Publication detail

Valve exploiting the principle of a side channel turbine

JANDOUREK, P. POCHYLÝ, F. HABÁN, V.

Original Title

Valve exploiting the principle of a side channel turbine

Type

conference paper

Language

English

Original Abstract

The presented article deals with a side channel turbine, which can be used as a suitable substitute for a pressure reducing valve. Pressure reducing valves are a source of high hydraulic losses. The aim is to replace them by a side channel turbine. With that in mind, hydraulic losses can be replaced by a production of electrical energy at comparable characteristics of the reducing valve and the side channel turbine. The basis for the design is the loss characteristics of the pressure reducing valve. Thereby create a new kind of turbine valve with speed-controlled flow in dependence of the runner revolution. It is technical innovation and new renewable source of energy, which can be in future used in rehabilitation or projecting of pumped-storage power plants. It also increases the power of the power plant.

Keywords

Valve, Turbine, Turbine valve, Side channel turbine, Regenerative turbine, Peripheral turbine, Vortex turbine, Turbine pump.

Authors

JANDOUREK, P.; POCHYLÝ, F.; HABÁN, V.

Released

4. 4. 2017

Publisher

IOP Publishing

ISBN

1742-6588

Periodical

Journal of Physics: Conference Series

Year of study

813

Number

1

State

United Kingdom of Great Britain and Northern Ireland

Pages from

1

Pages to

5

Pages count

5

URL

Full text in the Digital Library

BibTex

@inproceedings{BUT135149,
  author="Pavel {Jandourek} and František {Pochylý} and Vladimír {Habán}",
  title="Valve exploiting the principle of a side channel turbine",
  booktitle="Journal of Physics: Conference Series",
  year="2017",
  journal="Journal of Physics: Conference Series",
  volume="813",
  number="1",
  pages="1--5",
  publisher="IOP Publishing",
  doi="10.1088/1742-6596/813/1/012026",
  issn="1742-6588",
  url="http://iopscience.iop.org/article/10.1088/1742-6596/813/1/012026"
}