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class="u-taCenter"></div><div class="profile--tab_content_container js-tab-pane tab-pane active" id="all"><div class="profile--tab_heading_container js-section-heading" data-section="Papers" id="Papers"><h3 class="profile--tab_heading_container">Papers by Michel Lebouche</h3></div><div class="js-work-strip profile--work_container" data-work-id="106530878"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/106530878/A_Numerical_Algorithm_For_Simulation_Of_NonNewtonian_Fluid_Flowing_Through_A_SuddenExpansion"><img alt="Research paper thumbnail of A Numerical Algorithm For Simulation Of NonNewtonian Fluid Flowing Through A SuddenExpansion" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link 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106530878; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=106530878]").text(description); $(".js-view-count[data-work-id=106530878]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 106530878; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='106530878']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=106530878]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":106530878,"title":"A Numerical Algorithm For Simulation Of NonNewtonian Fluid Flowing Through A 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href="https://www.academia.edu/25967826/Semi_analytical_inverse_heat_conduction_on_a_rotating_cylinder_with_Laplace_and_Fourier_transforms"><img alt="Research paper thumbnail of Semi-analytical inverse heat conduction on a rotating cylinder with Laplace and Fourier transforms" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967826/Semi_analytical_inverse_heat_conduction_on_a_rotating_cylinder_with_Laplace_and_Fourier_transforms">Semi-analytical inverse heat conduction on a rotating cylinder with Laplace and Fourier transforms</a></div><div class="wp-workCard_item"><span>Inverse Problems in Science and Engineering</span><span>, 2008</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This work aims to verify the feasibility of the estimation of heat fluxes during the cooling of a...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This work aims to verify the feasibility of the estimation of heat fluxes during the cooling of a rotating cylinder by an impinging jet. A semi-analytical method has been developed for this two-dimensional inverse heat conduction problem (IHCP) using Laplace and Fourier transforms technique. The simulations of inversion for two representative test cases show that the estimated surface heat flux</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967826"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967826"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967826; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967826]").text(description); $(".js-view-count[data-work-id=25967826]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967826; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967826']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967826]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967826,"title":"Semi-analytical inverse heat conduction on a rotating cylinder with Laplace and Fourier transforms","internal_url":"https://www.academia.edu/25967826/Semi_analytical_inverse_heat_conduction_on_a_rotating_cylinder_with_Laplace_and_Fourier_transforms","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967824"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967824/Energetic_budget_on_an_evaporating_monodisperse_droplet_stream_using_combined_optical_methods"><img alt="Research paper thumbnail of Energetic budget on an evaporating monodisperse droplet stream using combined optical methods" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967824/Energetic_budget_on_an_evaporating_monodisperse_droplet_stream_using_combined_optical_methods">Energetic budget on an evaporating monodisperse droplet stream using combined optical methods</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2002</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">ABSTRACT Aerothermal properties in a fuel spray is a central problem in the field of the design o...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">ABSTRACT Aerothermal properties in a fuel spray is a central problem in the field of the design of the combustion chambers of automotive engines, turbojets or rocket engines. Heat and mass transfer models are necessary in the predictive calculation schemes used by the motorists. Reliable experimental data must be obtained for both the validation and development of new physical models linked to heat transfer and evaporation in sprays, where aerodynamic interactions have a key role. This paper proposes an experimental study of the energetic budget of a monodisperse ethanol droplet stream, injected in the thermal boundary layer of a vertical heated plate. The droplet size reduction is measured using a light scattering technique (interferential method) in order to characterize the evaporation, as the droplet mean temperature is monitored using the two colors laser-induced fluorescence technique. The convection heat transfer coefficient and the Nusselt number are inferred from the overall energetic budget, as a function of the inter-droplet distance, characterizing the interaction regime. The results are compared to physical models combined with numerical simulations available in the literature, for moving, evaporating isolated droplets and for three droplets arrangement in linear stream.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967824"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967824"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967824; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967824]").text(description); $(".js-view-count[data-work-id=25967824]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967824; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967824']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967824]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967824,"title":"Energetic budget on an evaporating monodisperse droplet stream using combined optical methods","internal_url":"https://www.academia.edu/25967824/Energetic_budget_on_an_evaporating_monodisperse_droplet_stream_using_combined_optical_methods","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967822"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967822/Local_analysis_of_heat_transfer_inside_corrugated_channel"><img alt="Research paper thumbnail of Local analysis of heat transfer inside corrugated channel" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967822/Local_analysis_of_heat_transfer_inside_corrugated_channel">Local analysis of heat transfer inside corrugated channel</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2005</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Experiments are performed to study effects of hydrodynamic conditions on the enhancement of heat ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Experiments are performed to study effects of hydrodynamic conditions on the enhancement of heat transfer for single phase flow. These experiments have been conducted for a wide range of Reynolds numbers, (0&amp;amp;amp;amp;amp;amp;amp;amp;amp;amp;lt;Re&amp;amp;amp;amp;amp;amp;amp;amp;amp;amp;lt;7500) in order to obtain the different regimes from steady laminar to turbulent. A two-dimensional corrugated test section which has been instrumented with thermocouples can be heated by electrical</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967822"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967822"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967822; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967822]").text(description); $(".js-view-count[data-work-id=25967822]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967822; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967822']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967822]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967822,"title":"Local analysis of heat transfer inside corrugated channel","internal_url":"https://www.academia.edu/25967822/Local_analysis_of_heat_transfer_inside_corrugated_channel","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967821"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967821/Heat_and_mass_transfer_of_combusting_monodisperse_droplets_in_a_linear_stream"><img alt="Research paper thumbnail of Heat and mass transfer of combusting monodisperse droplets in a linear stream" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967821/Heat_and_mass_transfer_of_combusting_monodisperse_droplets_in_a_linear_stream">Heat and mass transfer of combusting monodisperse droplets in a linear stream</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2005</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Heat and mass transfer phenomena in fuel sprays is a key issue in the field of the design of the ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Heat and mass transfer phenomena in fuel sprays is a key issue in the field of the design of the combustion chambers where the fuel is injected on a liquid form. The development and validation of new physical models related to heat transfer and evaporation in sprays requires reliable experimental data. This paper reports on an experimental study of the</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967821"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967821"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967821; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967821]").text(description); $(".js-view-count[data-work-id=25967821]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967821; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967821']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967821]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967821,"title":"Heat and mass transfer of combusting monodisperse droplets in a linear stream","internal_url":"https://www.academia.edu/25967821/Heat_and_mass_transfer_of_combusting_monodisperse_droplets_in_a_linear_stream","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967819"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967819/Experimental_thermomechanic_study_of_Newtonian_and_non_Newtonian_suspension_flows"><img alt="Research paper thumbnail of Experimental thermomechanic study of Newtonian and non-Newtonian suspension flows" class="work-thumbnail" src="https://attachments.academia-assets.com/46318366/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967819/Experimental_thermomechanic_study_of_Newtonian_and_non_Newtonian_suspension_flows">Experimental thermomechanic study of Newtonian and non-Newtonian suspension flows</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2005</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Hydrodynamic and thermal analysis of suspension flows is a difficult but fundamental task for the...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Hydrodynamic and thermal analysis of suspension flows is a difficult but fundamental task for the sterilization problems of particle charged fluids in food industries and also in any process where we can find flow with seeded particles. Nowadays, the influence of solid suspended particles on the flow is not yet a well known problem. Nevertheless, the solid particles have a strong influence on the rheological mixture脮s behaviour. The new approach of these solid-liquid suspension flows that we propose is based on experimental data and theoretical considerations. We use hard sphere approach in order to model the pressure drop assuming the mixture as an effective continuous medium. On these bases, we present a model of the heat transfer at the wall.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="de649bb8c0551ebd358dd0985298a03f" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318366,"asset_id":25967819,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318366/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967819"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967819"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967819; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967818"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967818/Mass_transfer_properties_in_a_grid_generated_turbulent_flow_some_experimental_investigations_about_the_concept_of_turbulent_diffusivity"><img alt="Research paper thumbnail of Mass transfer properties in a grid generated turbulent flow: some experimental investigations about the concept of turbulent diffusivity" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967818/Mass_transfer_properties_in_a_grid_generated_turbulent_flow_some_experimental_investigations_about_the_concept_of_turbulent_diffusivity">Mass transfer properties in a grid generated turbulent flow: some experimental investigations about the concept of turbulent diffusivity</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 1998</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">ABSTRACT</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967818"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967818"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967818; 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} }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967817"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967817/Ecoulement_de_fluides_non_newtoniens_a_travers_des_elargissements_brusques"><img alt="Research paper thumbnail of Ecoulement de fluides non newtoniens a travers des elargissements brusques" class="work-thumbnail" src="https://attachments.academia-assets.com/46318353/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967817/Ecoulement_de_fluides_non_newtoniens_a_travers_des_elargissements_brusques">Ecoulement de fluides non newtoniens a travers des elargissements brusques</a></div><div class="wp-workCard_item"><span>International Communications in Heat and Mass Transfer</span><span>, 1997</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">The present paper is concerned with non newtonian pseudoplastic fluid flow across an abrupt enlar...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">The present paper is concerned with non newtonian pseudoplastic fluid flow across an abrupt enlargement. Basic equations are integrated by a finite volume scheme. The obtained results clearly display the stabilizing effect of fluid pseudoplasticity. The recirculation zone and re-etablishment length diminish when behaviour index decreases. It is noticed that there is an agreement between the numerical results and the results of experimental study carried out in our laboratory. 漏 1997 Elsevier Science Ltd RESUME La pr6sente 6tude concerne l'6coulement de fluides non newtoniens pseudoplastiques h travers des 61argissements brusques. Les calculs sont effectu6s par un code aux volumes finis. L'effet stabilisant du caract~re rh6ofluidifiant du fluide est mis en 6vidence. La zone de recirculation et la longueur d'6tablissement diminuent quand l'indice de structure d6crott. 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967814"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967814/Local_heat_transfer_from_a_hot_plate_to_a_water_jet"><img alt="Research paper thumbnail of Local heat transfer from a hot plate to a water jet" class="work-thumbnail" src="https://attachments.academia-assets.com/46318356/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967814/Local_heat_transfer_from_a_hot_plate_to_a_water_jet">Local heat transfer from a hot plate to a water jet</a></div><div class="wp-workCard_item"><span>Heat and Mass Transfer</span><span>, 2003</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Jet impingement boiling is very efficient in cooling of hot surfaces as a part of the impinging l...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Jet impingement boiling is very efficient in cooling of hot surfaces as a part of the impinging liquid evaporates. Because of its importance to many cooling procedures, investigations on basic mechanisms of jet impingement boiling heat transfer are needed. Until now, most of the experimental studies, carried out under steady-state conditions, used a heat flux controlled system and were limited by the critical heat flux (CHF). The present study focuses on steady-state experiments along the entire boiling curve for hot plate temperatures of up to 700掳C. A test section has been built up simulating a hot plate. It is divided into 8 independently heated modules of 10 mm length to enable local heat transfer measurements. By means of temperature controlled systems for each module local steady-state experiments in the whole range between single phase heat transfer and film boiling are possible. By solving the two dimensional inverse heat conduction problem, the local heat flux and the corresponding wall temperature on the surface of each module can be computed. The measurements show important differences between boiling curves measured at the stagnation line and those obtained in the parallel flow region. At the stagnation line, the transition boiling regime is characterised by very high heat fluxes, extended to large wall superheats. Inversely, boiling curves in the parallel flow region are very near to classical ones obtained for forced convection boiling. The analysis of temperature fluctuations measured at a depth of 0.8 mm from the boiling surface enables some conclusions on the boiling mechanism in the different boiling regimes.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="ba1c95e9633df118a43390c337654a8c" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318356,"asset_id":25967814,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318356/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967814"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967814"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967814; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967813"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967813/Non_intrusive_temperature_measurements_using_three_color_laser_induced_fluorescence"><img alt="Research paper thumbnail of Non-intrusive temperature measurements using three-color laser-induced fluorescence" class="work-thumbnail" src="https://attachments.academia-assets.com/46318357/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967813/Non_intrusive_temperature_measurements_using_three_color_laser_induced_fluorescence">Non-intrusive temperature measurements using three-color laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2004</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper presents a new temperature measurement technique in a liquid, based on laser-induced f...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper presents a new temperature measurement technique in a liquid, based on laser-induced fluorescence of rhodamine B. The fluorescence intensity is detected on three spectral bands, where the ratios between the emission of each band determine the temperature while correcting for the effects of fluorescent re-absorption. In addition, the influence of parameters such as probe volume size, dye concentration, and Beer's absorption is removed. The principles of the technique are described in this paper, and the technique is demonstrated on a heated liquid jet studied under a constant and a spatially variable dye concentration.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="7625e49d78f1a6ded15019c718d7ebb9" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318357,"asset_id":25967813,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318357/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967813"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967813"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967813; 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dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "7625e49d78f1a6ded15019c718d7ebb9" } } $('.js-work-strip[data-work-id=25967813]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967813,"title":"Non-intrusive temperature measurements using three-color laser-induced fluorescence","internal_url":"https://www.academia.edu/25967813/Non_intrusive_temperature_measurements_using_three_color_laser_induced_fluorescence","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[{"id":46318357,"title":"","file_type":"pdf","scribd_thumbnail_url":"https://attachments.academia-assets.com/46318357/thumbnails/1.jpg","file_name":"s00348-003-0748-020160607-556-onzqfb.pdf","download_url":"https://www.academia.edu/attachments/46318357/download_file","bulk_download_file_name":"Non_intrusive_temperature_measurements_u.pdf","bulk_download_url":"https://d1wqtxts1xzle7.cloudfront.net/46318357/s00348-003-0748-020160607-556-onzqfb-libre.pdf?1465328352=\u0026response-content-disposition=attachment%3B+filename%3DNon_intrusive_temperature_measurements_u.pdf\u0026Expires=1739817798\u0026Signature=TcbkzapNhqSMehzwc~2xaJATWpa0Ckt6m6LTXWCaT1-9KYOM7uVM15U94NPV1cAsLasUiClYrhScUdkqj8D5oC~zDydNGsh1RNip0nYUthBTyw3Of1ADiCe59D4kZbv16S8C4IR6bI4Jt0lrfgBZhqHRgSdSgG6Z4QzMMlM~O4jhzl5YKls7fRa6rviwJHNAB7a2yxDpN9f9zcWbWCXXRGiYnfccGK0UyUDcRouN~qR-IsJPgaq~2byfY1lO83WUo4AczA5-4t0MEbbDV3g5SGS-2wXGB1YUflITocp3o5-nEB65uVa5yaF8QC1jcxTPxcMqGTJh7xDPtH2PTdsS4Q__\u0026Key-Pair-Id=APKAJLOHF5GGSLRBV4ZA"}]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967812"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967812/Measurement_of_the_temperature_distribution_within_monodisperse_combusting_droplets_in_linear_streams_using_two_color_laser_induced_fluorescence"><img alt="Research paper thumbnail of Measurement of the temperature distribution within monodisperse combusting droplets in linear streams using two-color laser-induced fluorescence" class="work-thumbnail" src="https://attachments.academia-assets.com/46318358/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967812/Measurement_of_the_temperature_distribution_within_monodisperse_combusting_droplets_in_linear_streams_using_two_color_laser_induced_fluorescence">Measurement of the temperature distribution within monodisperse combusting droplets in linear streams using two-color laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2003</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Two-color laser-induced fluorescence can be use to perform space-averaged flying droplet temperat...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Two-color laser-induced fluorescence can be use to perform space-averaged flying droplet temperature measurements. In this paper, the possibility to extend this technique to the measurement of the temperature distribution within a moving combusting droplet is considered and demonstrated. This technique may provide new experimental data related to the heat diffusion in liquid fuel droplets injected in high-temperature gas streams, for example, in combustion chambers. The main principles of the technique and the data reduction process are discussed, and a test on combusting a monodisperse ethanol droplets (200 lm in diameter) stream is presented.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="2fa0e58efe91528d1a9730310ab049b9" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318358,"asset_id":25967812,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318358/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967812"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967812"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967812; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967810"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967810/Temperature_measurements_on_droplets_in_monodisperse_stream_using_laser_induced_fluorescence"><img alt="Research paper thumbnail of Temperature measurements on droplets in monodisperse stream using laser-induced fluorescence" class="work-thumbnail" src="https://attachments.academia-assets.com/46318354/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967810/Temperature_measurements_on_droplets_in_monodisperse_stream_using_laser_induced_fluorescence">Temperature measurements on droplets in monodisperse stream using laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2000</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper presents a novel technique based on laser-induced炉uorescence in liquids, allowing the ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper presents a novel technique based on laser-induced炉uorescence in liquids, allowing the temperature of 200-lm diameter monodisperse droplets to be measured. The droplets are seeded with an organic dye (rhodamine B), and the temperature dependence of th膿</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="79a959a38d93a297b0cf860339033899" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318354,"asset_id":25967810,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318354/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967810"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967810"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967810; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967808"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967808/Evaporating_and_combusting_droplet_temperature_measurements_using_two_color_laser_induced_fluorescence"><img alt="Research paper thumbnail of Evaporating and combusting droplet temperature measurements using two-color laser-induced fluorescence" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967808/Evaporating_and_combusting_droplet_temperature_measurements_using_two_color_laser_induced_fluorescence">Evaporating and combusting droplet temperature measurements using two-color laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2001</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">ABSTRACT 鈥俆he paper presents a new technique based on laser-induced fluorescence, allowing drople...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">ABSTRACT 鈥俆he paper presents a new technique based on laser-induced fluorescence, allowing droplet temperature measurement of evaporating and combusting droplets to be performed. The liquid spray is seeded with a low concentration of rhodamine B. The fluorescence, induced by the green line of an argon laser, is measured on two separated color bands. It is demonstrated that two color bands can be selected for their strong difference in the temperature sensitivity of the fluorescence quantum yield. The determination of the fluorescence ratio between the fluorescence intensity corresponding to each color band allows the tracer concentration and the droplet size dependences to be eliminated. The technique was applied on a monodisperse spray: the effect of a thermal impulse on the distribution of the droplet temperature is studied and, the temperature of combusting droplets is investigated.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967808"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967808"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967808; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967808]").text(description); $(".js-view-count[data-work-id=25967808]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967808; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967808']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967808]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967808,"title":"Evaporating and combusting droplet temperature measurements using two-color laser-induced fluorescence","internal_url":"https://www.academia.edu/25967808/Evaporating_and_combusting_droplet_temperature_measurements_using_two_color_laser_induced_fluorescence","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967806"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967806/Development_of_a_thixotropic_fluid_flow_in_a_pipe"><img alt="Research paper thumbnail of Development of a thixotropic fluid flow in a pipe" class="work-thumbnail" src="https://attachments.academia-assets.com/46318352/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967806/Development_of_a_thixotropic_fluid_flow_in_a_pipe">Development of a thixotropic fluid flow in a pipe</a></div><div class="wp-workCard_item wp-workCard--coauthors"><span>by </span><span><a class="" data-click-track="profile-work-strip-authors" href="https://independent.academia.edu/RDevienne">R. Devienne</a> and <a class="" data-click-track="profile-work-strip-authors" href="https://independent.academia.edu/MichelLebouche">Michel Lebouche</a></span></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2001</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper deals with the interaction between the modi庐cations of the internal structure of a thi...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper deals with the interaction between the modi庐cations of the internal structure of a thixotropic uid and the炉ow development along a pipe. The experi-</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="a8b432ec7afda22cb615344c9f7563b6" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318352,"asset_id":25967806,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318352/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967806"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967806"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967806; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967804"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967804/Simultaneous_temperature_and_2D_velocity_measurements_in_a_turbulent_heated_jet_using_combined_laser_induced_fluorescence_and_LDA"><img alt="Research paper thumbnail of Simultaneous temperature and 2D velocity measurements in a turbulent heated jet using combined laser-induced fluorescence and LDA" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967804/Simultaneous_temperature_and_2D_velocity_measurements_in_a_turbulent_heated_jet_using_combined_laser_induced_fluorescence_and_LDA">Simultaneous temperature and 2D velocity measurements in a turbulent heated jet using combined laser-induced fluorescence and LDA</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 1999</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">... fluorescence quantum yield 0 fluorescence natural quantum yield fluid specific density temper...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">... fluorescence quantum yield 0 fluorescence natural quantum yield fluid specific density temperature relative to ... This assumption is verified in gases, at pressure higher than a few 103 ... correlations, between the axial and radial velocity and the temperature fluctuations are reported ...</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967804"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967804"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967804; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967804]").text(description); $(".js-view-count[data-work-id=25967804]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967804; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967804']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); 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</script> <div class="js-work-strip profile--work_container" data-work-id="25967803"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967803/Wall_shear_measurements_inside_corrugated_channels_using_the_electrochemical_technique"><img alt="Research paper thumbnail of Wall shear measurements inside corrugated channels using the electrochemical technique" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967803/Wall_shear_measurements_inside_corrugated_channels_using_the_electrochemical_technique">Wall shear measurements inside corrugated channels using the electrochemical technique</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 1998</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">We report on an investigation of adiabatic single-phase flow inside two-dimensional and three-dim...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">We report on an investigation of adiabatic single-phase flow inside two-dimensional and three-dimensional channels, with a hydraulic diameter of 0.033鈥卪. This work is a preliminary study to another one that will be carried out with a gas鈥搇iquid mixture. The flow structure is studied using the electrochemical technique. Circular single probes and rectangular sandwich probes are inserted flush to the wall.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967803"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967803"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967803; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967803]").text(description); $(".js-view-count[data-work-id=25967803]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967803; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967803']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967803]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967803,"title":"Wall shear measurements inside corrugated channels using the electrochemical technique","internal_url":"https://www.academia.edu/25967803/Wall_shear_measurements_inside_corrugated_channels_using_the_electrochemical_technique","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967802"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967802/Simultaneous_concentration_and_velocity_measurements_using_combined_laser_induced_fluorescence_and_laser_Doppler_velocimetry_Application_to_turbulent_transport"><img alt="Research paper thumbnail of Simultaneous concentration and velocity measurements using combined laser-induced fluorescence and laser Doppler velocimetry: Application to turbulent transport" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967802/Simultaneous_concentration_and_velocity_measurements_using_combined_laser_induced_fluorescence_and_laser_Doppler_velocimetry_Application_to_turbulent_transport">Simultaneous concentration and velocity measurements using combined laser-induced fluorescence and laser Doppler velocimetry: Application to turbulent transport</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 1996</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper describes the implementation of an optical technique, allowing to perform concentratio...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper describes the implementation of an optical technique, allowing to perform concentration and velocity measurements simultaneously and at the same point. This method is based on the coupling of laser-induced fluorescence of rhodamine B, applied to the determination of local concentration, and laser Doppler velocimetry. The method developed provides an accurate measurement of the concentration-velocity cross-correlation. The latter is</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967802"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967802"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967802; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967802]").text(description); $(".js-view-count[data-work-id=25967802]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967802; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967802']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967802]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967802,"title":"Simultaneous concentration and velocity measurements using combined laser-induced fluorescence and laser Doppler velocimetry: Application to turbulent transport","internal_url":"https://www.academia.edu/25967802/Simultaneous_concentration_and_velocity_measurements_using_combined_laser_induced_fluorescence_and_laser_Doppler_velocimetry_Application_to_turbulent_transport","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967801"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967801/Controlled_cooling_of_a_hot_plate_with_a_water_jet"><img alt="Research paper thumbnail of Controlled cooling of a hot plate with a water jet" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967801/Controlled_cooling_of_a_hot_plate_with_a_water_jet">Controlled cooling of a hot plate with a water jet</a></div><div class="wp-workCard_item"><span>Experimental Thermal and Fluid Science</span><span>, 2002</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Experiments are performed, under steady-state conditions, to study the boiling heat transfer from...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Experiments are performed, under steady-state conditions, to study the boiling heat transfer from a hot plate to a planar jet of water. Temperature control of the heating surface enables the determination of entire boiling curves and the identification of each boiling regime from ...</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967801"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967801"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967801; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967801]").text(description); $(".js-view-count[data-work-id=25967801]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967801; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967801']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967801]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967801,"title":"Controlled cooling of a hot plate with a water jet","internal_url":"https://www.academia.edu/25967801/Controlled_cooling_of_a_hot_plate_with_a_water_jet","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967800"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967800/Heat_transfer_associated_to_a_hot_surface_quenched_by_a_jet_of_oil_in_water_emulsion"><img alt="Research paper thumbnail of Heat transfer associated to a hot surface quenched by a jet of oil-in-water emulsion" class="work-thumbnail" src="https://attachments.academia-assets.com/46318370/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967800/Heat_transfer_associated_to_a_hot_surface_quenched_by_a_jet_of_oil_in_water_emulsion">Heat transfer associated to a hot surface quenched by a jet of oil-in-water emulsion</a></div><div class="wp-workCard_item"><span>Experimental Thermal and Fluid Science</span><span>, 2011</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">In hot rolling, the mechanical properties of steel alloys are conditioned by the rolling process ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">In hot rolling, the mechanical properties of steel alloys are conditioned by the rolling process but a great part is ensured by the cooling of the hot strip mill. Well controlling this cooling rate and its homogeneity is thus of primary importance for obtaining steels with desired mechanical properties. As the water used in the cooling stage of the rolling process can be polluted by oil (in hot mill strip, some oil is used to lubricate the rolls and a part of it can pollute the water), it is important to know how much varies the cooling rates when water is polluted. In this study, transient cooling has been investigated during quenching of a hot metal disk with various subcooled oil-in-water emulsion jets. The aim of this work is to compare the cooling efficiency of oil-in-water emulsion jet with a pure water jet. Experimental investigations of axisymmetric jet impingements on a preheated hot metal disk (500-600掳C) have been performed with various oil-in-water emulsions. The transient cooling heat fluxes on the quenched side are estimated by coupling the measurement of the temperature field of the other side (rear face) with a semi-analytical inverse heat conduction model.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="fab48855073a5f666025cbf032ec9647" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318370,"asset_id":25967800,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318370/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967800"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967800"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967800; 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window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=106530878]").text(description); $(".js-view-count[data-work-id=106530878]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 106530878; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='106530878']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=106530878]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":106530878,"title":"A Numerical Algorithm For Simulation Of NonNewtonian Fluid Flowing Through A SuddenExpansion","internal_url":"https://www.academia.edu/106530878/A_Numerical_Algorithm_For_Simulation_Of_NonNewtonian_Fluid_Flowing_Through_A_SuddenExpansion","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967826"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967826/Semi_analytical_inverse_heat_conduction_on_a_rotating_cylinder_with_Laplace_and_Fourier_transforms"><img alt="Research paper thumbnail of Semi-analytical inverse heat conduction on a rotating cylinder with Laplace and Fourier transforms" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967826/Semi_analytical_inverse_heat_conduction_on_a_rotating_cylinder_with_Laplace_and_Fourier_transforms">Semi-analytical inverse heat conduction on a rotating cylinder with Laplace and Fourier transforms</a></div><div class="wp-workCard_item"><span>Inverse Problems in Science and Engineering</span><span>, 2008</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This work aims to verify the feasibility of the estimation of heat fluxes during the cooling of a...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This work aims to verify the feasibility of the estimation of heat fluxes during the cooling of a rotating cylinder by an impinging jet. A semi-analytical method has been developed for this two-dimensional inverse heat conduction problem (IHCP) using Laplace and Fourier transforms technique. The simulations of inversion for two representative test cases show that the estimated surface heat flux</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967826"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967826"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967826; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967826]").text(description); $(".js-view-count[data-work-id=25967826]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967826; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967826']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967826]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967826,"title":"Semi-analytical inverse heat conduction on a rotating cylinder with Laplace and Fourier transforms","internal_url":"https://www.academia.edu/25967826/Semi_analytical_inverse_heat_conduction_on_a_rotating_cylinder_with_Laplace_and_Fourier_transforms","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967824"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967824/Energetic_budget_on_an_evaporating_monodisperse_droplet_stream_using_combined_optical_methods"><img alt="Research paper thumbnail of Energetic budget on an evaporating monodisperse droplet stream using combined optical methods" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967824/Energetic_budget_on_an_evaporating_monodisperse_droplet_stream_using_combined_optical_methods">Energetic budget on an evaporating monodisperse droplet stream using combined optical methods</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2002</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">ABSTRACT Aerothermal properties in a fuel spray is a central problem in the field of the design o...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">ABSTRACT Aerothermal properties in a fuel spray is a central problem in the field of the design of the combustion chambers of automotive engines, turbojets or rocket engines. Heat and mass transfer models are necessary in the predictive calculation schemes used by the motorists. Reliable experimental data must be obtained for both the validation and development of new physical models linked to heat transfer and evaporation in sprays, where aerodynamic interactions have a key role. This paper proposes an experimental study of the energetic budget of a monodisperse ethanol droplet stream, injected in the thermal boundary layer of a vertical heated plate. The droplet size reduction is measured using a light scattering technique (interferential method) in order to characterize the evaporation, as the droplet mean temperature is monitored using the two colors laser-induced fluorescence technique. The convection heat transfer coefficient and the Nusselt number are inferred from the overall energetic budget, as a function of the inter-droplet distance, characterizing the interaction regime. The results are compared to physical models combined with numerical simulations available in the literature, for moving, evaporating isolated droplets and for three droplets arrangement in linear stream.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967824"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967824"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967824; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967824]").text(description); $(".js-view-count[data-work-id=25967824]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967824; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967824']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967824]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967824,"title":"Energetic budget on an evaporating monodisperse droplet stream using combined optical methods","internal_url":"https://www.academia.edu/25967824/Energetic_budget_on_an_evaporating_monodisperse_droplet_stream_using_combined_optical_methods","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967822"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967822/Local_analysis_of_heat_transfer_inside_corrugated_channel"><img alt="Research paper thumbnail of Local analysis of heat transfer inside corrugated channel" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967822/Local_analysis_of_heat_transfer_inside_corrugated_channel">Local analysis of heat transfer inside corrugated channel</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2005</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Experiments are performed to study effects of hydrodynamic conditions on the enhancement of heat ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Experiments are performed to study effects of hydrodynamic conditions on the enhancement of heat transfer for single phase flow. These experiments have been conducted for a wide range of Reynolds numbers, (0&amp;amp;amp;amp;amp;amp;amp;amp;amp;amp;lt;Re&amp;amp;amp;amp;amp;amp;amp;amp;amp;amp;lt;7500) in order to obtain the different regimes from steady laminar to turbulent. A two-dimensional corrugated test section which has been instrumented with thermocouples can be heated by electrical</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967822"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967822"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967822; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967822]").text(description); $(".js-view-count[data-work-id=25967822]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967822; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967822']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967822]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967822,"title":"Local analysis of heat transfer inside corrugated channel","internal_url":"https://www.academia.edu/25967822/Local_analysis_of_heat_transfer_inside_corrugated_channel","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967821"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967821/Heat_and_mass_transfer_of_combusting_monodisperse_droplets_in_a_linear_stream"><img alt="Research paper thumbnail of Heat and mass transfer of combusting monodisperse droplets in a linear stream" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967821/Heat_and_mass_transfer_of_combusting_monodisperse_droplets_in_a_linear_stream">Heat and mass transfer of combusting monodisperse droplets in a linear stream</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2005</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Heat and mass transfer phenomena in fuel sprays is a key issue in the field of the design of the ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Heat and mass transfer phenomena in fuel sprays is a key issue in the field of the design of the combustion chambers where the fuel is injected on a liquid form. The development and validation of new physical models related to heat transfer and evaporation in sprays requires reliable experimental data. This paper reports on an experimental study of the</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967821"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967821"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967821; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967821]").text(description); $(".js-view-count[data-work-id=25967821]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967821; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967821']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967821]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967821,"title":"Heat and mass transfer of combusting monodisperse droplets in a linear stream","internal_url":"https://www.academia.edu/25967821/Heat_and_mass_transfer_of_combusting_monodisperse_droplets_in_a_linear_stream","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967819"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967819/Experimental_thermomechanic_study_of_Newtonian_and_non_Newtonian_suspension_flows"><img alt="Research paper thumbnail of Experimental thermomechanic study of Newtonian and non-Newtonian suspension flows" class="work-thumbnail" src="https://attachments.academia-assets.com/46318366/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967819/Experimental_thermomechanic_study_of_Newtonian_and_non_Newtonian_suspension_flows">Experimental thermomechanic study of Newtonian and non-Newtonian suspension flows</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 2005</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Hydrodynamic and thermal analysis of suspension flows is a difficult but fundamental task for the...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Hydrodynamic and thermal analysis of suspension flows is a difficult but fundamental task for the sterilization problems of particle charged fluids in food industries and also in any process where we can find flow with seeded particles. Nowadays, the influence of solid suspended particles on the flow is not yet a well known problem. Nevertheless, the solid particles have a strong influence on the rheological mixture脮s behaviour. The new approach of these solid-liquid suspension flows that we propose is based on experimental data and theoretical considerations. We use hard sphere approach in order to model the pressure drop assuming the mixture as an effective continuous medium. On these bases, we present a model of the heat transfer at the wall.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="de649bb8c0551ebd358dd0985298a03f" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318366,"asset_id":25967819,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318366/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967819"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967819"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967819; 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dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "de649bb8c0551ebd358dd0985298a03f" } } $('.js-work-strip[data-work-id=25967819]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967819,"title":"Experimental thermomechanic study of Newtonian and non-Newtonian suspension flows","internal_url":"https://www.academia.edu/25967819/Experimental_thermomechanic_study_of_Newtonian_and_non_Newtonian_suspension_flows","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[{"id":46318366,"title":"","file_type":"pdf","scribd_thumbnail_url":"https://attachments.academia-assets.com/46318366/thumbnails/1.jpg","file_name":"Experimental_thermomechanic_study_of_New20160607-18717-fhji87.pdf","download_url":"https://www.academia.edu/attachments/46318366/download_file","bulk_download_file_name":"Experimental_thermomechanic_study_of_New.pdf","bulk_download_url":"https://d1wqtxts1xzle7.cloudfront.net/46318366/Experimental_thermomechanic_study_of_New20160607-18717-fhji87-libre.pdf?1465328353=\u0026response-content-disposition=attachment%3B+filename%3DExperimental_thermomechanic_study_of_New.pdf\u0026Expires=1739817798\u0026Signature=Vg3KTWhrbXTkwGUMd1~iDruJpVjc6muHXq3BtBUmPGfhV7Ga3LWGlTfyuo9H8AshTA3HI-wwP6ijnLZg5vY0SgOPZz9~wzKdIQcVsgzwe8glb9uv4z~9l5UIV9nSQTfJ79GeeyDL9rQoJV~TCvTw~g0WDN07dwjk-sbsc6gHHuhCi9kfqko2srbNOafijoGMoMTA5NjntQOD6n9jqQObiQzPl-yaK1ARlf0mUrhtg41gRNT3yx03j50GryRUW6koeHxpvQCLE0ECxE7Xgzsqs~Nc8jnHxCnf8qKLv8aqlka4AA5~Oe8AiplNxyh00SH3-nIFok-TY9DkFebdnK6fWA__\u0026Key-Pair-Id=APKAJLOHF5GGSLRBV4ZA"}]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967818"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967818/Mass_transfer_properties_in_a_grid_generated_turbulent_flow_some_experimental_investigations_about_the_concept_of_turbulent_diffusivity"><img alt="Research paper thumbnail of Mass transfer properties in a grid generated turbulent flow: some experimental investigations about the concept of turbulent diffusivity" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967818/Mass_transfer_properties_in_a_grid_generated_turbulent_flow_some_experimental_investigations_about_the_concept_of_turbulent_diffusivity">Mass transfer properties in a grid generated turbulent flow: some experimental investigations about the concept of turbulent diffusivity</a></div><div class="wp-workCard_item"><span>International Journal of Heat and Mass Transfer</span><span>, 1998</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">ABSTRACT</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967818"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967818"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967818; 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dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967818]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967818,"title":"Mass transfer properties in a grid generated turbulent flow: some experimental investigations about the concept of turbulent diffusivity","internal_url":"https://www.academia.edu/25967818/Mass_transfer_properties_in_a_grid_generated_turbulent_flow_some_experimental_investigations_about_the_concept_of_turbulent_diffusivity","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967817"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967817/Ecoulement_de_fluides_non_newtoniens_a_travers_des_elargissements_brusques"><img alt="Research paper thumbnail of Ecoulement de fluides non newtoniens a travers des elargissements brusques" class="work-thumbnail" src="https://attachments.academia-assets.com/46318353/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967817/Ecoulement_de_fluides_non_newtoniens_a_travers_des_elargissements_brusques">Ecoulement de fluides non newtoniens a travers des elargissements brusques</a></div><div class="wp-workCard_item"><span>International Communications in Heat and Mass Transfer</span><span>, 1997</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">The present paper is concerned with non newtonian pseudoplastic fluid flow across an abrupt enlar...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">The present paper is concerned with non newtonian pseudoplastic fluid flow across an abrupt enlargement. Basic equations are integrated by a finite volume scheme. The obtained results clearly display the stabilizing effect of fluid pseudoplasticity. The recirculation zone and re-etablishment length diminish when behaviour index decreases. It is noticed that there is an agreement between the numerical results and the results of experimental study carried out in our laboratory. 漏 1997 Elsevier Science Ltd RESUME La pr6sente 6tude concerne l'6coulement de fluides non newtoniens pseudoplastiques h travers des 61argissements brusques. Les calculs sont effectu6s par un code aux volumes finis. L'effet stabilisant du caract~re rh6ofluidifiant du fluide est mis en 6vidence. La zone de recirculation et la longueur d'6tablissement diminuent quand l'indice de structure d6crott. I1 y a un bon accord entre nos r6sultats num6riques et les r6sultats des 6tudes exp6rimentales r6alis6es dans notre laboratoire.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="304c4b6c0b1fd771cff7f02030566705" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318353,"asset_id":25967817,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318353/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967817"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967817"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967817; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967815"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967815/Experimental_investigation_of_mass_transfer_in_high_viscosity_media"><img alt="Research paper thumbnail of Experimental investigation of mass transfer in high viscosity media" class="work-thumbnail" src="https://attachments.academia-assets.com/46318355/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967815/Experimental_investigation_of_mass_transfer_in_high_viscosity_media">Experimental investigation of mass transfer in high viscosity media</a></div><div class="wp-workCard_item"><span>International Communications in Heat and Mass Transfer</span><span>, 2003</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="652b56d38bb298dc64de7c911a364cde" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318355,"asset_id":25967815,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318355/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967815"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967815"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967815; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967815]").text(description); $(".js-view-count[data-work-id=25967815]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967815; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967815']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (true){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "652b56d38bb298dc64de7c911a364cde" } } $('.js-work-strip[data-work-id=25967815]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967815,"title":"Experimental investigation of mass transfer in high viscosity media","internal_url":"https://www.academia.edu/25967815/Experimental_investigation_of_mass_transfer_in_high_viscosity_media","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[{"id":46318355,"title":"","file_type":"pdf","scribd_thumbnail_url":"https://attachments.academia-assets.com/46318355/thumbnails/1.jpg","file_name":"s0735-1933_2803_2900129-520160607-31781-18emjy4.pdf","download_url":"https://www.academia.edu/attachments/46318355/download_file","bulk_download_file_name":"Experimental_investigation_of_mass_trans.pdf","bulk_download_url":"https://d1wqtxts1xzle7.cloudfront.net/46318355/s0735-1933_2803_2900129-520160607-31781-18emjy4-libre.pdf?1465328353=\u0026response-content-disposition=attachment%3B+filename%3DExperimental_investigation_of_mass_trans.pdf\u0026Expires=1739817798\u0026Signature=JNnhgypIlrM7v6UJKUAG3n3mK9TTCF0uex2qjpbM~4d5NWFMzIGNn3YGFpu8acvNwONKJV9cSh98qRb9bZKmozI91fQZ~ji2E7rxUarEY~G4paRUNYloc6874u2T6jl66O63kRIFnIk7IQ~7muFZAvnvmJ8nkii-9OSC8iQUaNKOrXuPTp8oHTLuIHv-JFqZe29cAMFHfgQtubh1QZ73n1okxP4vup6P6gsAO3xEK89sKarBuNMufyUdl7Hp9ZMPba52VtoawhMlUzv2biGM8BpA4NWBUL3O~6IWy5gT3Ryw6x7qrbDky6CmaATHlgCsJeApzSsicGvGS3qgpyFA9w__\u0026Key-Pair-Id=APKAJLOHF5GGSLRBV4ZA"}]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967814"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967814/Local_heat_transfer_from_a_hot_plate_to_a_water_jet"><img alt="Research paper thumbnail of Local heat transfer from a hot plate to a water jet" class="work-thumbnail" src="https://attachments.academia-assets.com/46318356/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967814/Local_heat_transfer_from_a_hot_plate_to_a_water_jet">Local heat transfer from a hot plate to a water jet</a></div><div class="wp-workCard_item"><span>Heat and Mass Transfer</span><span>, 2003</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Jet impingement boiling is very efficient in cooling of hot surfaces as a part of the impinging l...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Jet impingement boiling is very efficient in cooling of hot surfaces as a part of the impinging liquid evaporates. Because of its importance to many cooling procedures, investigations on basic mechanisms of jet impingement boiling heat transfer are needed. Until now, most of the experimental studies, carried out under steady-state conditions, used a heat flux controlled system and were limited by the critical heat flux (CHF). The present study focuses on steady-state experiments along the entire boiling curve for hot plate temperatures of up to 700掳C. A test section has been built up simulating a hot plate. It is divided into 8 independently heated modules of 10 mm length to enable local heat transfer measurements. By means of temperature controlled systems for each module local steady-state experiments in the whole range between single phase heat transfer and film boiling are possible. By solving the two dimensional inverse heat conduction problem, the local heat flux and the corresponding wall temperature on the surface of each module can be computed. The measurements show important differences between boiling curves measured at the stagnation line and those obtained in the parallel flow region. At the stagnation line, the transition boiling regime is characterised by very high heat fluxes, extended to large wall superheats. Inversely, boiling curves in the parallel flow region are very near to classical ones obtained for forced convection boiling. The analysis of temperature fluctuations measured at a depth of 0.8 mm from the boiling surface enables some conclusions on the boiling mechanism in the different boiling regimes.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="ba1c95e9633df118a43390c337654a8c" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318356,"asset_id":25967814,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318356/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967814"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967814"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967814; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967813"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967813/Non_intrusive_temperature_measurements_using_three_color_laser_induced_fluorescence"><img alt="Research paper thumbnail of Non-intrusive temperature measurements using three-color laser-induced fluorescence" class="work-thumbnail" src="https://attachments.academia-assets.com/46318357/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967813/Non_intrusive_temperature_measurements_using_three_color_laser_induced_fluorescence">Non-intrusive temperature measurements using three-color laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2004</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper presents a new temperature measurement technique in a liquid, based on laser-induced f...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper presents a new temperature measurement technique in a liquid, based on laser-induced fluorescence of rhodamine B. The fluorescence intensity is detected on three spectral bands, where the ratios between the emission of each band determine the temperature while correcting for the effects of fluorescent re-absorption. In addition, the influence of parameters such as probe volume size, dye concentration, and Beer's absorption is removed. The principles of the technique are described in this paper, and the technique is demonstrated on a heated liquid jet studied under a constant and a spatially variable dye concentration.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="7625e49d78f1a6ded15019c718d7ebb9" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318357,"asset_id":25967813,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318357/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967813"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967813"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967813; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967812"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967812/Measurement_of_the_temperature_distribution_within_monodisperse_combusting_droplets_in_linear_streams_using_two_color_laser_induced_fluorescence"><img alt="Research paper thumbnail of Measurement of the temperature distribution within monodisperse combusting droplets in linear streams using two-color laser-induced fluorescence" class="work-thumbnail" src="https://attachments.academia-assets.com/46318358/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967812/Measurement_of_the_temperature_distribution_within_monodisperse_combusting_droplets_in_linear_streams_using_two_color_laser_induced_fluorescence">Measurement of the temperature distribution within monodisperse combusting droplets in linear streams using two-color laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2003</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Two-color laser-induced fluorescence can be use to perform space-averaged flying droplet temperat...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Two-color laser-induced fluorescence can be use to perform space-averaged flying droplet temperature measurements. In this paper, the possibility to extend this technique to the measurement of the temperature distribution within a moving combusting droplet is considered and demonstrated. This technique may provide new experimental data related to the heat diffusion in liquid fuel droplets injected in high-temperature gas streams, for example, in combustion chambers. The main principles of the technique and the data reduction process are discussed, and a test on combusting a monodisperse ethanol droplets (200 lm in diameter) stream is presented.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="2fa0e58efe91528d1a9730310ab049b9" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318358,"asset_id":25967812,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318358/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967812"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967812"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967812; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967810"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967810/Temperature_measurements_on_droplets_in_monodisperse_stream_using_laser_induced_fluorescence"><img alt="Research paper thumbnail of Temperature measurements on droplets in monodisperse stream using laser-induced fluorescence" class="work-thumbnail" src="https://attachments.academia-assets.com/46318354/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967810/Temperature_measurements_on_droplets_in_monodisperse_stream_using_laser_induced_fluorescence">Temperature measurements on droplets in monodisperse stream using laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2000</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper presents a novel technique based on laser-induced炉uorescence in liquids, allowing the ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper presents a novel technique based on laser-induced炉uorescence in liquids, allowing the temperature of 200-lm diameter monodisperse droplets to be measured. The droplets are seeded with an organic dye (rhodamine B), and the temperature dependence of th膿</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="79a959a38d93a297b0cf860339033899" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318354,"asset_id":25967810,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318354/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967810"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967810"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967810; 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$(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967808"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967808/Evaporating_and_combusting_droplet_temperature_measurements_using_two_color_laser_induced_fluorescence"><img alt="Research paper thumbnail of Evaporating and combusting droplet temperature measurements using two-color laser-induced fluorescence" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967808/Evaporating_and_combusting_droplet_temperature_measurements_using_two_color_laser_induced_fluorescence">Evaporating and combusting droplet temperature measurements using two-color laser-induced fluorescence</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2001</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">ABSTRACT 鈥俆he paper presents a new technique based on laser-induced fluorescence, allowing drople...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">ABSTRACT 鈥俆he paper presents a new technique based on laser-induced fluorescence, allowing droplet temperature measurement of evaporating and combusting droplets to be performed. The liquid spray is seeded with a low concentration of rhodamine B. The fluorescence, induced by the green line of an argon laser, is measured on two separated color bands. It is demonstrated that two color bands can be selected for their strong difference in the temperature sensitivity of the fluorescence quantum yield. The determination of the fluorescence ratio between the fluorescence intensity corresponding to each color band allows the tracer concentration and the droplet size dependences to be eliminated. The technique was applied on a monodisperse spray: the effect of a thermal impulse on the distribution of the droplet temperature is studied and, the temperature of combusting droplets is investigated.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967808"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967808"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967808; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967808]").text(description); $(".js-view-count[data-work-id=25967808]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967808; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967808']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967808]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967808,"title":"Evaporating and combusting droplet temperature measurements using two-color laser-induced fluorescence","internal_url":"https://www.academia.edu/25967808/Evaporating_and_combusting_droplet_temperature_measurements_using_two_color_laser_induced_fluorescence","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967806"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967806/Development_of_a_thixotropic_fluid_flow_in_a_pipe"><img alt="Research paper thumbnail of Development of a thixotropic fluid flow in a pipe" class="work-thumbnail" src="https://attachments.academia-assets.com/46318352/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967806/Development_of_a_thixotropic_fluid_flow_in_a_pipe">Development of a thixotropic fluid flow in a pipe</a></div><div class="wp-workCard_item wp-workCard--coauthors"><span>by </span><span><a class="" data-click-track="profile-work-strip-authors" href="https://independent.academia.edu/RDevienne">R. Devienne</a> and <a class="" data-click-track="profile-work-strip-authors" href="https://independent.academia.edu/MichelLebouche">Michel Lebouche</a></span></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 2001</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper deals with the interaction between the modi庐cations of the internal structure of a thi...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper deals with the interaction between the modi庐cations of the internal structure of a thixotropic uid and the炉ow development along a pipe. The experi-</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="a8b432ec7afda22cb615344c9f7563b6" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318352,"asset_id":25967806,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318352/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967806"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967806"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967806; 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This assumption is verified in gases, at pressure higher than a few 103 ... correlations, between the axial and radial velocity and the temperature fluctuations are reported ...</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967804"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967804"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967804; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); 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</script> <div class="js-work-strip profile--work_container" data-work-id="25967803"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967803/Wall_shear_measurements_inside_corrugated_channels_using_the_electrochemical_technique"><img alt="Research paper thumbnail of Wall shear measurements inside corrugated channels using the electrochemical technique" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967803/Wall_shear_measurements_inside_corrugated_channels_using_the_electrochemical_technique">Wall shear measurements inside corrugated channels using the electrochemical technique</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 1998</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">We report on an investigation of adiabatic single-phase flow inside two-dimensional and three-dim...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">We report on an investigation of adiabatic single-phase flow inside two-dimensional and three-dimensional channels, with a hydraulic diameter of 0.033鈥卪. This work is a preliminary study to another one that will be carried out with a gas鈥搇iquid mixture. The flow structure is studied using the electrochemical technique. Circular single probes and rectangular sandwich probes are inserted flush to the wall.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967803"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967803"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967803; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967803]").text(description); 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dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967803]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967803,"title":"Wall shear measurements inside corrugated channels using the electrochemical technique","internal_url":"https://www.academia.edu/25967803/Wall_shear_measurements_inside_corrugated_channels_using_the_electrochemical_technique","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967802"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967802/Simultaneous_concentration_and_velocity_measurements_using_combined_laser_induced_fluorescence_and_laser_Doppler_velocimetry_Application_to_turbulent_transport"><img alt="Research paper thumbnail of Simultaneous concentration and velocity measurements using combined laser-induced fluorescence and laser Doppler velocimetry: Application to turbulent transport" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967802/Simultaneous_concentration_and_velocity_measurements_using_combined_laser_induced_fluorescence_and_laser_Doppler_velocimetry_Application_to_turbulent_transport">Simultaneous concentration and velocity measurements using combined laser-induced fluorescence and laser Doppler velocimetry: Application to turbulent transport</a></div><div class="wp-workCard_item"><span>Experiments in Fluids</span><span>, 1996</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">This paper describes the implementation of an optical technique, allowing to perform concentratio...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">This paper describes the implementation of an optical technique, allowing to perform concentration and velocity measurements simultaneously and at the same point. This method is based on the coupling of laser-induced fluorescence of rhodamine B, applied to the determination of local concentration, and laser Doppler velocimetry. The method developed provides an accurate measurement of the concentration-velocity cross-correlation. The latter is</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967802"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967802"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967802; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967802]").text(description); $(".js-view-count[data-work-id=25967802]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967802; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967802']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967802]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967802,"title":"Simultaneous concentration and velocity measurements using combined laser-induced fluorescence and laser Doppler velocimetry: Application to turbulent transport","internal_url":"https://www.academia.edu/25967802/Simultaneous_concentration_and_velocity_measurements_using_combined_laser_induced_fluorescence_and_laser_Doppler_velocimetry_Application_to_turbulent_transport","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967801"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" rel="nofollow" href="https://www.academia.edu/25967801/Controlled_cooling_of_a_hot_plate_with_a_water_jet"><img alt="Research paper thumbnail of Controlled cooling of a hot plate with a water jet" class="work-thumbnail" src="https://a.academia-assets.com/images/blank-paper.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" rel="nofollow" href="https://www.academia.edu/25967801/Controlled_cooling_of_a_hot_plate_with_a_water_jet">Controlled cooling of a hot plate with a water jet</a></div><div class="wp-workCard_item"><span>Experimental Thermal and Fluid Science</span><span>, 2002</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">Experiments are performed, under steady-state conditions, to study the boiling heat transfer from...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">Experiments are performed, under steady-state conditions, to study the boiling heat transfer from a hot plate to a planar jet of water. Temperature control of the heating surface enables the determination of entire boiling curves and the identification of each boiling regime from ...</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967801"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967801"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967801; window.Academia.workViewCountsFetcher.queue(workId, function (count) { var description = window.$h.commaizeInt(count) + " " + window.$h.pluralize(count, 'View'); $(".js-view-count[data-work-id=25967801]").text(description); $(".js-view-count[data-work-id=25967801]").attr('title', description).tooltip(); }); });</script></span></span><span><span class="percentile-widget hidden"><span class="u-mr2x work-percentile"></span></span><script>$(function () { var workId = 25967801; window.Academia.workPercentilesFetcher.queue(workId, function (percentileText) { var container = $(".js-work-strip[data-work-id='25967801']"); container.find('.work-percentile').text(percentileText.charAt(0).toUpperCase() + percentileText.slice(1)); container.find('.percentile-widget').show(); container.find('.percentile-widget').removeClass('hidden'); }); });</script></span></div><div id="work-strip-premium-row-container"></div></div></div><script> require.config({ waitSeconds: 90 })(["https://a.academia-assets.com/assets/wow_profile-a9bf3a2bc8c89fa2a77156577594264ee8a0f214d74241bc0fcd3f69f8d107ac.js","https://a.academia-assets.com/assets/work_edit-ad038b8c047c1a8d4fa01b402d530ff93c45fee2137a149a4a5398bc8ad67560.js"], function() { // from javascript_helper.rb var dispatcherData = {} if (false){ window.WowProfile.dispatcher = window.WowProfile.dispatcher || _.clone(Backbone.Events); dispatcherData = { dispatcher: window.WowProfile.dispatcher, downloadLinkId: "-1" } } $('.js-work-strip[data-work-id=25967801]').each(function() { if (!$(this).data('initialized')) { new WowProfile.WorkStripView({ el: this, workJSON: {"id":25967801,"title":"Controlled cooling of a hot plate with a water jet","internal_url":"https://www.academia.edu/25967801/Controlled_cooling_of_a_hot_plate_with_a_water_jet","owner_id":49773627,"coauthors_can_edit":true,"owner":{"id":49773627,"first_name":"Michel","middle_initials":null,"last_name":"Lebouche","page_name":"MichelLebouche","domain_name":"independent","created_at":"2016-06-07T12:33:33.450-07:00","display_name":"Michel Lebouche","url":"https://independent.academia.edu/MichelLebouche"},"attachments":[]}, dispatcherData: dispatcherData }); $(this).data('initialized', true); } }); $a.trackClickSource(".js-work-strip-work-link", "profile_work_strip") }); </script> <div class="js-work-strip profile--work_container" data-work-id="25967800"><div class="profile--work_thumbnail hidden-xs"><a class="js-work-strip-work-link" data-click-track="profile-work-strip-thumbnail" href="https://www.academia.edu/25967800/Heat_transfer_associated_to_a_hot_surface_quenched_by_a_jet_of_oil_in_water_emulsion"><img alt="Research paper thumbnail of Heat transfer associated to a hot surface quenched by a jet of oil-in-water emulsion" class="work-thumbnail" src="https://attachments.academia-assets.com/46318370/thumbnails/1.jpg" /></a></div><div class="wp-workCard wp-workCard_itemContainer"><div class="wp-workCard_item wp-workCard--title"><a class="js-work-strip-work-link text-gray-darker" data-click-track="profile-work-strip-title" href="https://www.academia.edu/25967800/Heat_transfer_associated_to_a_hot_surface_quenched_by_a_jet_of_oil_in_water_emulsion">Heat transfer associated to a hot surface quenched by a jet of oil-in-water emulsion</a></div><div class="wp-workCard_item"><span>Experimental Thermal and Fluid Science</span><span>, 2011</span></div><div class="wp-workCard_item"><span class="js-work-more-abstract-truncated">In hot rolling, the mechanical properties of steel alloys are conditioned by the rolling process ...</span><a class="js-work-more-abstract" data-broccoli-component="work_strip.more_abstract" data-click-track="profile-work-strip-more-abstract" href="javascript:;"><span> more </span><span><i class="fa fa-caret-down"></i></span></a><span class="js-work-more-abstract-untruncated hidden">In hot rolling, the mechanical properties of steel alloys are conditioned by the rolling process but a great part is ensured by the cooling of the hot strip mill. Well controlling this cooling rate and its homogeneity is thus of primary importance for obtaining steels with desired mechanical properties. As the water used in the cooling stage of the rolling process can be polluted by oil (in hot mill strip, some oil is used to lubricate the rolls and a part of it can pollute the water), it is important to know how much varies the cooling rates when water is polluted. In this study, transient cooling has been investigated during quenching of a hot metal disk with various subcooled oil-in-water emulsion jets. The aim of this work is to compare the cooling efficiency of oil-in-water emulsion jet with a pure water jet. Experimental investigations of axisymmetric jet impingements on a preheated hot metal disk (500-600掳C) have been performed with various oil-in-water emulsions. The transient cooling heat fluxes on the quenched side are estimated by coupling the measurement of the temperature field of the other side (rear face) with a semi-analytical inverse heat conduction model.</span></div><div class="wp-workCard_item wp-workCard--actions"><span class="work-strip-bookmark-button-container"></span><a id="fab48855073a5f666025cbf032ec9647" class="wp-workCard--action" rel="nofollow" data-click-track="profile-work-strip-download" data-download="{"attachment_id":46318370,"asset_id":25967800,"asset_type":"Work","button_location":"profile"}" href="https://www.academia.edu/attachments/46318370/download_file?s=profile"><span><i class="fa fa-arrow-down"></i></span><span>Download</span></a><span class="wp-workCard--action visible-if-viewed-by-owner inline-block" style="display: none;"><span class="js-profile-work-strip-edit-button-wrapper profile-work-strip-edit-button-wrapper" data-work-id="25967800"><a class="js-profile-work-strip-edit-button" tabindex="0"><span><i class="fa fa-pencil"></i></span><span>Edit</span></a></span></span></div><div class="wp-workCard_item wp-workCard--stats"><span><span><span class="js-view-count view-count u-mr2x" data-work-id="25967800"><i class="fa fa-spinner fa-spin"></i></span><script>$(function () { var workId = 25967800; 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