Grevelingendam

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Grevelingendam
Grevelingedam-01.jpg
The Grevelingendam
Coordinates 51°40′40″N4°6′42″E / 51.67778°N 4.11167°E / 51.67778; 4.11167
CarriesN59 motorway
Owner Rijkswaterstaat
Characteristics
Total length6.0 kilometres (3.7 mi)
History
Engineering design byDeltadienst
Construction start1958
Construction end1965
Opened1965
Location
Grevelingendam

The Grevelingendam is a dam located in the Grevelingen sea inlet between Schouwen-Duiveland and Goeree-Overflakkee in The Netherlands. The Grevelingendam was the fourth structure constructed as part of the Delta Works. [1]

Contents

The dam is six kilometres in length. Construction began in 1958 with the aim of delivering it in 1964. Due to several setbacks, the construction of the dam took seven years and was opened on 1 April 1965 by Minister of Transport and Water Management, Jan van Aartsen. [1] There is a navigation lock at the southern end of the dam near Bruinisse, and nearby a control lock using a siphon system, known as the Flakkeese Spuisluis, which connects the Eastern Scheldt with the Grevelingenmeer. [2]

The construction of the Grevelingendam permitted Dutch civil engineers and contractors to gain experience that would be necessary for the Brouwersdam, along with more complicated closure works such as those at the Haringvlietdam, and the Oosterscheldekering. [1] [3]

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Delta Works

Feasibility, planning and design

Being part of the Delta Works scheme, the Grevelingendam works were conceived in response to the North Sea flood of 1953, as a result of which it was decided to close the inlets in Zeeland and South Holland. The Grevelingendam was not a specific requirement of the Dutch Delta Act of 1958 and is not primarily intended to protect against flooding. Rather, as was the case with two other Delta Works projects (the Volkerakdam and the Zandkreekdam), the Grevelingendam was designed as a secondary compartmentalisation dam with the goal of reducing tidal current velocities in four surrounding estuaries, thereby permitting easier subsequent construction of the primary dams of the Haringvlietdam, the Brouwersdam and the Oosterscheldekering. [3]

Location of the Grevelingendam works, showing the adjacent Flakkeese Spuisluis and the Philipsdam Grevelingendam-PhilipsdamEN.jpg
Location of the Grevelingendam works, showing the adjacent Flakkeese Spuisluis and the Philipsdam

The location of the dam had a major influence on the construction schedule. The dam is founded over much of its length on a sandbank known as the Plaat van Oude Tonge, which dries out at low tide. Between the south side of the dam and the lock, which is situated on the bank of Schouwen-Duiveland, the dam crosses a gully up to 25 metres in depth. Between the north side of the Plaat van Oude Tonge and the bank at Goeree-Overflakkee, the dam crosses a shallower, 1000 metre-wide network of gullies. [4]

The height of the western part of the dam (the 'crown line') over the Plaat van Oude Tonge is 5.5 metres above Amsterdam Ordnance Datum (Normaal Amsterdams Peil, NAP). This high crest line is necessary due to large wave run-up, with the dike designed to permit some flooding at very high water levels. Space was reserved on the crown of the dam for the conversion of the N59 into a four-lane motorway, with a parallel road for other traffic. Due to a policy change in the 1970s, the four-lane motorway was never built. [5] [6]

The hydraulic investigations undertaken at the design stage had shown that it was desirable to have the closure of the southern channel at the Schouwen-Duiveland coast precede the closing of the northern channel near Goeree-Overflakkee. The following construction schedule was therefore planned:

Construction: Southern channel caisson closure

The dam closure at the southern channel was achieved using a system of caissons, with a number of the caissons that had been used for the emergency closures immediately after the North Sea flood disaster of 1953 repurposed for use. In addition to new caisson units made specially for the Grevelingendam project, a caisson unit which had been intended for use on the closure of the Brielse Maasdam in 1950 was also used. The caissons were floated to the closing gap, being transported in units of five. Before the closure, abutments were placed on both sides of the dam, composed of two caissons on the south side and three caissons on the north side, which were connected to the top of the dam sections. [6]

Engineering drawing of some of the caissons used in the closure works Eenheidscaisson.jpg
Engineering drawing of some of the caissons used in the closure works

When closing large gaps using caissons, the units must be placed in the closing hole during slack water, which in most cases occurs at the moment of tidal reversal (at or around the times of high water and low water). However, in the Grevelingenmeer, there were more than two turnarounds as a result of the fact that the currents in the closing gap were influenced by tides from the Oosterschelde and the Brouwershaven Gap.

The flow velocities in the closing area were therefore analysed and calculated in detail for the various caisson sinking phases, using the Deltar analogue computer, which had just been developed at the time. The time available during the turnaround made it impossible to sink the caissons individually. Therefore, two or three caissons were connected together and sunk at the same time. [7]

During the sinking manoeuvres, the caissons were guided by a firmly anchored floating crane. After they had been sunk, armourstone was installed along the front and rear of the caissons by a stone dumping vessel (on the sea side of the dam) and a floating crane on the river side. After pouring concrete to the caisson units, the remaining elements were placed using a floating sheerleg. The unit caissons had a height of 6 metres, with the extensions being 2 metres in height. The threshold level at the closing gap was around 5 metres below sea level (Amsterdam Ordnance Datum) with the concrete barrier terminating 8 metres above this. [7] [8]

Construction: Northern channel closure using cable-way

Cable car system used on the northern channel closures Afsluiting Grevelingendam, Bestanddeelnr 915-7505.jpg
Cable car system used on the northern channel closures
The cable car anchor block has been retained as a monument to the construction Grevelingendam - Monument kabelbaan.jpg
The cable car anchor block has been retained as a monument to the construction

The shallow nature of the northern channel permitted a more gradual closure, with the use of a 1.9 kilometre long cable car system. [9] The advantage of a gradual vertical closure is that flow velocities are limited, resulting in a reduction in the magnitude of scour holes either side of the dam. [7] Another advantage of the cable car solution was that only a single pylon was required in the centre of the channel. The cable car system was designed by Rijkswaterstaat in combination with the French company Neyrpic, and used self-propelled cars and a one-way system to optimise capacity.

A threshold at the base of the dam in the northern channels was poured in 1962, along with a dike section from Goeree-Overflakkee. The remaining length, of approximately 1200 metres, was constructed by the cable car method. The cableway consisted of two carrying cables, with the last sections terminating at a turntable, along which the cars could pass from one side to the other. The cables were attached to a fixed anchor point on the north-east side of the closure, which has been preserved as a monument to the construction, and to a tilting counterweight on the opposite side. The units and stone placed by the cars were transported by four steel hopper barges, being lifted and lowered by the cars. A production rate of 360 tonnes of stone per hour was achieved. [8] [6]

The channels were closed using the method of gradual closing, partly because loosely packed sand in the substrate could lead to settlement issues, and partly to gain experience with the use of a cable-way. Using the cable-way stone was dumped on a threshold covered with fascine mattresses, polyethylene foil, and asphalt mastic. The stone dam was built up in this way to 2.5 metres above NAP, after which sand could begin to be sprayed against the closing dam by dredgers, and the dam body raised. By the autumn of 1965, the Grevelingen Dam was completed. [10]

The Grevelingenmeer (Lake Grevelingen)

With the Grevelingendam complete, the subsequent construction of the Brouwersdam in 1971 created the Grevelingenmeer Lake, which has become a popular water sports location for recreational diving and sea kayaking. [11] Shipping enters the Krammer via the Grevelingen navigation lock at Bruinisse. [12] [13]

In order to maintain the freshwater status of the Grevelingenmeer, a siphon control lock complex was constructed in the Brouwersdam, and later a similar structure was constructed at the Grevelingendam (the Flakkeese Spuisluis). These locks turned out to have more capacity than originally intended, and a decision was made to allow the Grevelingenmeer to remain as a seawater lake, it thus becoming the largest seawater lake in Europe. [14] A connection to the Philipsdam was made at the South Holland end of the Grevelingendam. [8] [5]

Road and bridge over the dam

The N59 runs over the Grevelingendam, with a secondary bridge constructed over the Grevelingen lock to cope with increased traffic volumes. [5]

Media

See also

Related Research Articles

The Delta Works is a series of construction projects in the southwest of the Netherlands to protect a large area of land around the Rhine–Meuse–Scheldt delta from the sea. Constructed between 1954 and 1997, the works consist of dams, sluices, locks, dykes, levees, and storm surge barriers located in the provinces of South Holland and Zeeland.

<span class="mw-page-title-main">Eastern Scheldt</span> Estuary in Zeeland, Netherlands

The Eastern Scheldt is a former estuary in the province of Zeeland, Netherlands, between Schouwen-Duiveland and Tholen on the north and Noord-Beveland and Zuid-Beveland on the south. It also features the largest national park in the Netherlands, founded in 2002.

<span class="mw-page-title-main">Schouwen-Duiveland</span> Municipality in Zeeland, Netherlands

Schouwen-Duiveland is a municipality and an island in the southwestern Netherlands province of Zeeland. The municipality has 33,737 inhabitants and covers an area of 488.94 square kilometres.

<span class="mw-page-title-main">Goeree-Overflakkee</span> Island and Municipality in South Holland, Netherlands

Goeree-Overflakkee is the southernmost delta island of the province of South Holland, Netherlands. It is separated from Voorne-Putten and Hoeksche Waard by the Haringvliet, from the mainland of North Brabant by the Volkerak, and from Schouwen-Duiveland by Lake Grevelingen.

<span class="mw-page-title-main">Grevelingen</span> Brackish water body in the Netherlands partly isolated from the North Sea by a levee

The Grevelingen or Grevelingenmeer is a closed off part of the Rhine-Meuse estuary on the border of the Dutch provinces of South Holland and Zeeland.

<span class="mw-page-title-main">Oosterscheldekering</span> Dutch storm surge barrier in the North Sea

The Oosterscheldekering, between the islands Schouwen-Duiveland and Noord-Beveland, is the largest of the Delta Works, a series of dams and storm surge barriers, designed to protect the Netherlands from flooding from the North Sea. The construction of the Delta Works was a response to the widespread damage and loss of life in the North Sea flood of 1953.

<span class="mw-page-title-main">Herkingen</span> Village in South Holland, Netherlands

Herkingen is a village in the Dutch province of South Holland. It is located on the south coast of the island Goeree-Overflakkee, in the municipality of Goeree-Overflakkee.

The Krammer is a body of fresh water located in the western part of Volkerak in the Netherlands.

<span class="mw-page-title-main">Volkerak</span>

The Volkerak is a body of water in the Netherlands. It is part of the Rhine–Meuse–Scheldt delta, and is situated between the island Goeree-Overflakkee to the north-west and the Dutch mainland to the south and east. The western part of the Volkerak is also called Krammer. Tributaries of the Volkerak are the Dintel and Steenbergse Vliet.

<span class="mw-page-title-main">Philipsdam</span> Hydraulic engineering structures in the Netherlands

The Philipsdam is a compartmentalisation dam constructed as part of the Delta Works in the Netherlands. It separates water of the lakes Krammer and Volkerak from the Oosterschelde, and connects the Grevelingendam to Sint Philipsland.

<span class="mw-page-title-main">Brouwersdam</span> Bridge

The Brouwersdam is the seventh structure of the Delta Works in the Netherlands, forming a barrier across the former estuary known as the Brouwershavense Gat. As a result, the area of water became known as the Grevelingenmeer.

<span class="mw-page-title-main">Oesterdam</span> Compartmentalisation dam in the Netherlands, part of the Delta Works

The Oesterdam is a compartmentalisation dam in The Netherlands, situated between Tholen and South Beveland in the eastern part of the Eastern Scheldt. The dam, with a length of 10.5 kilometres, is the longest structure built for the Delta Works. The Oesterdam was necessitated, like the Philipsdam, after the decision was taken to close off the Eastern Scheldt with a storm surge barrier, rather than a solid dam.

<span class="mw-page-title-main">Markiezaatskade</span> Dam in the Netherlands

The Markiezaatskade is a compartmentalisation dam in The Netherlands, situated between South Beveland and Molenplaat, near Bergen op Zoom. The dam was constructed as part of the Delta Works, and has a length of 4 kilometres.

<span class="mw-page-title-main">Volkerakdam</span> Hydraulic engineering structures in the Netherlands

The Volkerakdam or Volkerakwerken is the name given to a group of hydraulic engineering structures between Goeree-Overflakkee and North Brabant in the Netherlands. The works are not a single dam, but are composed of three distinct structures: a dam between Goeree-Overflakkee and Hellegatsplein, a series of locks from Hellegatsplein to North Brabant, and a bridge from Hellegatsplein to Hoekse Waard. The works cross three separate bodies of water: the Haringvliet, Hollands Diep and Volkerak. The works together comprise the fifth project of the Delta Works.

<span class="mw-page-title-main">Stormvloedkering Hollandse IJssel</span> Hydraulic engineering structure in the Netherlands

The Stormvloedkering Hollandse IJssel, Hollandse IJsselkering or Algerakering is a storm surge barrier located on the Hollandse IJssel, at the municipal boundary of Capelle aan den IJssel and Krimpen aan den IJssel, east of Rotterdam in The Netherlands. The construction of the works comprised the first project of the Delta Works, undertaken in response to the disastrous effects of the North Sea flood of 1953. Prior to 1954, the spelling Hollandsche was used in the official name.

<span class="mw-page-title-main">Zandkreekdam</span> Hydraulic engineering structures in the Netherlands

The Zandkreekdam is a compartmentalisation dam located approximately 3 kilometres north of the city of Goes in The Netherlands, which connects Zuid-Beveland with Noord-Beveland, and separates the Oosterschelde from the Veerse Meer.

<span class="mw-page-title-main">Frank Spaargaren</span> Dutch civil engineer

Frank Spaargaren was a Dutch hydraulic engineer who was one of the main designers of the Oosterscheldekering and served as a director of the Waterloopkundig Laboratorium in Delft.

<span class="mw-page-title-main">Jan Agema</span> Dutch Hydraulic Engineer and professor of Civil Engineering

Jan Fokke Agema was a Dutch hydraulic engineer and professor at Delft University of Technology. He is notable for his design of the harbour entrance at Hoek van Holland and involvement in the construction of the Oosterscheldekering. The prof. dr.ir. J.F. Agemaprijs is named for him, and has been awarded every five years since 2000.

A compartmentalisation dam is a dam that divides a body of water into two parts. A typical use of such a dam is the regulation of water levels separately in different sections of a basin. One application of a compartmentalisation dam is to facilitate closures of areas with multiple tidal inlets, such as in the case of the Delta Works.

<span class="mw-page-title-main">Closure of tidal inlets</span> Man-made coastal barriers against tides

In coastal and environmental engineering, the closure of tidal inlets entails the deliberate prevention of the entry of seawater into inland areas through the use of fill material and the construction of barriers. The aim of such closures is usually to safeguard inland regions from flooding, thereby protecting ecological integrity and reducing potential harm to human settlements and agricultural areas.

References

  1. 1 2 3 "Driemaandelijks Bericht Deltawerken nr 001-010 (1957-1959)" [Quarterly Bulletin on the Delta Works: No. 001-010 (1957-1959)]. Quarterly Bulletin on the Delta Works (in Dutch) (1–010). 1957. Retrieved 27 December 2022.
  2. "Grevelingendam". The Watersnoodmuseum official website. Watersnoodmuseum. Archived from the original on 27 December 2022. Retrieved 29 December 2022.
  3. 1 2 Watson, I.; Finkl, C.W. (1990). "State of the Art in Storm-Surge Protection: The Netherlands Delta Project". Journal of Coastal Research. 6 (3): 739–764.
  4. "Driemaandelijks Bericht Deltawerken nr 011-020 (1960-1962)" [Quarterly Bulletin on the Delta Works: No. 011-020 (1960-1962)]. Quarterly Bulletin on the Delta Works (in Dutch) (11–020). 1960. Retrieved 29 December 2022.
  5. 1 2 3 Steenhuis, M.; Voerman, L.; Swart, S.; Emmerik, J. (2016). De Deltawerken [The Delta Works] (in Dutch). [Rotterdam]: nai010 Uitgevers. ISBN   978-94-6208-272-4. OCLC   951540787.
  6. 1 2 3 4 "Driemaandelijks Bericht Deltawerken nr 011-020 (1960-1962)" [Quarterly Bulletin on the Delta Works: No. 021-030 (1963-1965)]. Quarterly Bulletin on the Delta Works (in Dutch) (21–030). 1963. Retrieved 29 December 2022.
  7. 1 2 3 Huis in 't Veld, J. C. (1987). The Closure of tidal basins: closing of estuaries, tidal inlets, and dike breaches (2nd ed.). Delft, the Netherlands: Delft University Press. ISBN   90-6275-287-X. OCLC   18039440.
  8. 1 2 3 Stamhuis, E. (1997). Afsluitingstechnieken in de Nederlandse Delta: Een overzicht van de ontwikkeling van deze techniek [Closure techniques in the Dutch Delta: An overview of the development of the technique] (in Dutch). The Hague: Rijkswaterstaat. ISBN   9057301768.
  9. van der Kley, J.; Zuidweg, H.J. (1969). Polders en dijken [Polders and dikes] (in Dutch). Amsterdam: N.V. Uitgeversmaatschappij Agon Elsevier. OCLC   64334419.
  10. van der Kley, J.; Zuidweg, H.J. (1969). Polders en dijken [Polders and dikes] (in Dutch). Rotterdam: Elsevier. pp. 321–323. Retrieved 31 December 2023.
  11. Hoeksema, H.J. (12 July 2002). "Grevelingenmeer: Van kwetsbaar naar weerbaar?" [Grevelingenmeer: From vulnerable to resilient?]. Technical Reports of Rijkswaterstaat: Rijksinstituut voor Kust en Zee/RIKZ (in Dutch). Retrieved 29 December 2022.
  12. Saeijs, H.L.F.; Stortelder, P.B.M. (1982). "Converting an estuary to Lake Grevelingen: Environmental review of a coastal engineering project". Environmental Management. 6 (5): 377–405. doi:10.1007/BF01871888. ISSN   0364-152X . Retrieved 19 December 2023.
  13. Bannink, B.A.; van der Meulen, J.H.M.; Nienhuis, P.H. (1984). "Lake Grevelingen: From an estuary to a saline lake. An introduction". Netherlands Journal of Sea Research. 18 (3): 179–190. doi:10.1016/0077-7579(84)90001-2. ISSN   0077-7579 . Retrieved 19 December 2023 via Elsevier Science Direct.
  14. de Vlieger, F. (2018). Brouwershaven: Is there a necessity to adapt the harbour constructions in the harbour of Brouwershaven, or to secure them against the reduced tide in the Grevelingen lake? (MSc). TU Delft. Retrieved 29 December 2022.
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