Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme

Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme

Pumped hydroelectric energy storage (PHES) projects are being considered worldwide to achieve renewable energy targets and to stabilize baseload energy supply from intermittent renewable energy sources. Unlike conventional hydroelectric systems that only pass water downstream, a feature of PHES sche...

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Bibliographic Details
Main Authors: Katherine E. Doyle, Nathan Ning, Luiz G. M. Silva, Eduardo M. Brambilla, Craig A. Boys, Z. Daniel Deng, Tao Fu, Jan A. du Preez, Wayne Robinson, Lee J. Baumgartner
Format: Article
Language:English
Published: Frontiers Media S.A. 2020-10-01
Series:Frontiers in Environmental Science
Subjects:
pumped hydropower
renewable energy
invasive species
Francis turbine
pressure
shear strain
Online Access:https://www.frontiersin.org/articles/10.3389/fenvs.2020.563654/full
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spelling doaj-999f80db28b6417ca8e00a1f517cc7202020-11-25T03:03:04ZengFrontiers Media S.A.Frontiers in Environmental Science2296-665X2020-10-01810.3389/fenvs.2020.563654563654Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric SchemeKatherine E. Doyle0Nathan Ning1Luiz G. M. Silva2Luiz G. M. Silva3Eduardo M. Brambilla4Craig A. Boys5Craig A. Boys6Z. Daniel Deng7Tao Fu8Jan A. du Preez9Wayne Robinson10Lee J. Baumgartner11Institute for Land, Water and Society, Charles Sturt University, Albury, NSW, AustraliaInstitute for Land, Water and Society, Charles Sturt University, Albury, NSW, AustraliaInstitute for Land, Water and Society, Charles Sturt University, Albury, NSW, AustraliaETH-Zurich, Stocker Lab, Institute of Environmental Engineering (IfU), Zurich, SwitzerlandDepartamento de Zoologia, Instituto de Biociências, UNESP – Universidade Estadual Paulista, São Paulo, BrazilInstitute for Land, Water and Society, Charles Sturt University, Albury, NSW, AustraliaNew South Wales Department of Primary Industries, Port Stephens Fisheries Institute, Taylors Beach, NSW, AustraliaHydrology Group, Pacific Northwest National Laboratory, Richland, WA, United StatesHydrology Group, Pacific Northwest National Laboratory, Richland, WA, United StatesJAD Systems LLC, Kingswood, TX, United StatesInstitute for Land, Water and Society, Charles Sturt University, Albury, NSW, AustraliaInstitute for Land, Water and Society, Charles Sturt University, Albury, NSW, AustraliaPumped hydroelectric energy storage (PHES) projects are being considered worldwide to achieve renewable energy targets and to stabilize baseload energy supply from intermittent renewable energy sources. Unlike conventional hydroelectric systems that only pass water downstream, a feature of PHES schemes is that they rely on bi-directional water flow. In some cases, this flow can be across different waterbodies or catchments, posing a risk of inadvertently expanding the range of aquatic biota such as fish. The risk of this happening depends on the likelihood of survival of individuals, which remains poorly understood for turbines that are pumping rather than generating. This study quantified the survival of a globally widespread and invasive poeciliid fish, Eastern gambusia (Gambusia holbrooki), when exposed to three hydraulic stresses characteristic of those experienced through a PHES during the pumping phase. A shear flume and hyperbaric chamber were used to expose fish to different strain rates and rapid and sustained pressurization, respectively. Blade strike models were also used to predict fish survival through a Francis dual turbine/pump. Simulated ranges were based on design and operational conditions provided for a PHES scheme proposed in south-eastern Australia. All gambusia tested survived high levels of shear stress (up to 1,853 s−1), extremely high pressurization (up to 7,600 kPa gauge pressure) and the majority (>93%) were unlikely to be struck by a turbine blade. Given their tolerance to these extreme simulated stresses, we conclude that gambusia will likely survive passage through the simulated PHES scheme if they are entrained at the intake. Therefore, where a new PHES project poses the risk of inadvertently expanding the range of gambusia or similar poeciliid species, measures to minimize their spread or mitigate their ecosystem impacts should be considered.https://www.frontiersin.org/articles/10.3389/fenvs.2020.563654/fullpumped hydropowerrenewable energyinvasive speciesFrancis turbinepressureshear strain
collection DOAJ
language English
format Article
sources DOAJ
author Katherine E. Doyle
Nathan Ning
Luiz G. M. Silva
Luiz G. M. Silva
Eduardo M. Brambilla
Craig A. Boys
Craig A. Boys
Z. Daniel Deng
Tao Fu
Jan A. du Preez
Wayne Robinson
Lee J. Baumgartner
spellingShingle Katherine E. Doyle
Nathan Ning
Luiz G. M. Silva
Luiz G. M. Silva
Eduardo M. Brambilla
Craig A. Boys
Craig A. Boys
Z. Daniel Deng
Tao Fu
Jan A. du Preez
Wayne Robinson
Lee J. Baumgartner
Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme
Frontiers in Environmental Science
pumped hydropower
renewable energy
invasive species
Francis turbine
pressure
shear strain
author_facet Katherine E. Doyle
Nathan Ning
Luiz G. M. Silva
Luiz G. M. Silva
Eduardo M. Brambilla
Craig A. Boys
Craig A. Boys
Z. Daniel Deng
Tao Fu
Jan A. du Preez
Wayne Robinson
Lee J. Baumgartner
author_sort Katherine E. Doyle
title Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme
title_short Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme
title_full Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme
title_fullStr Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme
title_full_unstemmed Gambusia holbrooki Survive Shear Stress, Pressurization and Avoid Blade Strike in a Simulated Pumped Hydroelectric Scheme
title_sort gambusia holbrooki survive shear stress, pressurization and avoid blade strike in a simulated pumped hydroelectric scheme
publisher Frontiers Media S.A.
series Frontiers in Environmental Science
issn 2296-665X
publishDate 2020-10-01
description Pumped hydroelectric energy storage (PHES) projects are being considered worldwide to achieve renewable energy targets and to stabilize baseload energy supply from intermittent renewable energy sources. Unlike conventional hydroelectric systems that only pass water downstream, a feature of PHES schemes is that they rely on bi-directional water flow. In some cases, this flow can be across different waterbodies or catchments, posing a risk of inadvertently expanding the range of aquatic biota such as fish. The risk of this happening depends on the likelihood of survival of individuals, which remains poorly understood for turbines that are pumping rather than generating. This study quantified the survival of a globally widespread and invasive poeciliid fish, Eastern gambusia (Gambusia holbrooki), when exposed to three hydraulic stresses characteristic of those experienced through a PHES during the pumping phase. A shear flume and hyperbaric chamber were used to expose fish to different strain rates and rapid and sustained pressurization, respectively. Blade strike models were also used to predict fish survival through a Francis dual turbine/pump. Simulated ranges were based on design and operational conditions provided for a PHES scheme proposed in south-eastern Australia. All gambusia tested survived high levels of shear stress (up to 1,853 s−1), extremely high pressurization (up to 7,600 kPa gauge pressure) and the majority (>93%) were unlikely to be struck by a turbine blade. Given their tolerance to these extreme simulated stresses, we conclude that gambusia will likely survive passage through the simulated PHES scheme if they are entrained at the intake. Therefore, where a new PHES project poses the risk of inadvertently expanding the range of gambusia or similar poeciliid species, measures to minimize their spread or mitigate their ecosystem impacts should be considered.
topic pumped hydropower
renewable energy
invasive species
Francis turbine
pressure
shear strain
url https://www.frontiersin.org/articles/10.3389/fenvs.2020.563654/full
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