Jump to content

Screw turbine

From Wikipedia, the free encyclopedia
Reverse action of the Archimedean screw, the principle of the screw turbine gaining energy from water flowing down through the screw
Screw turbines typically have three or four flights (second row)
Two parallel screw turbines capable of producing 75 kW each, in Monmouth, Wales
Video of a 40 kW screw turbine in Munich, Germany

A screw turbine (also known as an Archimedean turbine, Archimedes screw generator or ASG, or Archimedes screw turbine or AST) is water turbine that converts the potential energy of water on an upstream level into work. This hydropower converter is driven by the weight of water, similar to water wheels, and can be considered as a quasi-static pressure machine. Archimedes screw generators operate in a wide range of flows (0.01 to 14.5 ) and heads (0.1 m to 10 m), including low heads and moderate flow rates that are not ideal for traditional turbines and not occupied by high performance technologies.

Archimedes' screw can be used to generate power if they are driven by flowing fluid instead of lifting fluid. Water transiting the screw from high to low elevation generates a torque on the helical plane surfaces, causing the screw to rotate. The Archimedes screw generator consists of a rotor in the shape of an Archimedean screw which rotates in a semicircular trough. Water flows into the screw and its weight presses down onto the blades of the turbine, which in turn forces the turbine to turn. Water flows freely off the end of the screw into the river. The upper end of the screw is connected to a generator through a gearbox. The Archimedes screw is theoretically a reversible hydraulic machine, and there are examples of single installations where screws can be used alternately as pumps and generators.

History

[edit]
A screw turbine at a small hydro power plant in Goryn, Poland

The Archimedean screw is an ancient invention, attributed to Archimedes of Syracuse (287–212 BC.), and commonly used to raise water from a watercourse for irrigation purposes. In 1819 the French engineer Claude Louis Marie Henri Navier (1785–1836) suggested using the Archimedean screw as a type of water wheel. In 1916 William Moerscher applied for a U.S. patent on the hydrodynamic screw turbine.[1]

Application

[edit]
12 kW screw turbine at the Cragside estate

The Archimedean screw turbine is applied on rivers with a relatively low head (from 0.1 m to 10 m) and on low flows (0.01 m3/s up to around 10 m3/s on one turbine). Due to the construction and slow movement of the blades of the turbine, the turbine is considered to be friendly to aquatic wildlife. It is often labelled as "fish friendly". The Archimedean turbine may be used in situations where there is a stipulation for the preservation and care of the environment and wildlife.

Design

[edit]

An Archimedes Screw Turbine (AST) hydroelectricity powerplant can be considered as a system with three major components: a reservoir, a weir, and the AST (which is connected to the system by a control gate and trash rack). At most real AST locations, the incoming flow must be divided between the AST and a parallel weir. Typically, a minimum flow over the weir is mandated for the protection of the local environment. Other outlets as well as a fish ladder could be considered as the other components of this system. A comprehensive guide about the principles of designing Archimedes screw turbines and screw hydropower plants is available in "Archimedes Screw Turbines: A Sustainable Development Solution for Green and Renewable Energy Generation—A Review of Potential and Design Procedures".[2]

Flow rate

[edit]

To design Archimedes screw turbines and hydropower plants, it is essential to estimate the amount of water is passing through the screw turbine since the amount of power generated by an Archimedes screw turbine is proportional to the volume flow rate of water through it. The volume of water that enters an Archimedes screw turbine depends on the inlet water depth and the screw's rotation speed. To estimates the total flow rate passing through an Archimedes screw turbine for different rotation speeds (ω) and inlet water levels the following equation could be used:

Where , and are constants related to the screw properties. Preliminary investigations suggest that , , and give reasonable predictions of for a wide range of small to full-scale AST sizes.

Examples

[edit]
United Kingdom
United States

References

[edit]
  1. ^ United States 1434138, William Moerscher, "Water-power system", issued October 31, 1922 
  2. ^ YoosefDoost, Arash; Lubitz, William David (2020-09-08). "Archimedes Screw Turbines: A Sustainable Development Solution for Green and Renewable Energy Generation—A Review of Potential and Design Procedures". Sustainability. 12 (18): 7352. doi:10.3390/su12187352. ISSN 2071-1050.
  3. ^ "Woolston | Planning Application". Warrington Borough Council. Retrieved 2021-03-22.
  4. ^ "Woolston | Project Overview". renfin.eu. Retrieved 2021-03-22.
  5. ^ "Woolston | Local News Items". Warrington Worldwide. Retrieved 2021-03-22.
  6. ^ "Totnes | MannPower Consulting". www.mannpower-hydro.co.uk. Retrieved 2016-08-05.
  7. ^ "Romney | MannPower Consulting". www.mannpower-hydro.co.uk. Retrieved 2016-08-05.
  8. ^ "Bealeys Weir | MannPower Consulting". www.mannpower-hydro.co.uk. Retrieved 2016-08-05.
  9. ^ a b c d e f g "Hydro Power Case Studies, Micro-Hydro Case Studies - Western Renewable Energy". www.westernrenew.co.uk. Retrieved 2016-08-05.
  10. ^ "Hydropower returns to Cragside". National Trust. Retrieved 2016-08-09.
  11. ^ Philippa Gerrard (4 November 2016). "Powering Up". Press and Journal. Retrieved 20 November 2023.
  12. ^ Andrew Ragall, Ancient technology in Meriden's Hannover Pond dam begins generating electricity, Meriden Record Journal, April 27, 2017
  13. ^ New England Hydropower Energizes First Archimedes Screw Turbine in U.S., PR Newswire, April 27, 2017

Further reading

[edit]
  • P. J. Kantert: Manual for Archimedean Screw Pump, Hirthammer Verlag 2008, ISBN 978-3-88721-896-6
  • P. J. Kantert: Praxishandbuch Schneckenpumpe. Hirthammer Verlag 2008, ISBN 978-3-88721-202-5
  • K. Brada, K.-A. Radlik - Water Screw Motor to Micro Power Plant - First Experiences of Construction and Operation (1998)
  • K. Brada - Micro Power Plant with Water Screw Motor (1995)
  • K. Brada, K.-A. Radlik - Water Power Screw - Characteristic and Use (1996)
  • K. Brada, K.-A. Radlik, (1996). Water screw motor for micropower plant. 6th Intl. Symp. Heat exchange and renewable energy sources, 43–52, W. Nowak, ed. Wydaw Politechniki Szczecińskiej, Szczecin, Poland.
[edit]