[en] ANALYSIS OF THE EFFECT OF DROPLET SIZE DISTRIBUTION ON THE STABILITY OF WATER-INOIL EMULSIONS / [pt] ANÁLISE DO EFEITO DA DISTRIBUIÇÃO DO TAMANHO DE GOTAS NA ESTABILIDADE DE EMULSÕES ÁGUA EM ÓLEO

CAROLINE OLIVEIRA PAES DE BARROS

28 September 2021

[pt] Com as novas regulamentações ambientais proibindo o uso de fluidos de perfuração que apresentassem em sua composição elementos como óleo diesel, se fez necessário a busca por novos componentes que, além de serem eficazes em sua função, apresentassem característica de biodegradabilidade sendo, assim, menos danoso ao meio ambiente. A base do fluido de perfuração escolhida para se enquadrar as novas regras foi estudada neste trabalho com objetivo de avaliar a sua estabilidade e o seu comportamento reológico. O fluido trabalhado é uma emulsão inversa cuja fase contínua é a olefina e a fase dispersa, salmoura de NaCl, acrescido de um emulsificante primário, Cybermul, e um secundário, Cyberplus. Para retardar o processo de desestabilização, majoritariamente caracterizado pela sedimentação, em um segundo momento, foi adicionada a cal hidratada. Os testes realizados foram divididos em duas etapas: a primeira avaliando emulsões preparadas a 5000 rpm, 7500 rpm e 10000 rpm sem cal em sua composição e a segunda avaliando emulsões preparadas com a mesma velocidade de rotação, entretanto com cal hidratada. A principal variável adotada foi a velocidade de rotação com objetivo de ratificar o conhecimento de que quanto maior a velocidade de agitação durante a emulsificação, menores são as gotas geradas e, consequentemente, mais estável a emulsão. Os testes foram compostos por tensão interfacial, bottle test, distribuição do tamanho de gotas (microscopia e espalhamento dinâmico de luz) e testes de comportamento reológico, que incluem, tensão constante, curva de escoamento e varredura de tensão e tempo. Os resultados obtidos permitiram relacionar o tamanho das gotas geradas com a estabilidade da emulsão e com a sua viscosidade. / [en] Since new environmental regulations were established prohibiting the use of drilling fluids that had elements such as diesel in their composition, it was necessary to search for new components that, besides being effective in their function, had a biodegradability characteristic, thus being less harmful to the environment. The base of the drilling fluid chosen to fit the new rules was studied in this thesis in order to characterize its stability and rheological behavior. The fluid used is an inverse emulsion whose continuous phase is the olefin and the dispersed phase, brine, plus a primary emulsifier, Cybermul, and a secondary one, Cyberplus. To delay the destabilization process, mainly characterized by sedimentation, in a second moment, hydrated lime was added to the emulsion s composition. The tests performed were divided into two stages: the first, emulsions prepared at 5000 rpm, 7500 rpm and 10,000 rpm without lime in their composition were analyzed and the second, emulsions prepared at the same rotation velocities however with hydrated lime in their composition. The main variable adopted was the speed of rotation in order to confirm the knowledge that the higher is the speed of agitation during emulsification, the smaller are the drops generated and, consequently, the more stable is the emulsion. The tests consisted of interfacial tension, bottle test, droplet size distribution (microscopy and dynamic light scattering) and rheological behavior tests, which include, creep tests, flow curve and stress and time sweep tests. The results obtained allowed to relate the size of the drops with the emulsion s stability and with its viscosity.

[pt] ESTABILIDADE

[pt] BOTTLE TEST

[pt] DISTRIBUICAO DO TAMANHO DE GOTAS

[pt] EMULSAO

[pt] MICROSCOPIA

[en] STABILITY

[en] BOTTLE TEST

[en] DROPLET SIZE DISTRIBUTION

[en] EMULSION

[en] MICROSCOPY

Evolution of Droplet Distributions in Hydrodynamic Systems / Entwicklung von Tropfenverteilungen in hydrodynamischen Systemen

Lapp, Tobias

25 November 2011

No description available.

530 Physik

Physics

Größenverteilung

Phasen Separation

Binäre Fluids

Atemniederschlagsmuster

Bildverarbeitung

Tropfenerkennung

Teilchenverfolgung

droplet size distribution

phase separation

binary fluids

breath figures

image processing

droplet detection

particle tracking

33.00

RDE 000: Experimentalphysik

The Characterization of Bimodal Droplet Size Distributions in the Ultrafiltration of Highly Concentrated Emulsions Applied to the Production of Biodiesel

Falahati, Hamid

26 August 2010

A non-reactive model system comprising a highly concentrated and unstable oil-in-water emulsion was used to investigate the retention of oil by the membrane in producing biodiesel with a membrane reactor. Critical flux was identified using the relationship between the permeate flux and transmembrane pressure along with the separation efficiency of the membrane. It was shown that separation efficiencies above 99.5% could be obtained at all operating conditions up to the critical flux. It was observed that the concentration of oil in all collected permeate samples using the oil-water system was below 0.2 wt% when operating at a flux below the critical flux. Studies to date have been limited to the characterization of low concentrated emulsions below 15 vol.%. The average oil droplet size in highly concentrated emulsions was measured as 3200 nm employing direct light scattering (DLS) measurement methods. It was observed that the estimated cake layer thickness of 20 to 80 mm was larger than external diameter of the membrane tube i.e. 6 mm based on a large particle size. Settling of the concentrated emulsion permitted the detection of a smaller particle size distribution (30-100 nm) within the larger particles averaging 3200 nm. It was identified that DLS methods could not efficiently give the droplet size distribution of the oil in the emulsion since large particles interfered with the detection of smaller particles. The content of the smaller particles represented 1% of the total weight of oil at 30°C and 5% at 70°C. This was too low to be detected using DLS measurements but was sufficient to affect ultrafiltration. In order to study the critical flux in the presence of transesterification reaction and the effect of cross flow velocity on separation, various oils were transesterified in another membrane reactor providing higher cross flow velocity. higher cross flow velocity provides better separation by reducing materials deposition on the surface of the membrane due to higher shearing. The oils tested were canola, corn, sunflower and unrefined soy oils (Free Fatty Acids (FFA< 1%)), and waste cooking oil (FFA= 9%). The quality of all biodiesel samples was studied in terms of glycerine, mono-glyceride, di-glyceride and tri-glyceride concentrations. The composition of all biodiesel samples were in the range required by ASTM D6751 and EN 14214 standards. A critical flux based on operating pressure in the reactor was reached for waste cooking and pre-treated corn oils. It was identified that the reaction residence time in the reactor was an extremely important design parameter affecting the operating pressure in the reactor. / Natural Sciences and Engineering Research Council of Canada (NSERC)

Ultrafiltration

Oil-in-water emulsion

Membrane reactor

Biodiesel

Critical flux

Bimodal droplet size distribution

Process integration

Ceramic membrane

Alkali-transesterification

Fatty acid methyl ester

Dynamic light scattering

Cross flow velocity

Concentration polarization

Cake layer formation

Cross flow filtration

Emulsions

Biofuel

Process intensification

The Characterization of Bimodal Droplet Size Distributions in the Ultrafiltration of Highly Concentrated Emulsions Applied to the Production of Biodiesel

Falahati, Hamid

26 August 2010

A non-reactive model system comprising a highly concentrated and unstable oil-in-water emulsion was used to investigate the retention of oil by the membrane in producing biodiesel with a membrane reactor. Critical flux was identified using the relationship between the permeate flux and transmembrane pressure along with the separation efficiency of the membrane. It was shown that separation efficiencies above 99.5% could be obtained at all operating conditions up to the critical flux. It was observed that the concentration of oil in all collected permeate samples using the oil-water system was below 0.2 wt% when operating at a flux below the critical flux. Studies to date have been limited to the characterization of low concentrated emulsions below 15 vol.%. The average oil droplet size in highly concentrated emulsions was measured as 3200 nm employing direct light scattering (DLS) measurement methods. It was observed that the estimated cake layer thickness of 20 to 80 mm was larger than external diameter of the membrane tube i.e. 6 mm based on a large particle size. Settling of the concentrated emulsion permitted the detection of a smaller particle size distribution (30-100 nm) within the larger particles averaging 3200 nm. It was identified that DLS methods could not efficiently give the droplet size distribution of the oil in the emulsion since large particles interfered with the detection of smaller particles. The content of the smaller particles represented 1% of the total weight of oil at 30°C and 5% at 70°C. This was too low to be detected using DLS measurements but was sufficient to affect ultrafiltration. In order to study the critical flux in the presence of transesterification reaction and the effect of cross flow velocity on separation, various oils were transesterified in another membrane reactor providing higher cross flow velocity. higher cross flow velocity provides better separation by reducing materials deposition on the surface of the membrane due to higher shearing. The oils tested were canola, corn, sunflower and unrefined soy oils (Free Fatty Acids (FFA< 1%)), and waste cooking oil (FFA= 9%). The quality of all biodiesel samples was studied in terms of glycerine, mono-glyceride, di-glyceride and tri-glyceride concentrations. The composition of all biodiesel samples were in the range required by ASTM D6751 and EN 14214 standards. A critical flux based on operating pressure in the reactor was reached for waste cooking and pre-treated corn oils. It was identified that the reaction residence time in the reactor was an extremely important design parameter affecting the operating pressure in the reactor. / Natural Sciences and Engineering Research Council of Canada (NSERC)

Ultrafiltration

Oil-in-water emulsion

Membrane reactor

Biodiesel

Critical flux

Bimodal droplet size distribution

Process integration

Ceramic membrane

Alkali-transesterification

Fatty acid methyl ester

Dynamic light scattering

Cross flow velocity

Concentration polarization

Cake layer formation

Cross flow filtration

Emulsions

Biofuel

Process intensification

The Characterization of Bimodal Droplet Size Distributions in the Ultrafiltration of Highly Concentrated Emulsions Applied to the Production of Biodiesel

Falahati, Hamid

26 August 2010

A non-reactive model system comprising a highly concentrated and unstable oil-in-water emulsion was used to investigate the retention of oil by the membrane in producing biodiesel with a membrane reactor. Critical flux was identified using the relationship between the permeate flux and transmembrane pressure along with the separation efficiency of the membrane. It was shown that separation efficiencies above 99.5% could be obtained at all operating conditions up to the critical flux. It was observed that the concentration of oil in all collected permeate samples using the oil-water system was below 0.2 wt% when operating at a flux below the critical flux. Studies to date have been limited to the characterization of low concentrated emulsions below 15 vol.%. The average oil droplet size in highly concentrated emulsions was measured as 3200 nm employing direct light scattering (DLS) measurement methods. It was observed that the estimated cake layer thickness of 20 to 80 mm was larger than external diameter of the membrane tube i.e. 6 mm based on a large particle size. Settling of the concentrated emulsion permitted the detection of a smaller particle size distribution (30-100 nm) within the larger particles averaging 3200 nm. It was identified that DLS methods could not efficiently give the droplet size distribution of the oil in the emulsion since large particles interfered with the detection of smaller particles. The content of the smaller particles represented 1% of the total weight of oil at 30°C and 5% at 70°C. This was too low to be detected using DLS measurements but was sufficient to affect ultrafiltration. In order to study the critical flux in the presence of transesterification reaction and the effect of cross flow velocity on separation, various oils were transesterified in another membrane reactor providing higher cross flow velocity. higher cross flow velocity provides better separation by reducing materials deposition on the surface of the membrane due to higher shearing. The oils tested were canola, corn, sunflower and unrefined soy oils (Free Fatty Acids (FFA< 1%)), and waste cooking oil (FFA= 9%). The quality of all biodiesel samples was studied in terms of glycerine, mono-glyceride, di-glyceride and tri-glyceride concentrations. The composition of all biodiesel samples were in the range required by ASTM D6751 and EN 14214 standards. A critical flux based on operating pressure in the reactor was reached for waste cooking and pre-treated corn oils. It was identified that the reaction residence time in the reactor was an extremely important design parameter affecting the operating pressure in the reactor. / Natural Sciences and Engineering Research Council of Canada (NSERC)

Ultrafiltration

Oil-in-water emulsion

Membrane reactor

Biodiesel

Critical flux

Bimodal droplet size distribution

Process integration

Ceramic membrane

Alkali-transesterification

Fatty acid methyl ester

Dynamic light scattering

Cross flow velocity

Concentration polarization

Cake layer formation

Cross flow filtration

Emulsions

Biofuel

Process intensification

The Characterization of Bimodal Droplet Size Distributions in the Ultrafiltration of Highly Concentrated Emulsions Applied to the Production of Biodiesel

Falahati, Hamid

January 2010

A non-reactive model system comprising a highly concentrated and unstable oil-in-water emulsion was used to investigate the retention of oil by the membrane in producing biodiesel with a membrane reactor. Critical flux was identified using the relationship between the permeate flux and transmembrane pressure along with the separation efficiency of the membrane. It was shown that separation efficiencies above 99.5% could be obtained at all operating conditions up to the critical flux. It was observed that the concentration of oil in all collected permeate samples using the oil-water system was below 0.2 wt% when operating at a flux below the critical flux. Studies to date have been limited to the characterization of low concentrated emulsions below 15 vol.%. The average oil droplet size in highly concentrated emulsions was measured as 3200 nm employing direct light scattering (DLS) measurement methods. It was observed that the estimated cake layer thickness of 20 to 80 mm was larger than external diameter of the membrane tube i.e. 6 mm based on a large particle size. Settling of the concentrated emulsion permitted the detection of a smaller particle size distribution (30-100 nm) within the larger particles averaging 3200 nm. It was identified that DLS methods could not efficiently give the droplet size distribution of the oil in the emulsion since large particles interfered with the detection of smaller particles. The content of the smaller particles represented 1% of the total weight of oil at 30°C and 5% at 70°C. This was too low to be detected using DLS measurements but was sufficient to affect ultrafiltration. In order to study the critical flux in the presence of transesterification reaction and the effect of cross flow velocity on separation, various oils were transesterified in another membrane reactor providing higher cross flow velocity. higher cross flow velocity provides better separation by reducing materials deposition on the surface of the membrane due to higher shearing. The oils tested were canola, corn, sunflower and unrefined soy oils (Free Fatty Acids (FFA< 1%)), and waste cooking oil (FFA= 9%). The quality of all biodiesel samples was studied in terms of glycerine, mono-glyceride, di-glyceride and tri-glyceride concentrations. The composition of all biodiesel samples were in the range required by ASTM D6751 and EN 14214 standards. A critical flux based on operating pressure in the reactor was reached for waste cooking and pre-treated corn oils. It was identified that the reaction residence time in the reactor was an extremely important design parameter affecting the operating pressure in the reactor. / Natural Sciences and Engineering Research Council of Canada (NSERC)

Ultrafiltration

Oil-in-water emulsion

Membrane reactor

Biodiesel

Critical flux

Bimodal droplet size distribution

Process integration

Ceramic membrane

Alkali-transesterification

Fatty acid methyl ester

Dynamic light scattering

Cross flow velocity

Concentration polarization

Cake layer formation

Cross flow filtration

Emulsions

Biofuel

Process intensification