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Galina LyutskanovaKiril Mihaylov
Vasil Kolev
Instructor: Tihomir Ivanov
Surface tensionSurface tension is a property of fluids that makes them take a shape that minimizes their surface area.
ExperimentA drop of a given fluid is subjected to rotation or to gravitational forces. Then, a photo of the drop is taken. This is the experimental profile of the drop.
Problem
Software that is used to control the measuring devices finds the value of the surface tension for which the theoretical and experimental profiles coincide.
Drop shape analysis methods
The drop shape analysis are :easy to do;can be used in difficult experimental conditions;require only a small amount of the liquid material;can be used for real-time estimations.
Axisymmetric drop shape analysis (ADSA)
ADSA is a powerful drop shape method. It is fast, easy to handle and produce accurate results. The corner stone of this method is the fact that any given drop is axisymmetric. Using this assumption with the help of the Young-Laplace equation we can efficiently analyze the shape of any given drop.
ADSA is used in various systems such as tensiometers.
Implementation of ADSATwo possible settings are pendant drop and rotating drop. In both the settings we approach the problem in the same way.We create a program that processes the image of the drop that we are going to examine in order to obtain the cloud of points. Then, we acquire differential equations that describe the influence of the interfacial tension and the gravity on the shape of the drop. These equations are dependent on parameters with the help of which we can identify the interfacial tension.
Give approximate discrete solutions of the differential equations using the Euler and RK methods.
By optimizing the error of our approximations we identify the parameters on which our equations depend and find the interfacial tension.
The only difference is in the differential equations but it has no substantial effects on any of the steps.
Steps for Contour Extraction
The Young – Laplace Equation of Capillarity
The model for the pendant drop
Substituting (2) and (3) into (1) and parameterizing the curve with the arc length s, we obtain
z
With initial conditions
b
Euler method Runge-Kutta method
ODE45 – One-step solver, based on a Runge-Kutta methodODE113 – Multistep solver, based on the Adams-Bashforth Methods
big numerical
errors
b = 1 c = [ 0.05 – 2.5]
OptimizationGradient descent Gauss-Newton
Gradient descent Gauss-Newton
Gradient descent Gauss-Newton
Thank you for your attention!