Your search keyword '"Yin, Haoran"' showing total 6 results

1. Enhanced mixing of binary droplets induced by capillary pressure.

Author

Luo, Xiaoming, Yin, Haoran, Ren, Jing, Yan, Haipeng, Huang, Xin, Yang, Donghai, and He, Limin

Subjects

*JETS (Fluid dynamics), *EXPANSION of liquids, *INTERFACIAL tension, *MIXING, *REYNOLDS number, *DROPLETS

Abstract

Graphical abstract Abstract The mixing of binary droplets is of paramount importance in microfluidic systems. In order to reveal the mixing mechanism of two free droplets suspended in the immiscible phase, we have developed a novel experimental setup to study the internal mixing in coalescing droplets with varying interfacial tension differences and droplet sizes. It is confirmed that the interfacial energy of droplets supports the jet flow and liquid bridge expansion during the coalescence of droplets. The increase of interfacial tension difference can increase the intensity of jet flow accompanied with slower liquid bridge expansion, which enhances the mixing of droplets. The decrease of droplet size can increase the initial velocity of jet flow. However, the intensity of jet flow decreases due to the rapid expansion of the liquid bridge, which results in weaker internal mixing. On this basis, a Reynolds number incorporating the jet velocity and droplet size is proposed to characterize the vortex size, which represents the degree of droplet mixing. This study presents an effective approach for enhancing the mixing of droplets. [ABSTRACT FROM AUTHOR]

Published

2019

2. Droplets banding characteristics of water-in-oil emulsion under ultrasonic standing waves.

Author

Luo, Xiaoming, Cao, Juhang, Yin, Haoran, He, Limin, and Yan, Haipeng

Subjects

*EMULSIONS, *ULTRASONIC imaging, *INTERFACIAL tension, *DROPLETS, *ELECTROPHORESIS

Abstract

Droplets banding is critical to emulsion separation under ultrasonic irradiation as it can greatly improve the separation efficiency. In this paper, the formation process of droplets banding under ultrasonic standing waves was precisely captured by high-speed microscopic photography; by processing the images, the droplets banding characteristics, including the banding formation time and banding interval, were extracted. Then the effects of acoustic intensity, frequency, droplet size, and physical properties of oil and water on the droplets banding characteristics were discussed in details. The results show that the range of acoustic intensities, within which the droplets banding can form, increases with the increase of the frequency; a maximum allowable acoustic intensity exists for banding formation, which also increases with the frequency. The banding formation time, which increases with increasing oil viscosity but decreases with droplet size, is found to be hardly affected by the oil-water interfacial tension. In addition, the banding interval is only related to the frequency, which closely corresponds to the half wavelength. [ABSTRACT FROM AUTHOR]

Published

2018

3. Deformation and coalescence of water droplets in viscous fluid under a direct current electric field.

Author

Huang, Xin, He, Limin, Luo, Xiaoming, Yin, Haoran, and Yang, Donghai

Subjects

*DIRECT currents, *ELECTRIC fields, *DROPLETS, *FLUID dynamics, *ELECTRORHEOLOGY, *FLUIDS, *INTERFACIAL tension

Abstract

• Droplet response mode depends on electric capillary number and viscosity ratio. • Liquid bridge growth is dominated by interface tension instead of electric stress. • Dimensionless liquid bridge radius is linear with the conical angle. Deformation and coalescence behaviors of water droplets in viscous fluid under a direct current electric field are investigated with experiments and numerical simulations. An electro-hydrodynamic model is developed based on fluid dynamics equations and electrostatic equations. A coupled level set and volume of fluid method is proposed to capture the dynamic interface. The numerical results are validated to be in good accordance with classic results in the literature. The effects of electric capillary number Ca and viscosity ratio λ on droplet deformation and coalescence are systematically analyzed. Two different droplet response modes are obtained, namely overdamping response and underdamping response. The conversion of response modes is discussed with the (Ca, λ) phase diagram. Moreover, the distributions of electric field and flow field before and after the droplets contact are compared and analyzed. Numerical results show the time evolution of liquid bridge is dominated by the interfacial tension and viscosity of continuous phase. The electric stress is extremely weak at the liquid bridge and has a slight influence on evolution of liquid bridge. The correlation formula between dimensionless liquid bridge radius and conical angle during the growth of liquid bridge is regressed. These results are helpful for the optimization of electro-coalescence process. Image, graphical abstract [ABSTRACT FROM AUTHOR]

Published

2019

4. Enhanced separation of water-in-oil emulsions using ultrasonic standing waves.

Author

Luo, Xiaoming, Gong, Haiyang, Cao, Juhang, Yin, Haoran, Yan, Yaipeng, and He, Limin

Subjects

*ULTRASONIC waves, *EMULSIONS, *STANDING waves, *ACOUSTIC streaming, *DEMULSIFICATION, *ACOUSTIC intensity, *INTERFACIAL tension

Abstract

Highlights • Effect of droplet banding on demulsification process is analyzed. • Optimal acoustic intensity and treatment time are obtained. • Acoustic cavitation threshold in emulsions is achieved by spectral analysis. • Range of oil-water properties suitable for ultrasonic separation is determined. Abstract This paper focuses on the application range and optimal parameters for separating water-in-oil (W/O) emulsions using ultrasonic standing waves (USWs). Firstly, the effect of droplet bandings on the demulsification process is theoretically analyzed. The formation of droplet bandings coincides with droplet sedimentation when horizontal irradiation is applied, which improves the separation efficiency. On this basis, the effects of acoustic parameters and oil-water properties on demulsification are analyzed in detail. It is shown that ultrasonic treatment is an efficient demulsification method, and that maximum demulsification efficiency can be achieved by optimizing the acoustic intensity and treatment time. Excessive acoustic intensity causes acoustic cavitation in low-frequency USWs and acoustic streaming in high-frequency USWs, resulting in a low separation efficiency. Acoustic cavitation also causes secondary emulsification, dispersing tiny oil droplets into separated water. In addition, ultrasonic separation is significantly affected by oil-water properties. The demulsification efficiency of W/O emulsions decreases with increasing oil viscosity and decreasing oil-water interfacial tension. Ultrasonic treatment has significant advantages for separation of emulsions with low water content and interfacial tension. This study presents an in-depth analysis of ultrasonic separation. [ABSTRACT FROM AUTHOR]

Published

2019

5. Coalescence characteristics of silica nanoparticle-laden droplets with a planar interface under direct current electric field.

Author

Yang, Donghai, Sun, Yongxiang, He, Limin, Luo, Xiaoming, Lü, Yuling, Yin, Haoran, Xia, Xue, and Zhang, Huihui

Subjects

*COALESCENCE (Chemistry), *SILICA nanoparticles, *DIRECT currents, *ELECTRIC fields, *INTERFACIAL tension

Abstract

Graphical abstract Highlights • Addition of silica nanoparticles affects droplet–interface electrocoalescence. • Reduced interfacial tension, increased water conductivity are responsible for effect. • Effect of field strength is pronounced compared to that of initial droplet size. • Formation of a ring by the separation of vortices is visualized by nanoparticles. • A group (electric We × Oh) is not suitable for coalescence containing nanoparticles. Abstract Electric dehydration method is widely used in oil industry to separate water from oil. Droplets resting on the oil–water interface discharge their liquids into the bulk phase, and the process can be altered by the change of electric field strength (E) or properties of water. Phenomenon of silica (SiO 2) nanoparticle-laden droplets coalescing with a planar interface under direct current electric field was observed using a high-speed digital video camera. The effects of initial droplet diameter (D), E , and weight percent of nanoparticles in deionized water (C) were studied experimentally. The results showed that increasing D or E contributed to the formation of secondary droplets. Addition of SiO 2 nanoparticles to water produced two competing effects: reduction in oil–water interfacial tension and increase in water conductivity, and a shift in the dominant effect occurred with the increase of E. Furthermore, formation of a ring by the separation of vortices was visualized by movement of nanoparticles in experiments, and its downward moving velocity decreased with time, which is small compared to that reported in literature. Finally, it was confirmed that the dimensionless WO number is not suitable for describing the volume fraction of secondary droplets for droplet–interface coalescence containing nanoparticles. [ABSTRACT FROM AUTHOR]

Published

2018

6. Study on separation characteristics of water in oil (W/O) emulsion under ultrasonic standing wave field.

Author

Luo, Xiaoming, Cao, Juhang, Yan, Haipeng, Gong, Haiyang, Yin, Haoran, and He, Limin

Subjects

*OIL-water interfaces, *EMULSIONS, *ULTRASONIC waves, *ACOUSTIC intensity, *INTERFACIAL tension, *ACOUSTIC wave propagation

Abstract

The separation characteristics of W/O emulsion were investigated under ultrasonic standing wave field in this paper. The effects of the irradiation time, acoustic intensity, frequency, oil viscosity, and oil-water interfacial tension on the separation characteristics of emulsion were studied in details. It was proved that there existed an optimal irradiation time, acoustic intensity and oil-water interfacial tension to achieve the maximum separation efficiency in ultrasonic treatment process. Excessive long irradiation time had little effect on improving the dehydration rate of emulsion but rather increased unnecessary processing time. Excessive high acoustic intensity caused the occurrence of acoustic cavitation phenomenon. The acoustic cavitation would cause the aggregated droplets to be dispersed by oscillating bubbles or even emulsified again by high speed micro jets. The acoustic cavitation threshold is effectively and accurately obtained by a spectral analysis method. The micro acoustic streaming which resulted from the attenuation of acoustic energy occurred with the increase of frequency. It sheared the aggregated droplets, destroyed the stable droplets banding and reduced the separation efficiency of emulsion. The excess surfactant adsorbed on the oil-water interface resulted in the increase of the interfacial film strength, which hindered the coalescence process of droplets and reduced the separation efficiency. [ABSTRACT FROM AUTHOR]

Published

2018