- Alte Weser (lighthouse)
Infobox_Lighthouse
name=Alte Weser
caption = "Alte Weser" lighthouse in 1992
location = Offshore, mouth of theWeser River ,German Bight
coordinates =coord|53|52|N|8|08|E|
yearbuilt = 1961 - 1964
yearlit = September 1, 1964
automated = 1972
yeardeactivated =
foundation = Ferroconcrete. (cf. Fig. 2)
construction = Steel
shape = Inverted conical with two-story observation centre and lantern on top
marking = Red with two white bands and green lantern room
height =
elevation = 33 m
lens =
currentlens = Double beltoptics with 400 mm focal distance
intensity = 424,000 cd
range = 23 nmi
characteristic = F WRG
fogsignal = Horn Mo(AL) 60s
admiralty = B 1188
NGA = 10308
ARLHS = FED-001The Alte Weser Lighthouse is located offshore from the estuary mouth of the river
Weser in theGerman Bight , southernNorth Sea .It was built on sand between 1961 and 1964. The Alte Weserlighthouse took over duties and replaced the historical Roter Sand lighthouse on September 1, 1964. The latter had been built from 1883 to 1885.General aspects
The "Alte Weser" lighthouse was built between 1961 and 1964. It consists of steel-coated
ferroconcrete and a steel superstructure. It was built offshore into a sand bed at a depth of 11 m below mean sea level. Its height measures about 40m above msl. Depending on the color of the light beam, its visibility is between 18 and 23 sm. The only inhabited place where the Alte Weser or Roter Sand lighthouse can be seen with the naked eye is the German island ofWangerooge .Technical data
The
light characteristic is "F WRG", i.e. a continuous light, coloured white, red or green depending on the bearing of the lighthouse. The light is emitted by a 2000Watt s Xenon lamp. On low visibility conditions afoghorn sounds a signal, theMorse code letters "AL" with an intervall of one minute.On the tower a number of additional navigational and meteorological devices are installed next to the optics.
Directional antenna e and aradar serve as means of security in the Weser approach while ananemometer and an automated tide gauge collect data on wind conditions and water levels. The tower has a built-inemergency power system and provides accommodation for a maintenance crew.Construction
The “Roter Sand“ lighthouse (German transl. “red sand“) is located in the "Outer-Weser" waterway in the German Bight, southern North Sea. At the end of the 1950s the lighthouse had been badly damaged by corrosion, corrasion, and lixiviation of its concrete. To replace the old lighthouse, the “Alte Weser” was built in the years 1961-1964 not far from the former location. Simultaneously, the conditions for the ships' traffic in the "Outer-Weser" waterway were intended to be improved and the new lighthouse was planned to be established as an offshore part of the radar chain on the Weser between Bremen and the North Sea (Fig. 2).
The novel form of the tower (Fig. 2), i.e. its downward tapering tower-shaft together with its cantilevered upper stories was based on a design by engineer Andreas Carstens,
Bremerhaven . The conical design of the tower was intended to minimize exposure to waves anddrift ice . The German Waterway Administration, the "Wasser- und Schifffahrtsamt (WSA) Bremerhaven" as the responsible governmental agency, assigned the task of workmanship to a cooperative of companies: Philipp Holzmann, Strabag Bau AG, Hermann Moeller [ [http://www.wsv.de/wsa-bhv/verkehrswesen/schifffahrtszeichen/leuchttuerme/alte_weser/index.html Bremerhaven] ] . This cooperative instructed theHowaldtswerke inKiel to carry out the steelworks.The steelwork's for the tower-shaft, the upper stories and the equipment were carried out in a dry dock of the Howaldts-factory in Kiel (Fig. 3). The tower-shaft was towed through the
Kiel Canal towards its destination site in the Outer-Weser waterway (Fig. 6). For this purpose a floating offshore-lift platform which had been supplied with a central cut-out for the tower was used. At the site the shaft was lowered and subsequently jetted into the sand to the intended depth. After feeding in a layer of underwater concrete, the shaft was evacuated and the additional layers of ferroconcrete were installed (Fig. 5).Frequently, adequate supply of building materials was hampered and delayed, because relatively small coasters had been contracted for transport, which were quite sensitive to the state of the sea and weather conditions. Timing was especially important in order to ensure joints were constructed correctly. To this end, all building materials needed for the underwater concrete had to arrive in time and without delay. Therefore, an optimal weather period was required.
A further interruption happened due to two accidents. The first was fatal when a sudden leak killed two workers. However, the exact reason for the accident was never fully revealed. The tower-shaft which had been lowered and jetted into the sand had to be abandoned. The upper stories were detached and transported back to Kiel on the offshore-lift-platform for later use. One year later the upper stories were re-used on a second tower-shaft nearby. The old stump of the tower-shaft remains underground today. The
storm surge of 1962 which cost many human lives inHamburg and other places on the German coast had no impact on the construction of the lighthouse. The first accident did however force a new start to the works in Kiel, causing a delay of one year. The second accident happened because of a malfunction of the gripper at the front legs of the offshore-lift-platform. A second platform had to be used in order to repair and replace the first one. In the third year, after the lift-platform had been repaired, the construction works resumed at the tower-shaft and were subsequently completed.Next, the offshore-lift-platform could pick up the upper stories which were still stored at Kiel (Fig. 6) to join them with the tower-shaft in the North Sea. Under favorable weather conditions the upper stories were placed on top of the tower without complications (Fig. 7). Now, the completing works such as installation of the optics including the corresponding blinds and the installation of the standby sets were implemented. The power supply of the lighthouse demanded special attention. A 6 kV cable was run from the “Robbenplate” lighthouse (Fig. 1) towards “Alte Weser”, jetted in using a special device (“Einspuelstiefel”, Fig. 8) and threaded into the tower through a protective cable conduit. In addition, measures had to be taken to adopt the same cable for the planned “Tegeler Plate” lighthouse (see below). The foundation of the building was safeguarded with stone ballast poured down on bush mats against rinsing and water erosion. In 1964 the light of “Alte Weser” lighthouse went into service (Fig. 9). In 1972 the four keepers were displaced when the lighthouse became automated.
Tegeler Plate lighthouse
As an additional improvement of the waterway conditions as implemented by the procedure as a whole (see above), construction of another lighthouse was essential. This effort simultaneously made it possible to take the light vessel `Bremen`out of service. As a location for the new lighthouse the Tegeler Plate sand bar was chosen. The tower-shaft as well as the upper stories of the Tegeler Plate lighthouse were intended to be entirely built as steel construction. The tower-shaft's height of about 46 m as well as the local shallow water conditions (i.e. average low tide about 2.50 m above ground level) made it possible to pile jet the tower-shaft 18 m deep into the sand in one step. To this end, jetting the tower-shaft into sand as a first step was considered to be followed by placing the upper stories on top as a second step. In this manner corrections of slight discrepancies of the shaft could be made.
After the steelworks had been carried out at Wilhelmhaven, the tower-shaft and the upper stories were brought to the intended position by a salvage ship carrying heavy water pump systems, and were jetted into the sandy ground. The power cable already installed at the “Alte Weser” lighthouse was integrated. The Tegeler Plate Lighthouse went into service in 1966 – it was unmanned and operated remotely from the beginning. Only emergency quarters were set up for maintenance workers. The base was secured through stone ballasting.
With these arrangements two important steps for the deepening project of the Outer Weser waterway had been accomplished.
In popular culture
Alte Weser lighthouse was featured on a German stamp in 1976.
Alte Weser lighthouse as well as Tegeler Plate, Roter Sand and others were shown on various paintings by Katharina Noack.
References (German)
* "Leuchtturm Roter Sand: Bildband." 2005. Wirtschaftsverlag N.W. Verlag für neue Wissenschaft. ISBN 3-8650-9334-5
* Luttermann, H.-J. 2003. "Blüsen, Baken, Feuertürme." Convent. ISBN 3-9346-1354-3
* Scheiblich, R. 1998. Leuchttürme an Deutschlands Küsten, 2nd ed., Delius Klasing.
* Scheiblich, R., and H.-J. Lutterman. 2003. "Sterne unter den Wolken." Convent. ISBN 3-9346-1351-9
* Scheiblich, R., and H. Staack. 2002. "Leuchttürme Lexikon." Edition Ellert & Richter. ISBN 3-8319-0038-8
* Seedorf, R., and P. Fäthke. 1989. "Gerettet! Leuchtturm Roter Sand." ISBN 3-8841-2116-2
* Schnall, U. 1999. "Leuchttürme an deutschen Küsten." 4th ed., Ellert & Richter, ISBN 3-89234-521-X
* Stölting, S. 1985. "Leuchtturm Roter Sand. 1885-1985." Worpsweder Vlg., Lil.
* Zemke, F.-K. 2000. "Deutsche Leuchttürme einst und jetzt." Koehlers Verlagsges. ISBN 3-7822-0769-6
*reflistExternal links
* [http://www.wsa-bremerhaven.de/ German office of waterways at Bremerhaven (Wasser- und Schifffahrtsamt Bremerhaven)]
* [http://www.leuchttuerme.net/globus.htm Lighthouses of the world]
* [http://www.leuchtturm-atlas.de/HTML/AlWeseT.html data on lighthouse]
* [http://www.leuchttuerme.net/index.php?nav=1000001&lang=1&id=32&action=portrait Lighthouse "Tegeler Plate"]
* list of lighthouses
* German lighthouses
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