$A consideration based on the grouting-model for fractured rock mass$

A consideration based on the grouting-model for fractured rock mass

A variety of types of grouting models have been proposed. We propose the parallel plates radial flow model with limited geometrical parameters. The model is considered to be useful to the intelligent construction for grouting. Also, the model is applicable mainly to a developed fractured rock mass i...

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Veröffentlicht in:	Japanese Geotechnical Journal 2018/12/31, Vol.13(4), pp.359-378
Hauptverfasser:	KISHI, Hirokazu, KOBAYASHI, Kaoru, KAKUE, Toshiaki
Format:	Artikel
Sprache:	eng ; jpn
Schlagworte:	Apertures Computational fluid dynamics Computer simulation critical Reynolds number critical velocity Flow rates Flow velocity Fluid flow Grout Grouting Hydraulic fracturing Injection Laboratory tests Laminar flow Newtonian fluids Non Newtonian fluids non-Newtonian fluid Parallel plates parallel plates radial flow model Permeability Radial flow Reynolds number Rock masses Rocks Turbulent flow Viscous fluids
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container_title	Japanese Geotechnical Journal
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creator	KISHI, Hirokazu KOBAYASHI, Kaoru KAKUE, Toshiaki
description	A variety of types of grouting models have been proposed. We propose the parallel plates radial flow model with limited geometrical parameters. The model is considered to be useful to the intelligent construction for grouting. Also, the model is applicable mainly to a developed fractured rock mass in which turbulent and laminar flow condition coexists. Therefore the critical Reynolds number is very important to the model, which is related to the transfer condition between laminar and turbulent flow. Thus we conducted laboratory tests in use of single rock fissure and in-situ permeability tests with highly viscous fluid in several dam sights. Moreover, we conducted grouting simulations with the model under consideration on the viscous property of a grout as non-Newtonian fluid. This analysis researched for injection conditions in order to adjust a turbulent-laminar transfer radius to a target grouting radius under a low critical Reynolds number. The result indicates that the condition is available on limited injection pressure, flow rate and grout mix corresponding to each hydraulic fracture-aperture.
doi_str_mv	10.3208/jgs.13.359
format	Article
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We propose the parallel plates radial flow model with limited geometrical parameters. The model is considered to be useful to the intelligent construction for grouting. Also, the model is applicable mainly to a developed fractured rock mass in which turbulent and laminar flow condition coexists. Therefore the critical Reynolds number is very important to the model, which is related to the transfer condition between laminar and turbulent flow. Thus we conducted laboratory tests in use of single rock fissure and in-situ permeability tests with highly viscous fluid in several dam sights. Moreover, we conducted grouting simulations with the model under consideration on the viscous property of a grout as non-Newtonian fluid. This analysis researched for injection conditions in order to adjust a turbulent-laminar transfer radius to a target grouting radius under a low critical Reynolds number. 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We propose the parallel plates radial flow model with limited geometrical parameters. The model is considered to be useful to the intelligent construction for grouting. Also, the model is applicable mainly to a developed fractured rock mass in which turbulent and laminar flow condition coexists. Therefore the critical Reynolds number is very important to the model, which is related to the transfer condition between laminar and turbulent flow. Thus we conducted laboratory tests in use of single rock fissure and in-situ permeability tests with highly viscous fluid in several dam sights. Moreover, we conducted grouting simulations with the model under consideration on the viscous property of a grout as non-Newtonian fluid. This analysis researched for injection conditions in order to adjust a turbulent-laminar transfer radius to a target grouting radius under a low critical Reynolds number. 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We propose the parallel plates radial flow model with limited geometrical parameters. The model is considered to be useful to the intelligent construction for grouting. Also, the model is applicable mainly to a developed fractured rock mass in which turbulent and laminar flow condition coexists. Therefore the critical Reynolds number is very important to the model, which is related to the transfer condition between laminar and turbulent flow. Thus we conducted laboratory tests in use of single rock fissure and in-situ permeability tests with highly viscous fluid in several dam sights. Moreover, we conducted grouting simulations with the model under consideration on the viscous property of a grout as non-Newtonian fluid. This analysis researched for injection conditions in order to adjust a turbulent-laminar transfer radius to a target grouting radius under a low critical Reynolds number. The result indicates that the condition is available on limited injection pressure, flow rate and grout mix corresponding to each hydraulic fracture-aperture.</abstract><cop>Tokyo</cop><pub>The Japanese Geotechnical Society</pub><doi>10.3208/jgs.13.359</doi><tpages>20</tpages><oa>free_for_read</oa></addata></record>
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subjects	Apertures Computational fluid dynamics Computer simulation critical Reynolds number critical velocity Flow rates Flow velocity Fluid flow Grout Grouting Hydraulic fracturing Injection Laboratory tests Laminar flow Newtonian fluids Non Newtonian fluids non-Newtonian fluid Parallel plates parallel plates radial flow model Permeability Radial flow Reynolds number Rock masses Rocks Turbulent flow Viscous fluids
title	A consideration based on the grouting-model for fractured rock mass
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