Simulation strategies for improved contamination modeling of liquid dynamics on automotive surfaces

Sugathapala, Thisal Mandula, Bakker, Twan

January 2022

A significant level of research is currently being carried out in the development of driver support systems as they are expected to play a key role in minimizing road vehicle accidents and creating a safe driving environment under harsh weather conditions. However, the performance of some components used by existing driver support systems like LIDAR and visual cameras are affected by extreme weather conditions such as heavy rain fall and snow. Therefore, it is paramount to identify key locations in an automotive vehicle where such systems are least affect by external weather conditions, thereby, improving their overall performance. The field of research that deals with such questions from a simulation perspective is called contamination modeling. At the moment, one of the biggest knowledge gaps in this field is how to consider the effect of different materials on the movement of liquids such as water on different automotive surfaces like glass, plastic, rubber and painted metal. The work presented in this research study has been carried out to investigate and establish the most suitable simulation strategies to match numerical predictions with experimental data for flow of water over different automotive surfaces. Following a comprehensive parametric study of simulation parameters, it was found that the most suitable model that can be tweaked to achieve different flow properties with different surfaces is a dynamic contact angle model. The Blended Kistler model available in STAR-CCM+ required specific values for static, advancing and receding contact angles to optimize a surface for a given material. Therefore, droplet experiments of two droplet sizes were initially carried out for all tested materials at different inclinations and necessary flow parameters were recorded. All experiments were carried out using an approach known as light induced fluorescence imaging where the captured images provided a very convenient method for post processing in computational software. Results from droplet experiments showed that water moved quickest on plastic and slowest on glass. Static contact angle measurements were carried out first on horizontal surfaces. Afterwards, the surface was inclined at 15, 30, 45, 60, and 75 degrees to measure changes in contact angle and velocities. The surfaces for glass and painted metal were directly taken from the door of a Volvo S60 while a separate surface was used for plastic and rubber. These results were then used to create simulation setups for rivulets in STAR-CCM+ with the multiphase modeling approach known as volume of fluid. Rivulet simulations were carried out for all four materials at five different inclinations and the results were compared and validated with experimental data. The results show good correlation between numerical predictions for rivulet movement and experimental data emphasising on the possibility of fine-tuning the surfaces of a simulation setup to represent different material properties.

Volume of Fluid

Contamination modeling

Blended Kistler model

Dynamic contact angle models

Exterior water management

Light-induced fluorescence imaging

Multiphase flows

Surface flows

Computational fluid dynamics

Sensor soiling

Mechanical Engineering

Maskinteknik

Improving Water Droplet Prediction for Vehicle Exterior Water Management: Insights from Experimental and Simulation Studies / Förbättring av Förutsägelse av Vattendroppars Rörelse på Fordonsexteriörer: Insikter från Experiment och Simuleringar

Labbé, Anton, Ahsan, Mahim

January 2023

This thesis focuses on the study of water transportation on vehicle surfaces, which is crucial for ensuring the unobstructed operation of sensors and cameras in autonomous vehicles. The research aims to develop and validate experimental and simulation methods to enhance the understanding of water droplet behaviour and to create accurate models for computational fluid dynamics (CFD) simulations. The primary objective is to investigate the feasibility of simulating water droplets using CFD. The study examines the behaviour of water droplets on a lacquered metal sheet and a glass surface. Physical experiments and CFD simulations are conducted to analyse droplet movement under the influence of gravity and airflow. The findings provide insights into the factors influencing droplet behaviour and validate the accuracy of the simulation models through physical tests. The research also discusses the limitations of the study and the implications for Volvo Cars, aiming to improve their ability to predict water droplet movement on their vehicles. / Denna avhandling fokuserar på studien av vattentransport på fordonssytor, vilket är avgörande för att säkerställa att sensorer och kameror i autonoma fordon kan fungera utan hinder. Forskningen syftar till att utveckla och validera experimentella och simuleringsmetoder för att förbättra förståelsen av vattendroppars beteende och skapa noggranna modeller för simuleringar inom beräkningsfluidmekanik (CFD). Det primära målet är att undersöka möjligheten att simulera vattendroppar med hjälp av CFD och deras påverkan på fordonssytor. Studien undersöker beteendet hos vattendroppar på en lackerad metallplåt och en glasyta med varierande lutningsvinklar. Fysiska experiment och CFD-simuleringar utförs för att analysera dropparnas rörelse under påverkan av tyngdkraft och luftström. Resultaten ger insikter om de faktorer som påverkar dropparnas beteende och validerar modellernas noggrannhet genom fysiska tester. Forskningen diskuterar även studiens begränsningar och dess implikationer för Volvo Cars, med målet att förbättra deras förmåga att förutsäga vattendroppars rörelse på deras fordon, vilket leder till effektivare vindtunneltester och säkrare fordon.

Computational Fluid Dynamics

Volume of Fluid

Kistler Correlation

Water Droplet

Wind Tunnel Measurement

Exterior Water Management.

Beräkningsfluidmekanik

Volume of Fluid

Kistler-korrelation

Vattendroppar

Vind Tunnel Experiment

Exteriört Vattenhantering.

Vehicle Engineering

Farkostteknik