late 1800s.
Photograph of the original stand pipe, located in front of the Water Treatment Plant
During its first year of operation the Authority converted the existing Water Treatment Plant to a direct filtration process and let contracts to increase the plant’s capacity to 12 megalitres a day. At that time, Beechworth’s Water Treatment Plant was providing water to a population of 4,200.
Photograph of an old wooden pipe that would have been used to supply water, now located at the Beechworth Water Treatment Plant
Upgrades to the Water Treatment Plant
Kiewa Murray Water upgraded the water treatment plant between 1992 and 1995, at a capital cost of $1 million.
A major upgrade of the Water Treatment Plant was also undertaken during 2001-2002 financial year.
The Beechworth Water Treatment Plant
Beechworth’s Water Treatment Plant is Converted to a DAFF Plant
In 2005 the North East Region Water Authority upgraded the Water Treatment Plant and converted it to a Dissolved Air Flotation and Filtration (DAFF) plant, at a cost of approximately $2.3 million. This took the design capacity to 10 megalitres per day.
Beechworth Water Treatment Plant – upgraded in 2005
Aerial view of the Beechworth Water Treatment Plant, photographed in 2014
Ensuring the continued safety of Lake Kerferd
Lake Kerferd is a 900 megalitre storage built in the 1860s and is the sole source of water supply for the township of Beechworth. Minor works were carried out on the Lake by Kiewa Murray Water around 1995, followed by the addition of a new outlet for the Lake Kerferd storage by North East Region Water Authority in 1998-99.
In 1999 the North East Region Water Authority commenced remedial works on Lake Kerferd as part of its dam safety improvement program. The first stage of works involved constructing a new gravity outlet through the right abutment of the dam. The second stage involved widening the spillway and constructing a concrete crest and training walls, straightening the spillway alignment and strengthening the embankment. The final stage of works involved raising the embankment crest with the construction of a concrete wave wall, to increase the freeboard required to retain water levels of the probable maximum flood event.
Lake Kerferd, photographed in 2014
New Concrete Water Storage Tank
During 2017-18 North East Water invested in a 3.5 million litre water storage tank for Beechworth. The tank, approximately 35 metres in diameter and 6 metres high, was constructed close to the existing Water Treatment Plant. At an estimated cost of $1.9 million, the tank increased the treated water storage capacity for Beechworth and was part of a major project to help secure the town’s water supply well into the future.
The new 3.5 megalitre concrete water storage tank
Beechworth’s Water Supply Today
Today Beechworth’s water supply is sourced from a diversion on Nine Mile Creek and Frenchmans Creek, and a small local catchment of Lake Kerferd on Hurdle Creek.
The Beechworth catchment – water flowing towards Lake Kerferd
Water is diverted from Nine Mile Creek to Lake Kerferd, through weir boards and a network of enclosed tunnels and open channels, which serve as a reminder of Beechworth’s strong history of gold mining. There is limited access to the lake, with no fishing or swimming allowed.
The Nine Mile Creek diversion – water flows towards Lake Kerferd, with a diversion towards Yackandandah
The raw water from Lake Kerferd is gravity fed to a 4 megalitre raw water basin located at the Water Treatment Plant. There, treatment consists of coagulation and flocculation, dissolved air flotation and filtration and chlorine disinfection.
From the plant, the treated water moves into the No 1 clear water storage, with a capacity of 92 kilolitres, and then gravitates into a second clear water storage, with a capacity of 1.1 megalitres. The treated water is then gravity fed to the Beechworth high level reticulation, gravity fed to the 1.0 megalitre Mayday Hills tank and then gravity fed to the Beechworth low level reticulation. Silver Creek reticulation is supplied from the No 2 clear water storage with the assistance of a booster pump.
Beechworth’s Sewerage Scheme
A sewerage scheme for Beechworth was first proposed in 1925, however there was no funding available due to a decline in mining activities. It wasn’t until 1965 that the town’s sewerage scheme was approved.
The wastewater collection system was constructed between 1967 and 1970, and used vitrified clay pipes. The full gravity system included conveyance to the Wastewater Treatment Plant.
Beechworth Wastewater Treatment Plant
The Beechworth Wastewater Treatment Plant was constructed in 1968. When the North East Region Water Authority assumed responsibility for Beechworth’s wastewater services in 1997, the plant consisted of lagoon treatment, with effluent being disposed to land during the irrigation season and to surface waters during the rest of the year. The plant would exceed discharge limits for colour and suspended solids, as well as ammonia levels. The Authority identified that considerable upgrading was required to improve the effluent quality by 2001.
In 1999 the Authority constructed a chemical dosing facility for tertiary treatment, which provided improved compliance with discharge licence requirements.
ERA process leads to Licence Amendment for North East Water
Effluent from the Wastewater Treatment Plant is discharged to waterway via its discharge point to La Serena Creek. The lagoon system at Beechworth’s Wastewater Treatment Plant had historically failed to meet with EPA licence compliance, with the effluent containing elevated levels of nitrogen (from ammonia) during the cooler months.
North East Water explored a mechanical plant solution however this was very expensive and not financially viable. North East Water initiated a process called the Ecological Risk Assessment (ERA). The ERA process uses science and a consultative process to understand the effects that stressors (in this instance the discharge) are having on environmental values (in this case the waterway receiving the discharge). The ERA process found that the discharge to the receiving waterway was posing a relatively low risk to the receiving environment.
As a result of the Ecological Risk Assessment, the discharge licence limits were amended and an investment of approximately $6 million for a mechanical plant solution was avoided. The licence amendment was the first to occur in the State.
In 2013, North East Water improved the removal of nitrogen levels with the installation of fixed media “Aquamats”, as well as diffused aeration in Lagoon 4 of the secondary lagoons. The project was at a relatively low cost of $500,000.
The Aquamats at the Beechworth Wastewater Treatment Plant, photographed in 2014
Pipeline upgrade for Beechworth’s Sewer System
In March 2017 North East Water consulted with the community to discuss options to increase the capacity of the sewer pipe that runs through the Beechworth Historic Park. The planned changes to the sewer pipe will address an elevated risk of sewer spills during heavy rain events, due to a lack of capacity within the pipeline.
An upgrade of the Beechworth Wastewater Treatment Plant is planned as part of the Beechworth Wastewater system upgrade, which is scheduled to occur within the next four years.
Situated along the Kiewa River, Baranduda was a rural hamlet settled by German farm selectors (by way of South Australia). The pastoral runs were taken up in 1845, and the name Baranduda is thought to be derived from an Aboriginal expression relating to a swamp or water rat.
Water brought settlers to graze cattle, which led to a prosperous dairy industry. The well-wooded land at the base of the Baranduda Range saw the introduction of a sawmill, serving Wodonga with timber sleepers for railway construction. It would take 35 years for the population to warrant a school, and a further 32 years before an inter-denominational church would spring up.
Despite its ideal location (near the Murray and the future Hume dam) and attempts by the Albury Wodonga Development Corporation (established in 1974) to create a satellite township with a projected population of 30,000 within 15 years, Baranduda remains a small town and one of the most idyllic hamlets of north east Victoria.
Baranduda is Linked to the Wodonga Reticulation
During the 1999-2000 financial year, the North East Region Water Authority undertook negotiations with the Army, who were seeking upgrades to their water and wastewater systems. Baranduda was linked to a proposed Wodonga wastewater works upgrade and to the Wodonga reticulation, along with Bandiana and Latchford Barracks.
Baranduda’s Water Supply
Today Baranduda’s water supply is from the Murray system. Water is sourced from the Wodonga Creek, an anabranch of the Murray River. Raw water is pumped 5.5 kilometres, from the Wodonga Creek to a 32 megalitre raw water storage situated at the Wodonga Water Treatment Plant.
Water is pumped from the Wodonga Water Treatment Plant into the 10 megalitre low level storage at Baranduda. There, the water is treated with pH correction and booster chlorination. The treated water from the low level storage tank supplies the low level reticulation of Bandiana and Lightwood Drive, Wodonga. Water is also pumped from the 10 megalitre low level storage to the 1.26 megalitre Baranduda high level storage, and from there it gravitates to the Baranduda high level reticulation.
Baranduda Wastewater Treatment Plant
The Baranduda Wastewater Treatment Plant is located approximately 4 kilometres to the east of Baranduda and 11 kilometres south east of Wodonga, on Whyte’s Road, Baranduda.
The Baranduda Wastewater Treatment Plant, photographed in 2015
The plant was constructed in two stages in the 1990s and uses a lagoon based treatment process. The treatment plant consists of a partially mixed aerated lagoon and aspirator, a second smaller lagoon and a large winter storage.
The plant receives domestic wastewater from Baranduda, Kiewa, Tangambalanga, Bandiana, Killara and Bonegilla and has a design capacity to service a population of 19,100. The wastewater is partially treated through a two lagoon system, with aeration in the primary lagoon. From there, the partially treated effluent is pumped from the Baranduda Wastewater Treatment Plant to the Wodonga sewerage reticulation system, where it flows to the West Wodonga Wastewater Treatment Plant and is fully treated there.
A new inlet screen was added in 2014, as well as a primary bypass line, which enabled the desludging of the primary lagoon during the 2015-16 financial year.
Inlet screen at the Baranduda Wastewater Treatment Plant
Desludging of the Primary Lagoon
The primary lagoon was air dried for two months during 2015-16, with screening of the waste occurring in the last month. 1,500 tonnes of screened biosolids were transported to West Wodonga for stockpiling, with 150 tonnes sent to landfill. The primary lagoon was then brought back online with an upgrade to the aeration to complete the works.
Before desludging
After desludging
With roughly the same number of residents now as it hosted over a century ago, it’s easy to wonder how Goorambat came to be. But Goorambat still has the two things that brought settlers to it back in 1861 – good land and good water.
Selectors first took up farms near Broken Creek, forming the first Goorambat European settlement. With great swathes of land and little tree cover to interrupt it, the area drew pastoralists (mainly dairy) and agriculturalists, both of which tapped Broken Creek to supply and replenish their farms.
By 1869 Goorambat joined the Shire of Benalla and by 1882 the water supply was under the purview of the Benalla Water Trust. With their assistance, Goorambat was the site of the first successful irrigation weir in northern Victoria. Casey Weir on Broken River (near the junction with Stockyard Creek) was built in 1886 to divert water into Broken Creek for stock and domestic supply further north.
Historically Goorambat’s water was supplied from a diversion weir on Broken Creek.
By the time the Ovens Region Water Authority assumed control of Goorambat’s water supply in 1994, the town’s water supply was from groundwater, as had been the case since 1992. Water was sourced from a groundwater bore, with the water pumped to an elevated tank. From there the water was gravity fed to the township’s reticulation system. At the time the water supply serviced a population of 120 people.
The former supply from a diversion weir on Broken Creek remained an alternative source of supply in the event of an emergency.
In 2013 North East Water began investigating opportunities to increase the quality and reliability of Goorambat’s water supply. This involved looking at options to increase the supply from groundwater, which at the time was from a shallow groundwater bore.
More Reliable Water Supply for Goorambat
The original water supply from a shallow bore was subject to unreliability during periods of drought.
Towards the end of 2017 North East Water completed an 11 kilometre pipeline to link Goorambat to Yarrawonga’s water supply. The pipeline cost $1.5 million and was an extension of the existing pipeline that previously ended in Devenish.
The treated water from Yarrawonga is transferred to the tank at Goorambat, pumped to the water tower and then gravity fed to the reticulation.
Goorambat’s water tower, photographed in 2014
The water now supplied to Goorambat is of a higher quality, thanks to the increased treatment processes in place. The new pipeline also provides Goorambat’s residents with a more reliable water supply, with around 70 homes and businesses benefiting, which is a great outcome for the community.
Goorambat’s residents use septic tanks to treat their domestic wastewater.
Pioneer pastoralists and brothers James and George Rowan – Glenrowan’s namesakes – had two significant issues to contend with in 1848, and neither of those were the Kelly Gang (that would come much later).
The first was 16,000 acres of grazing land and little to no water. The Warby Ranges provided run-off for a small amount of agricultural pursuits by filling what would come to be known as Lake Mokoan. ‘Lake’ was a generous term, though, as the shallowness caused heavy evaporation and the brothers carted water from what was more likely several swamps.
The second was the isolation. By the time the town was declared in 1861, the population was a total of 12. Fortunately, Cobb & Co set up shop a year later and used Glenrowan as a pit stop to change horses and for passengers to eat and have a rest.
It would be the Kelly Gang that put Glenrowan on the map and cemented the town in the nation’s mind. In 1880 Glenrowan was the site of the siege of the Kelly gang at Jones Hotel. In the two-day siege that followed, three of the four gang members were killed and Ned Kelly was captured and brought to trial. Glenrowan acquired the reputation of being part of ‘Kelly Country’ and the town’s infamy created a mostly unheard of industry – tourism.
The Ovens Region Water Authority became responsible for Glenrowan’s water supply when the Authority was constituted on 19 December 1994.
In its first year of operation, Ovens Water completed a dedicated rising main from Fifteen Mile Creek to a new Water Treatment Plant that had been substantially completed. This meant that water no longer had to be pumped through the reticulation system. With all water now going through the treatment plant, there was a significant improvement in the quality of the water provided. This was followed by the completion of a new high level storage the following year.
Supply was from Fifteen Mile Creek. Water was diverted from the creek and pumped to the Edwin Scott Basin, which has a capacity of 22 megalitres. From there, water was pumped to the high level storage (with a capacity of 42 megalitres). Water from the high level storage would pass through the treatment plant, receiving chlorination before it was supplied to the town’s reticulation system.
New Water Supply for Glenrowan
The existing water supply from Fifteen Mile Creek had ongoing quality and quantity issues. There had been increasing outbreaks of blue-green algae in the reservoir and low flows in the creek during dry periods would often result in the need to impose water restrictions.
On 30 May 2011 Glenrowan received a new water supply, following the completion of a 12 kilometre pipeline from Wangaratta. The construction of the pipeline and storage tanks cost $2.25 million and resulted in improvements in the quality and quantity of water being provided. The water is now sourced from the Ovens River and treated at the Wangaratta Water Treatment Plant. From there the water is piped to two new storage tanks at Warby Springs, before being fed into the Glenrowan system. As a result of the new scheme, the Glenrowan community is provided with a much more reliable and higher quality of water supply.
A reticulated Sewerage System for Glenrowan
In May 2013 contracts were awarded for the construction of Glenrowan’s $3.3 million sewerage project. The project involved transforming the former Water Treatment Plant into a Wastewater Treatment Plant and holding dam. The Edwin Scott Basin site used for the Wastewater Treatment Plant was formerly used for raw water storage and transfer to the upper reservoir site for Glenrowan, before the potable water supply from Wangaratta. The raw water dam was converted to a winter storage with installation of an HDPE liner. The dam is also able to be supplemented with raw water to assist the reclaimed irrigation scheme.
The project used gravity reticulation, with wastewater piped to the new Wastewater Treatment Plant. North East Water made use of the existing infrastructure system of the town’s water pipeline, storage dam and 30 megalitre storage system, which was no longer in use now that the town’s water was supplied through a new pipeline from Wangaratta.
The wastewater scheme was completed in November 2014 at a cost of $4.1 million. Approximately 140 customers connected to the sewerage system, with the system able to accommodate future growth and treat almost double that capacity of wastewater. The plant is the only one in the region to use a Rotating Biological Contractor to treat the wastewater.
The Wastewater Treatment Plant and reuse scheme was constructed by Mawson Constructions of Shepparton, with Alpine Plumbing of Albury carrying out the sewerage reticulation works, and more than two kilometres of pipes laid throughout the town.
The treated wastewater is used for irrigation, stored in a plastic-lined dam and then used for sub-surface irrigation.
The new sewerage scheme ended the use of septic tanks and ensured that the management of Glenrowan’s wastewater was compliant with environmental standards, resulting in significant health and environmental benefits for the town, its residents and tourists.
Glenrowan Wastewater Treatment Plant Reservoir
The first settlers of Chiltern were, in fact, squatters. Taking up land near Black Dog Creek (and assuming the temporary name of the Black Dog township), the number of squatters (and the traffic that passed through) grew enough for a bush inn to be established. Ironically, the settlement later became a police outpost.
A township on Black Dog Creek would be declared in 1851. At least until John Conness discovered gold a little further away, and the town grew up around the miner’s track (what would later be called Conness Street).
At its height the town had an estimated population of up to 20,000 prospectors. But as the gold quickly diminished, so did the population, and by 1865 the town and its 2,200 residents had diversified. Mixed agriculture and vineyards were being developed, two steam-powered sawmills were in effect, and quartz-reef mining replaced gold. Though the population would drop by another 1,000 over the next 20 years, Chiltern was determined to find a way to stick around.
Before Kiewa Murray Region Water Authority was constituted in December 1994, the Rural City of Wodonga was responsible for providing water and wastewater services to Chiltern. By 1995, the Kiewa Murray Water Authority was providing water services to a population of 1,380 and wastewater services to a population of 1,135.
New Water Treatment Plant for Chiltern
During its first year of operation, Kiewa Murray Region Water Authority commissioned a new water treatment plant for Chiltern. The plant had a capacity of 2.5 megalitres a day and cost $.06 million to construct, with two thirds of the cost funded by the Government. The new plant significantly improved the quality of water being supplied to Chiltern customers.
Springs at Barambogie Reservoir
Chiltern’s water supply was from the Barambogie Springs and 33 megalitre Barambogie reservoir, with a service basin and standpipe adjacent to the urban area. Bore water was also available for use, which was pumped to the Barambogie reservoir before being fed into the treatment plant.
The Old Chiltern Water Treatment Plant
A few years later, the North East Region Water Authority established the Chiltern Consultative Committee to look at the overall Chiltern water supply system. This led to a professional study into the local catchment being undertaken, which looked at using the catchment to its full potential. The group looked at the spring and bore water that were used as water sources for the town, to investigate existing security of supply issues. This resulted in the open storage being updated as a roofed tank, to prevent the recontamination of disinfected water that was stored in there. Engineers were also engaged to better understand the supply issues at Chiltern, and to help with future planning.
Chiltern is connected to the Murray System
In April 2009, Chiltern began receiving water from the Murray system, via a new $2.7 million pipeline. The 16 kilometre long pipeline stretches between the Logic Centre inland port at North Barnawartha, to the Chiltern reticulation system, and enables customers in Chiltern to receive water that has been treated at the Wodonga Water Treatment Plant. The addition of the pipeline provides Chiltern with a higher quality and quantity of water, as well as ensuring long-term water security for the Chiltern community. The Barambogie reservoir is no longer in service.
Wastewater
The Chiltern wastewater treatment plant was constructed in 1983. The plant consists of a primary and secondary lagoon, as well as a winter storage.
The primary and secondary lagoons and winter storage, at the Chiltern wastewater treatment plant
Chiltern’s wastewater system was developed in 1986 and comprises vitrified clay sewers. There are three main pump stations at Epson Road, Barkly Street and Skerry Street; all flows are pumped through the Skerry Street pump station to the Chiltern wastewater treatment plant.
All treated wastewater is used for agricultural irrigation. While there are two irrigation areas available for reuse at Chiltern, only the one centre pivot irrigation is in use, with plans for reuse expansion over the next few years.
To understand the history of the way water was used in regional Victoria, it helps to provide a glimpse of what life was thought to be like on the Murray River before the arrival of Europeans.
It is believed that Aboriginal settlement on the Murray River occurred around 40,000 years ago. Evidence of Aboriginal occupation of the rivers includes burial sites, ochre mining, rock quarries and scar trees (so named as Aboriginal people would carve canoe bases directly out the tree).
The original inhabitants of the Murray River near Albury and Wodonga are the Wiradjuri, Wavereoo and Dhudhuroa people. There are presently more than 40 Aboriginal Nations in the Murray-Darling Basin and at least 10,000 known Aboriginal sites.
Water played a significant role in the lives of the original occupants of the land, providing them with the means to survive as well as a strong spiritual connection to the rivers and floodplains.
The Rainbow Serpent is a common feature of many Aboriginal creation stories. It is believed that the Rainbow Serpent created the rivers, water holes and streams by moving across the land and shaping the landscape with its body. It is believed that the Rainbow Serpent leaves its resting place in nearby water holes and goes into the rivers to cleanse its waters and its people.
Aerial view of Murray River, taken from 3,000 feet in November 2005 – The Age
The Aboriginal community had a spiritual connection with water and the land, describing the land as ‘our food, our spirit and identity’.[1] The river and surrounding land provided Aboriginals with an important source of food, with fish and shellfish believed to be have been the main food source.
Aboriginals used water to trap food – they made nets using the fibres of rushes that grew in the creeks, which were chewed and twisted into shape. These nets were positioned across creeks to trap pelicans, ducks and black swans. Dams were made across creeks by weaving branches between a row of stakes pushed into the bed of the creek; fish would swim into these creeks during flooding and thousands of fish would be trapped when the water subsided. Canoes made from the bark of trees were also used for fishing; a fire would be made from clay and damp reeds inside the canoe, to cook the fish.
The ‘Yuki’, 13 foot-long bark canoe made from a Red Gum
[1] Source: http://aboriginalart.com.au/culture/dreamtime
The crossing place of the river by the Hume and Hovell expedition in a photograph taken in December 1919. Photo courtesy of the Border Mail
Hume & Hovell
Despite the common misconception, Hamilton Hume, the first white explorer to discover the Hume River, didn’t name it after himself. Rather, according to Hume himself, the river was named after his father, Andrew. Years later, Captain Charles Sturt would discover the river after travelling down the Murrumbidgee, and, not realising it was the same river that Hume had discovered upstream several years earlier, name it the Murray River. It was an auspicious beginning for one of Australia’s most contentious and valued water supplies.
The expedition of Hume and his fellow explorer William Hovell is itself mired in contention. Hume’s credentials as an explorer were well-established, having already been commissioned by the NSW Governor for several successful expeditions including an inland journey to Lake Bathurst. Hovell, however, was an exceptional navigator, albeit more at sea. By his early 20s, he had an established career at sea commanding a trade ship in South America, and later in Australia as a Captain of coastal and transpacific trading vessels. By the time he and Hume met, he’d taken up farming at his land in Narellan, some 20kms from Hume’s own farm in Appin.
The expedition was originally intended to be funded by the then Governor of NSW, Sir Thomas Brisbane, but when the money dried up, Hume & Hovell financed the expedition almost solely on their own. The government did cough up for some of the supplies, though, including pack saddles, tents, and clothing for Hume & Hovell’s convict servants (some of whom would accompany the duo on the journey, and at least one of whom would later claim ownership of the discovery).
Setting out on 17 October 1824, initially in search of good grazing land, the men discovered a few weeks later what would later be known as the Australian Alps, and the Murray River ten days after that. What occurred next remains unclear, as rivalry and dispute over the importance of their respective roles saw Hume and Hovell in conflict throughout their remaining years, with both men claiming larger roles in the find. Complicating matters further is an 1883 Memorandum of Understanding (written 10 years after Hume’s death and 8 years after Hovell’s) by one of their servants, Thomas Boyd, who threw his own hat into the ring.
“I was the first in the party to see the river,” Boyd wrote. “Being the first white man who ever did cross it. I carried a line, by which the provisions of the party were afterwards towed across in a rough boat constructed by Mr Hume.”
Boyd also went on to cast doubt over Hovell’s navigation skills.
“Mr Hume was the real leader of the party,” he states. “He and Mr Hovell often had long and warm [heated] disputes about the route to be pursued, but Mr Hume’s counsels always eventually prevailed; and I feel sure that without Mr Hume the party would never have reached [their ultimate destination of] Port Phillip or returned safely to the place whence it started.”
While the squabbles over recognition continued back in NSW, word of the all-important discovery of rivers and good grazing land spread. Though it would take another 30-odd years before it was so-named, Wodonga was about to put on the map.
Settling In
By the mid-1830s, a steady stream of settlers had landed and a smattering of semi-permanent dwellings and provision stores now littered the Murray’s riverbank. Brothers Charles and Paul Huon established the Wodonga Station in 1836, building a mudbrick homestead and christening it ‘Belvoir’ (which, for a number of years afterwards, was adopted as the name of the town). Settlements also occurred on the other side of the Murray in what would come to be known as Albury.
In 1851, the division of northern and southern New South Wales into two separate States was enacted. The border was proposed as the Murrumbidgee River, well north of Albury, but due to a clerical error, the boundary was fixed at the Murray River. Albury now resided in NSW and Wodonga was now rooted in the newly minted state of Victoria.
By 1857, Wodonga had a steam sawmill, an inn, a school and a court house, a stock inspector, a newspaper and a customs office. It was a police station that formally tipped the scales for Wodonga to be declared a township. The North Eastern Railway, completed in 1873 and improving trade and supply routes, cemented Wodonga with a permanency and accessibility that had, until then, evaded the isolated the town. The Wodonga Herald gushed with excitement.
“The wonted quietude of Wodonga will soon be dispelled, and the dream of a prosperous future realised in all of its phases.”
Trust Wodonga
Originally under the purview of Yackandandah Shire, ratepayers petitioned for their own council, and Wodonga Shire was formed in 1876. Given the fundamental necessity for providing water, the Wodonga Waterworks Trust was constituted in 1897 and tasked with responsibility for Wodonga’s drinking and wastewater. The most pressing issue was the quality of the drinking water. By all reports the water didn’t taste too great. Equally, it didn’t smell too good, either.
In 1899, Engineer B.A. Smith addressed the issue with the Wodonga and Towong Sentinel on “the question of the smell in the water, of which complaint has naturally been made.” Taking samples from various sources – Castle Creek, the storage reservoir, the service basin and a tap in town – it appeared only the town taps had a noticeable smell. Smith determined that this was due to the tar that lined the water pipes. With a somewhat cavalier attitude, he reported to the Sentinel, “I knew the tar was not thoroughly dry on all the pipes. I was not surprised by this.”
A further report came in from the Metropolitan Board regarding water quality, pointing out that while the water (in the reservoir in particular) was fit for domestic purposes, it did contain a high number of organisms and floating vegetable matter. The analyst suggested the water be passed through an ‘efficient domestic filter’, which, in 1899, was nothing more than a ‘good piece of flannel tied around the tap’.
The Water Act of 1890 enabled Wodonga to get their hands on £2,500 for their water supply, and another £8,000 in 1899. Combined with rates and charges for water (a complicated but surprisingly equitable equation issued by the Trust), a flush Trust set about increasing infrastructure and the implementation of several key projects, including the House Creek Dam. The Wodonga and Towong Sentinel exclaimed “Wodonga is at last within measurable distance of obtaining an excellent water supply; no greater boon could possibly be conferred on any community.”
The health officer was less sure. After taking samples from five different sources, including Castle Creek, he reported to the Sentinel that “no conclusion can be drawn from the analysis [of the water] from a sanitary standpoint.”
It would be some time before a conclusion could be drawn, and even longer before that conclusion was good news.
House Creek Dam, circa 1903. Photo courtesy of the Wodonga Historical Society
The Dam
Following successive years of severe drought in the 1890s, and a record dry year in 1902, it became clear on both sides of the border that a water storage was required to capture the winter flows for the settlements along the Murray.
From the first conference held in Corowa in 1902 to an actual ratified agreement for the regulation and sharing of the Murray waters, 13 years would pass. Distribution and rights to the water, as well as the methods for capturing it, were hotly contested, and it eventually took a Royal Commission with input from NSW, Victoria and South Australia to create a plan.
It would take a further 17 years and over a thousand men to build the Hume Dam. At the time it was the largest dam in the southern hemisphere, designed to hold a staggering 1.5 gigalitres. The dam was designed by engineers E.M. de Burgh (from NSW) and J.S. Dethridge (from Victoria), with NSW workers employed for the concrete gravity section of the build while Victorians were responsible for the main earthen embankment.
Despite what seemed like an equitable split of the job, working conditions and wages on either side of the river varied widely and workers on both sides would often down tools in protest. The temporary town of Ebden was hastily erected to house the sudden number of Victorian workers, while the same occurred for their northern neighbours. Stores, recreational halls, a post office, even a school were built. The resentful animosity between the two towns developed into a healthy rivalry with entry into the Ovens & Murray Football League, with Weir United taking out two consecutive premierships in the only two years they competed.
How they managed to compete at all remains unclear, since, for the most part, the dam was painstakingly built by hand. The back-breaking manual labour saw a wealth of injuries and at least nine recorded deaths. Only two steam cranes were employed for the digging, and the majority of excavation was achieved with little more than picks and shovels and hand-to-hand rock passing. The work dragged on until November 1936, and with work impacting the usual water supply (thanks, in no small part, to the relocation and subsequent flooding of the town of Bowna), Wodonga needed to start shoring up the waterworks of their own.
Flying fox builders from the NSW side of the Dam. Photo courtesy of the Albury & District Historical Society
Cashed Up
The Water Act of 1890 was superseded by the Water Act of 1915, a provision of which enabled local Councils to take out a loan against the State for the provision of water services. Each Waterworks Trust was specifically allocated the amount they could borrow, presumably commensurate with their population (though this is unclear), leaving some Trusts flush with cash (such as Wangaratta, who were cleared for £1,000), and others floundering, such as Murchison, who had to split £23 – or roughly $2,000 in today’s terms – across all their water supply works. It’s also possible that the distribution was decided on an as-needs basis, as Murchison had spent the previous ten years completing construction on the Waranga Dam and were nicely hydrated by the time loans were being offered. It may also explain why Wodonga, with a rapidly inflating population and a seemingly perpetual water supply, were short-changed and excluded from the list entirely.
Undeterred and underfunded, The Commissioners of the Wodonga Waterworks Trust put forward an ambitious proposal in the summer of 1922 for a pumping plant at Railway Bridge, a water tower, and new infrastructure to supply more and better quality water to Wodonga. Until this time, Wodonga’s water came primarily from Castle Creek, the quality of which ranged from the generous descriptor of ‘murky’ to the more blunt one of simply ‘green’.
Residents were asked to support the Trust’s new scheme by casting a ‘yes’ vote on Valentine’s Day in 1923. Despite an astonishing price tag of £17,380, residents voted in the affirmative for the proposal by a resounding 12 to 1. The following day’s Border Morning Mail quotes the Commissioner’s praise of the results, adding matter-of-factly that ratepayers ‘prefer to pay an increased rate for a satisfactory supply of water.’ (it’s worth noting that those four key words – ‘pay an increased rate’ – are curiously absent in the referendum document).
The Commissioner promised the water would be available next summer, and indeed it would be, but in order to achieve that, construction needed to begin on one of Wodonga’s most recognisable landmarks.
The Wodonga Water Tower
Work on the Wodonga Water Tower began in 1923 and was completed, on time, twelve months later. Contractor A.A. Hargrave, who would later also build the Wangaratta Water Tower (twice, in fact, when the first one collapsed a year after it was built), was commissioned for the project at a tidy sum of £3,000. At the time it was built, the water tower was the third highest elevated tank in Australia, standing at 33 metres high with a capacity of 341,000 litres (the estimated daily consumption of the town at the time).
The tower was made of seven tons of reinforced concrete. The tower has three floors, each with a window, and the water was supplied by an eight inch pipe via the pumping station at Wodonga Creek (an anabranch of the Murray River). A ball valve was installed at the top of tank which stopped the pump once capacity was reached, though the occasional overflow wasn’t uncommon. School children would often pass underneath it on their way to school hoping to cool off in the summer heat before making their way to class in soggy but decidedly cooler school uniforms.
The entire operation was entrusted to a turncock. The position was held by Ray Foster for 20 years, before it was assumed by Eric Fulford, who remained an employee of the Waterworks Trust until 1978. During their individual tenures, both men were the only employees of the water tower, the entire operation handled by each man pumping the water into the tower and tapping into the water mains for the plumbers.
There was a mark on the outside of the water tower connected to a float on the inside of the water tower to show the water level. Eric used a telescope (see below for a photograph of the actual telescope used) to look at the water level. The framed telescope is now proudly displayed at North East Water’s Regional Headquarters.
Occasionally the water tower did overflow – apparently if the water tower was overflowing on a hot summer’s day children walking to school would stand under the overflow from the tower to cool off before school.
The water tower supplied water to residents and businesses in Wodonga until 1959, after which it was drained.
The tower was eventually decommissioned in 1959 with the advent of a new 13 megalitre operation on Huon Hill. Its closure also coincided with another new opening, as the residents of Wodonga began to explore the use of water beyond irrigation and drinking.
Swimming Holes
Wodonga Creek Swimming Hole, circa 1923. Photo courtesy of the Wodonga Historical Society
It’s no coincidence that after a few years of the water tower tapping into Wodonga Creek for the town’s water supply that the idea for a town swimming pool was first floated. Wodonga Creek was a popular swimming hole not only for the town’s youth (estimated at this time to be around 400), but also the armed services, who camped out on the racecourse during the Second World War and commandeered the creek during rare recreational breaks. So popular was the spot that lights were eventually installed for night swimming, a pontoon for the local swimming club, and several ill-considered diving boards hastily built by wedging wooden planks into the rocks on the banks.
After several fatalities at the creek, the Wodonga and Towong Sentinel reported in 1928 that residents had urged the construction of a swimming pool. They were quickly shut down by councillor Jas Flowers, who contended that Wodonga Creek provided “an abundance of clean and wholesome water”.
It be would ten years before this was addressed and an anabranch of the Murray (upstream of the Wodonga stockbridge) was declared an official reserve and public swimming pool. Schools began hosting their swimming carnivals there, and along with new amenities such as dressing rooms and closets, a set of rules were issued, the most enforced of which was the wearing of appropriate swimming attire (with leg length and body coverage exactly proscribed).
Thirty years after it was first suggested, and just as work was winding down at the water tower, construction began on Stanley Street for Wodonga’s first public swimming pool. Wodonga Creek, as a swimming hole, soon fell by the wayside.
Opening Day at the Stanley Street Swimming Pool, 1959. Photo courtesy of the Wodonga Historical Society
The Number One Basin
The completion of the No 1 Basin on Huon Hill in 1958 may not have improved the water quality, but it certainly ensured residents got more of it more quickly. The concrete basin, which was essentially an uncovered storage, pumped raw water 3½ kilometres from Wodonga Creek before being distributed to resident’s taps. The process of supplying untreated water to Wodonga continued until the completion of a filtration plant in 1989, despite several attempts to improve things in the year’s in-between.
In 1973, a project was approved by the Wodonga Waterworks Trust to supply the town with filtered water from Lake Hume, and in 1975, Dr Bill Grant proposed introducing fluoridation to the water supply. Both ideas were thwarted by their respective councils. It would be 40 more years – 2005 – before the Department of Health would insist that Wodonga’s drinking water be fluoridated.
Not that money wasn’t being spent. In 1974 alone, over a million dollars was allocated to water and sewerage services. By 1983, however, the operations of the Wodonga Waterworks Trust, along with the Wodonga Sewerage Authority, were absorbed under the authority of Wodonga Council. It would be a short, ten-year venture for the Council, but a single $4 million dollar investment would have a lasting impact on the Wodonga water landscape.
The Filtration Revolution
The Huon Hill Treatment Plant was completed in 1989, bringing with it something Wodonga had yet to experience – filtered water. The improvement in water quality was substantial. Wodonga Creek remained the source supply, and the treatment plant, now able to pump 70 megalitres a day – or roughly 210 times more than the water tower – finally complied with the World Health Organisation’s guidelines.
In 1993, the Council also took over operations of the Chiltern, Barnawatha, Rutherglen, Wahgunyah and Lower Kiewa Valley Water Trusts, instigating a major works program in each centre. Before they had the opportunity to wade in too deeply, however, by Order of the Minister for Natural Resources, the Wodonga water and wastewater operations were abruptly abolished. From the first day in December of 1994, assets, liabilities and infrastructure changed hands to one of the many new Water Authorities that were born that year, the Kiewa Murray Region Water Authority.
Meanwhile to the west, a second Authority absorbed the Bright District, the Benalla Water Board, the Shire of Yarrawonga and the City of Wangaratta to form the Ovens Region Water Authority.
Though the stewardship of the Kiewa Murray Region Water Authority and the Ovens Region Water Authority would be brief (in name, at least), the inroads and upgrades they instigated and initiated would have a long and positive impact on the communities they served.
Kiewa Murray Region Water Authority
Ensuring they maintained momentum and a seamless transition, the Kiewa Murray Region Water Authority absorbed most of Wodonga Council’s staff, with close to 50 employees moving to the new Authority. The Authority also later assumed control of the Kiewa Valley Water Authority, who supplied another 20 employees.
The first issue was were to put them all. Offices were shared with other organisations and businesses before they eventually moved to a single location at the Council on Hovell Street, with branch offices operating out of Rutherglen, Mt Beauty and Tallangatta. These three towns, along with Chiltern and Beechworth, also had works depots, while outside contractors were brought in for Corryong. The operation – and the challenges ahead – loomed large.
With the largest residential footprint in our service area, Wodonga would see its fair share of investment in water and wastewater services, with almost annual upgrades to infrastructure. The pace of this would increase once the Kiewa Murray Region Water Authority combined with the Ovens Region Water Authority in 1999 and the North East Region Water Authority (NERWA) was born.
Big money for a big city
NERWA (later renamed North East Water) hit the ground running. Along with an upgrade to the No. 1 Pump Station, we set about connecting the Bandiana and Bonegilla army barracks to the water and sewerage networks.
North East Water also inherited two wastewater treatment plants, with a plant on Howard Street treating domestic flow and another plant in West Wodonga for industrial flow. With the second plant nearing capacity (and an increase in EPA requirements), North East Water determined in 2004 to upgrade West Wodonga and close down the Howard Street site.
The West Wodonga Wastewater Treatment Plant upgrade cost close to $16 million, and as well as increasing capacity and efficiencies (resulting in a reduction of no less than 20 tonne of phosphorous output back into the Murray River), the facility also enabled us to explore reuse opportunities (such as supplying reuse water to golf courses and parks, a practice we’re still doing today).
Before the decade was out, Huon Hill would get two new 14ML (that’s 80 times the capacity of the original Wodonga Water Tower) clear water storages, Logic would get connected to the water supply (along with its own 2ML tank), and another clear water storage for McGaffins Hill.
With the vast majority of infrastructure in place, North East Water spent the early part of the next decade on upgrades and improvements. The one exception was a long-needed regional headquarters, housed on the site of the Dunstan Timber Mill.
Tackling climate change
In 2016, North East Water committed to the Victorian government, and the residents of north east Victoria, to reduce its carbon footprint by 42% (and by 100% by 2050). With our West Wodonga Wastewater Treatment Plant one of our largest emitters of carbon, and a series of works were proposed to stem our carbon emissions.
In 2018, the first of these was completed, with the installation of high efficiency blowers (blowers are machines that are used to inject pressurised air in the form of fine bubbles into wastewater to ensure that sufficient oxygen is present for microbes to thrive and convert water into a cleaner product as part of the treatment process – yep, it’s a complicated business here!). The new blowers reduce the amount of power (and therefore carbon) at the plant by a whopping 14%. In 2018, we also began planning for a 2MW solar array that is estimated to produce approximately 4,380,000kWh/annum, enough to not only run the plant entirely on solar power, but provide extra power for selling back to the grid.
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