Abstract

BackgroundMany applications require liquids to efficiently wet required surfaces as it denotes better performance. The dynamics of pure and complex liquid is known to influence the spreading properties; however, this influence is less understood and solicits other measuring techniques to elucidate the grey area. In this work, we demonstrate the use of simple yet novel optical methods in the monitoring of liquid spreading of pure diesel and kerosene and their binary (complex) mixtures.MethodsThe optical devices are a table model and portable optical sensors which use a diffractive optical element for filtering the specular reflection from a laser speckle pattern obtained from the liquid spreading on the rough surface-liquid-air system. The surfaces used in this study were metal surface roughness standards and roughened glass surface. The viability of the devices was demonstrated using two liquids, namely diesel oil and kerosene, that have a wide difference in their contact angles. The performance of the devices was further tested using binary mixtures of the diesel oil and kerosene. Based on the scattering properties of the spreading liquids and the surfaces, the time-dependent signal was measured with the optical devices.ResultsIt was observed that the spreading was influenced by the surface roughness. The magnitude of the signal decreased with increased surface roughness indicating less variation in the spreading of the liquid drop with the increased surface roughness. The nature of the detected signal for the kerosene on the surface with roughness values below the wavelength of the device follows the Tanner’s law of drop spreading. However, the diesel spreads at a lower rate. Additionally, the complexity of the internal interaction of the diesel-kerosene binary mixtures leads to a complex spreading mechanism on the solid surfaces allowing us to screen the adulterated liquids from the authentic diesel oil with high reliability.ConclusionWe have introduced two novel optical sensors (table model and portable) for the detection of the changes in liquid drop spreading over rough surfaces. The spreading of the liquid drops over a rough surface causes a local contact angle that experiences hysteresis during the spreading process. The spreading depends on the complexity of the liquid and the magnitude of the surface roughness. The unique configuration of the devices makes the portable sensor suitable for longer duration measurements and for field applications, whilst the table model is best suited for monitoring the first transient moments of liquid spreading and for laboratory applications. Such spreading techniques can also be utilized in the detection of wine and strong alcohol, such as vodka, adulterations with glycol and water, respectively.

Highlights

  • Liquid-surface interaction plays a vital role in many applications, for example, in oil lubrication, printing and coating, hydrodynamic properties of aluminium in the marine environment, and in painting

  • Materials and method We present two optical sensors for studying liquid drop spreading on rough surfaces, namely, the portable sensor (PS) and the table model (TM) (MGM-Devices, Finland) to detect the time-dependent signal (S) from kerosene, diesel oil and their binary mixtures on rough surfaces with different finishing and average surface roughness

  • These optical sensors are useful for the monitoring of dynamic change in the liquid drop spreading which is important in the study of hydrophilic or hydrophobic properties of liquid over rough surfaces

Read more

Summary

Introduction

Liquid-surface interaction plays a vital role in many applications, for example, in oil lubrication, printing and coating, hydrodynamic properties of aluminium in the marine environment, and in painting. Due to this significance, it has received much attention, especially, in surface engineering. The characterization of the liquid-surface interaction resulting in wetting or spreading of the liquid on the solid surface is determined by the measure of the contact angle. This angle is in turn influenced by the cohesive and adhesive forces at play. We demonstrate the use of simple yet novel optical methods in the monitoring of liquid spreading of pure diesel and kerosene and their binary (complex) mixtures

Methods
Results
Conclusion

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.