On the basically single-type excitation source of resonance in the wind tunnel and in the hydroturbine channel of a hydraulic power plant

The operation of any hydraulic power plant is accompanied by pressure pulsations that are caused by vortex rope under the runner, rotor–stator interaction and various transitions during changes in operating conditions or start-ups and shut-downs. Water in the conduit undergoes volumetric changes due to these pulsations. Compression and expansion of the water are among the mechanisms by which energy is dissipated in the system, and this corresponds to the second viscosity of water. The better our knowledge of energy dissipation, the greater the possibility of a safer and more economic operation of the hydraulic power plant. This paper focuses on the determination of the second viscosity of water in a conduit. The mathematical apparatus, which is described in the article, is applied to data obtained during commissioning tests in a water storage power plant. The second viscosity is determined using measurements of pressure pulsations in the conduit induced with a ball valve. The result shows a dependency of second viscosity on the frequency of pulsations.

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Sealing of upper basin for hydraulic power plant Brežice

ce/papers ◽

10.1002/cepa.697 ◽

2018 ◽

Vol 2 (2-3) ◽

pp. 359-364

Author(s):

Mario MARIC ◽

Gorazd COPEK ◽

Lars VOLLMERT

Keyword(s):

Power Plant ◽

Hydraulic Power

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Coal-Shipping Appliances and Hydraulic Power-Plant at the Alexandra (Newport and South Wales) Docks and Railway, Newport, Mon

Proceedings of the Institution of Mechanical Engineers ◽

10.1243/pime_proc_1906_071_009_02 ◽

1906 ◽

Vol 71 (1) ◽

pp. 435-498

Author(s):

John Macaulay

Keyword(s):

Power Plant ◽

Hydraulic Power ◽

South Wales

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The Ocean Thermal Gradient Hydraulic Power Plant and Its Scope

Volume 1: Offshore Technology; Ocean Space Utilization ◽

10.1115/omae2003-37285 ◽

2003 ◽

Author(s):

Earl J. Beck

Keyword(s):

Power Plant ◽

Thermal Gradient ◽

Cold Water ◽

Working Fluid ◽

Hydraulic Power ◽

Tropical Oceans ◽

Thermal Energy Conversion ◽

Near Shore ◽

Power Outputs ◽

Ocean Thermal Energy

Heretofore, the concept of developing power from the tropical oceans, (Ocean Thermal Energy Conversion, or OTEC) has assumed the mooring of large platforms holding the plants in deep water to secure the coldest possible condensing water. As the Ocean Thermal Gradient Hydraulic Power Plant (OTGHPP) does not depend, on the expansion of a working fluid, other than forming a foam of steam bubbles. It does not need extremely cold water as would be dictated by Carnot’s concept of efficiency and the 2nd Law of Thermodynamics. Plants may be based on or near-shore on selected tropical islands, where cool but not extremely cold water may be available at moderate depths. This paper discusses the above possibilities and two possible plant locations, as well as projected power outputs. The location and utilization of large of amounts of power on isolated islands, where cabling of power to major population centers would not be feasible are discussed. Two that come to mind are the reduction of bauxite to produce aluminum and the of current interest is the electrolyzing of water to produce gaseous hydrogen fuel to be used in fuel cells, with oxygen as a by-product.

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Wind Tunnel Experiment for Predicting a Visible Plume Region from a Nuclear Power Plant Cooling Tower

Journal of Applied Meteorology and Climatology ◽

10.1175/jamc-d-13-0153.1 ◽

2014 ◽

Vol 53 (2) ◽

pp. 234-241 ◽

Cited By ~ 1

Author(s):

Dong-Peng Guo ◽

Ren-Tai Yao ◽

Dan Fan

Keyword(s):

Power Plant ◽

Nuclear Power Plant ◽

Wind Tunnel ◽

Flow Field ◽

Turbulence Intensity ◽

Nuclear Power ◽

Cooling Tower ◽

Wind Tunnel Experiment ◽

Plume Rise ◽

Plume Region

AbstractThis paper introduces a wind tunnel experiment to study the effect of the cooling tower of a nuclear power plant on the flow and the characteristics of visible plume regions. The relevant characteristics of the flow field near the cooling tower, such as the plume rise and the visible plume region, are compared with the results of previous experimental data from Électricité de France (EDF) and the Briggs formulas. The results show that the wind tunnel experiment can simulate the top backflow of the cooling tower and the rear cavity regions among others. In the near-wake region, including the recirculation cavity, mean velocity decreases and turbulence intensity increases significantly. The maximum turbulence intensity observed is 0.5. In addition, the disturbed flow extent of the cooling tower top reaches 1.5 times the cooling tower height. Analysis of the visible plume region shows that the wind tunnel experiment can simulate the variation of a visible plume region. The results are consistent with the wind tunnel experiment of EDF. Moreover, the plume rise analysis shows that the wind tunnel experiment data are in agreement with the Briggs formulas for 50–200 m. As a whole, the proposed wind tunnel experiment can simulate the flow field variation of the visible plume region and the plume rise around the buildings with reasonable accuracy.

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