about
Assessment of ground conditions near a mine portal using ground penetrating radarApplication of ground penetrating radar to evaluate the extent of polyurethane grout infiltration for mine roof control: a case studyUse of ground penetrating radar and Schmidt Hammer tests to determine the structural integrity of a mine sealRemotely installed mine seals for mine fire controlThe use of nitrogen-enhanced foam at the Pinnacle mine fireEvaluation of gas-enhanced foam for suppressing coal mine firesEvaluation of mine seals using ground penetrating radarUse of ground penetrating radar technology for mining applicationsRemote mine fire suppression technologyNIOSH mine fire research in the United StatesTesting and evaluation of an inflatable temporary ventilation control deviceUse of Rocsil® foam to remotely construct mine sealsDemonstration of remote mine seal constructionEvaluation of deep-seated crib block fires and direct-application fire suppression agentsApplication of gas-enhanced foam at the Excel No. 3 mine fireUse of CFD modeling to study inert gas injection into a sealed mine areaApplication of ground penetrating radar to assess ground control problems in two underground limestone minesEvaluation of remotely installed mine seals for mine fire controlUse of Rocsil foam to remotely construct mine sealsEvaluation of deep-seated crib block fires and direct-application fire suppression agentsDemonstration of remote mine seal constructionThe status of mine fire research in the United StatesEvaluation of deep-seated crib block fire testsMine fires: measuring the efficacy of gas-enhanced foamNew inertion technologyUse of pressure swing adsorption technology to inert sealed mine areas with nitrogenCoal mine inertization by remote applicationRecent National Institute for Occupational Safety and Health research using ground penetrating radar for detection of mine voidsTechnology for remote mine seal constructionUnderstanding mine fires by determining the characteristics of deep-seated firesA Case Study of Water Level Fluctuations Over a Series of Longwall Panels in the Northern Appalachian Coal RegionA comparison of subsidence prediction models for longwall and room-and-pillar conditionsBureau of Mines subsidence research in the eastern coal provinceThe Consequence of Longwall Mining of Surface StructuresDevelopment of a model to predict longwall gas emissions resulting from overburden failureUsing vertical boreholes to remove methane from the Mary Lee coalbed, Warrior Basin, Alabama - a case studyImproved methods for monitoring production from vertical degasification wellsMethane drainage: experience with hydraulic stimulation through slotted casingMethane drainage ahead of mining using foam stimulation: Mary Lee Coalbed, AlabamaThe Bureau of Mines Subsidence Research Program
P50
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P50
description
researcher at NIOSH
@en
name
Michael A. Trevits
@ast
Michael A. Trevits
@en
Michael A. Trevits
@es
Michael A. Trevits
@nl
type
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Michael A. Trevits
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Michael A. Trevits
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Michael A. Trevits
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Michael A. Trevits
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altLabel
Michael Trevits
@en
prefLabel
Michael A. Trevits
@ast
Michael A. Trevits
@en
Michael A. Trevits
@es
Michael A. Trevits
@nl
P214
P21
P214
P31
P735
P7859
lccn-n87857871