WO2015107159A1 - Device and method for determining the contact angle of a liquid body with a solid surface - Google Patents

Abstract

The invention relates to a device and a method for determining the contact angle of a liquid body or a body filled with a liquid, consisting of a support (1) and a plane (8) which is connected to the support and which can be tilted in an angular range from 0° to maximally 90°, wherein the plane comprises a rolling surface (9) which is formed in the plane for the liquid body or the body filled with a liquid. Multiple sensors (11, 12) for detecting the roll duration of the body along the rolling path are arranged on the plane (8). According to the invention, the angle of inclination of the plane (8) is adjusted by an angle measuring device (10), whereby a roll angle can be detected at which the body begins to move. The contact angle of the body is ascertained from the roll duration, the rolling path, and the roll angle.

Description

 Apparatus and method for determining the contact angle of a liquid body having a solid surface

Description:

Technical area:

The present invention relates to an apparatus and a method for determining the contact angle between the surface of a liquid or liquid-filled body and the surface of a solid. Furthermore, the invention relates to the use of such a device or method for determining the hydrophobicity of a surface. The invention also relates to the use of such a device or method for the determination, analysis or detection of substances or

Reaction products in a body filled with liquid.

State of the art:

Drops of liquid form on hydrophobic surfaces of a solid

Contact angle, which increases with increasing hydrophobicity of the surface of the solid. The contact angle can be measured with, for example, a contact angle goniometer. The contact angle between liquid and solid thus depends on the interaction between the substances at the contact surface. Hydrophilic

Surfaces result in a low contact angle between liquid and

Solid bodies, while superhydrophobic surfaces lead to large contact angles. The contact angle is dependent on the interaction between the surface of the liquid and the solid, in particular the surface tension of the liquid, the surface energy of the solid and the interfacial energy between liquid and solid. The contact angle provides information about the wettability or hydrophobicity of surfaces. This has, for example, in industrial production, for example in the nano-sealing or vehicle painting, a special

 Importance. A measure of the wetting properties is the free interfacial energy at the interface between a solid and a liquid, at the interface between a liquid and a gas, or at the interface between a liquid and a liquid

Solid is defined as a gas.

The contact angle between a drop of a sample liquid and the surface of a sample body can be determined, for example, via a contact angle measuring device become. Conventional devices include a camera to image the transition area between the drop and the surface of the sample body from the side. At the point where the drop contour touches the surface of the solid, a

Tangent be created, the slope of this tangent provides the contact angle to be determined. For the measurement to be accurate, the camera must be adjusted to the side of the drop if possible.

Such a contact angle measuring device is described, for example, in EP 0 919 801 A1 or WO 2000 070 324 A2. These methods are particularly suitable for determining the wetting ability of liquids on solids, since the

 Wetting properties of the involved material systems, for example during coating or painting, strongly influence the process.

A similar measuring system is also described in DE 38 08 860 A1. The measuring system has a horizontal and parallel to the surface of the sample body aligned

Video camera, which images the transition region between the drop and the surface of the specimen in side view. Based on the drop contour is over a

Calculation method of contact or contact angle determined.

Another device is also described in DE 197 54 765 C1, in which also by means of a camera, the transition region between the droplet and the surface of the sample body is shown in side view, wherein the optical axis of the camera extends at an angle to the surface of the sample body and further wherein a

Deflection device is provided close to the surface of the sample body in the imaging beam path.

Alternative contact angle measuring methods provide, for example, the determination of the surface constellation of an aqueous solution, as described in EP 1 729 109 A1. The contact angle is determined by two cameras, the

Take a side view of a drop. The contact angle is then calculated by applying an ellipse to the contour of the drop and calculating the tangents at the intersections between the ellipse and the baseline. Again, however, an optical camera system for the implementation is necessary. Another way is described in EP 2 093 557 A2. The procedure and the

Device are suitable for determining the contact angle of the

Drop radius of curvature by optical distance measurement. The method becomes Object represented according to the reflection property of the surface of a drop on the drop surface. The position of the object to the optical axis of an optical measuring system and the position of the object to a sample surface are known. The symmetry axis of the drop is located near the optical axis. The measurement includes the distance between the image and the optical axis of the image

 Drop. The contact angle is determined by the radius of curvature, which in turn is determined by the measured distance.

WO 2000 000 814 A1 describes an apparatus for measuring the contact angle between a drop of liquid and the surface of a sample, in which a high-power LED projects light onto the drop. The reflection is then observed via a mono-ocular and the position is determined at which no light is reflected.

WO 2003 073 045 A1 describes an indirect method for measuring the contact angle. The method makes use of the geometric relationship between a known volume of a liquid drop, the contact surface of the liquid drop and the contact angle.

Deäk et al. describe a way to determine the contact angle of nanoparticles. In the method described, the contact angle is determined in situ by the scanning angle reflectometry (SAR) method (A. Deäk, E. Hild, AL Kovacs and Z. Hörvölgyi, Contact angle determination of nanoparticles: film balance and scanning angle reflectometry studies. Physical Chemistry Chemical Physics 2007; 9: 6359-6370). Wu et al. report on an approach to measure the local contact angle of

Liquids on a surface of hydrophobic and hydrophilic patch assemblies employing confocal microscopy and a very low concentration of rhodamine-B. At the selected rhodamine B concentration (2 x 10 ^"7 mol / L) aggregated this (at the interface, whereby the liquid and solid interface, and the hydrophobic and hydrophilic stains (patches) can be distinguished by their respective fluorescence intensities J. Wu, Zhang, X. Wang, S. Li, W. Wen, A Simple Approach for Local Contact Angle Determination on a Heterogeneous Surface, Langmuir 201 1; 27: 5705-5708.) Chibowski and Holysz have investigated whether contact angle determination is Young has been determined using the Washburn equation and found that calculating the contact angle with the Washburn equation does not correlate with the contact angle of a Young's drop with the same liquid on the flat surface of a

Solid corresponds to (E. I. Chibowski and L. Holysz., On the use of Washburn's equation for contact angle determination., Journal of Adhesion Science and Technology 1997, 1: 10, 1289-1301).

Crick and Parkin have developed another visual method for characterizing a superhydrophobic surface based on high-speed camera systems. By jumping an aqueous droplet (8 μΙ_) of a certain height (20 mm) can meet. The number of jumps correlates with the static contact angle of a superhydrophobic surface (Crick and Parkin.) Bouncing drops of water define the hydrophobic character. Zeitschrift der Gesellschaft Deutscher Chemiker, 2012, 60: 8).

However, such camera-based contact angle measuring devices are not suitable for every application, expensive to purchase and complicated in the

Handling. Thus, for an accurate measurement, the camera must be aligned as far as possible to the side of the drop, whereby the optical axis of the camera practically extends over the surface of the preferably horizontally oriented sample body. In addition, a tangent must be adapted to the contour of the drop, which leads to inaccurate results in a manual evaluation.

In addition, devices are known with which it is possible to determine the rolling time of a body on an inclined plane. Such a system is known, for example, in a ski jump, in which sensors along a route make the time recording of the skijumper (see DE 10 2007 0234 41 B4). However, the rolling track is curved there.

In addition, there are also methods for analyzing the drop geometry, for example, to determine the state of keratinous fibers. For this purpose, in DE 10 2010 003 495 A1, a drop of a control liquid is applied to a fiber strand and the geometry of the drop is observed. Preferably, the fiber strand is first positioned horizontally for this purpose. For example, photographs can also be taken for observation. The fiber strand can also be inclined over an angle range between 5 and 70 °. Depending on the type of fiber, the state of the fibers, the size of the droplets and the type of control liquid, the droplet runs or rolls downwards at a certain angle on the inclined fiber strand. From the critical angle of unwinding and the

Unwinding speed or completeness of unwinding can also be done Derive knowledge about the fiber state. However, the contact angle is not determined by this method.

In addition, there are methods and devices for testing surface properties in which a drop of liquid is applied to a surface to be tested.

Subsequently, the surface is pivoted about a horizontal axis and the angle at which the droplet beads off is measured. However, in this method, no time recording, but it is only necessary to check at which angle of attack a beading of the droplet is observed on the surface. This analysis is purely qualitative, for example to check different surfaces. In addition, general methods for determining properties of liquids are also known, as described, for example, in US Pat. No. 5,792,941 B.

Presentation of the invention:

Starting from DE 102 01 234 A1 it is therefore an object of the present invention to determine an alternative, simplified device and method for determining the contact angle between the surface of a liquid or liquid-filled body and the surface of a solid.

This object is achieved by a device having the features of claim 1 and a method having the features of claim 11.

Preferred embodiments can be found in the subclaims again.

The present device allows the determination of the contact angle of a liquid or liquid-filled body by determining the rolling time along a defined rolling distance between the body and the surface of a solid. The contact angle here refers to the angle that the surface of a liquid drop or the surface of a liquid-filled body on the surface of a

Solid forms to this surface. In the case of a reaction capsule would

Contact angle thus describe the interface between the shell of the capsule and the surface of the solid. For example, properties of a liquid or material properties of the surface of the solid along the rolling path can be determined or analyzed via the contact angle. Furthermore, the contact angle provides information about the content of the body filled with liquid. The body is

preferably a hollow body or a capsule with an outer, closed Shell enclosing a lumen, similar to a balloon. The shell of the hollow body may be made, for example, of polymers, preferably selected from the group consisting of water-absorbing poly (meth) acrylates, (meth) acrylic acid copolymers, for example ethylene (meth) acrylic acid copolymers, (meth) acrylic acid ester copolymers, maleic acid Copolymers, for example maleic acid-propylene copolymers, polyurethanes, vinyl acetate copolymers, for example an ethylene-vinyl acetate copolymer or vinyl acetate-butyl acrylate copolymers, styrene copolymers, for example butyl acrylate-styrene copolymers, polycarbonates, polyvinyl alcohols or organic materials such as celluloses. Preferably, the liquid body is a liquid drop of any liquid or a capsule filled with such a liquid. In the case of a hollow body or a capsule is the

Contact angle next to the liquid of course also from the properties of

enclosing, closed envelope dependent. Nevertheless, physical properties of different liquids can be determined with such filled capsules on the rolling behavior, such as the Abperlverhalten.

The solid body is preferably a tiltable plane having a surface on which the liquid or liquid-filled body can roll along the rolling path of a rolling track at a given rolling angle. The contact angle here refers to the interface of the liquid drop or the liquid-filled body and the surface of the solid.

The device consists of a carrier and an associated, in one

Angular range of more than 0 ° to a maximum of 90 °, preferably between 10 ° and 80 °, more preferably between 10 ° and 60 °, inclinable plane with a trained therein

 Rolling path for the liquid or liquid-filled body. Preferably, the rolling track is integrated in the plane and consists of a hydrophobic surface or is coated with such. Preferably, the rolling track with PTFE

(Polytetrafluoroethylene) or other unbranched, linear polymer coated. However, for the examination of material properties, the surface may be coated or provided with any substrate. Depending on the substrate, different properties of the surface or of the liquid arranged thereon can thereby be determined. In a preferred variant, therefore, the rolling properties of the body filled with liquid are determined on rolling tracks with different surfaces. In such an embodiment, the surface of the solid body along the rolling track is interchangeable. As a result, for example, physical properties of Determine the surface, such as the Abperlverhalten or the surface energy.

At an upper end of the plane, a first sensor for detecting the coasting start time is arranged. The roll-off start time does not necessarily have to be the time of the

Start of movement of the liquid drop or filled with liquid body, but it denotes a start time at the beginning of the rolling track to determine the rolling time. The plane is moved to a certain angle of inclination until a rolling of the liquid or liquid-filled body along the rolling track is triggered. The first sensor detects the start time as it passes the moving body.

Along a defined rolling path is at the lower end of the plane another sensor for detecting the Abrollendzeit the body. The rolling distance is therefore defined by the arrangement of the two sensors, i. It starts at the first upper sensor and ends at the second lower sensor. To detect the rolling time of the body along the rolling path, a time detection device is provided between the two sensors. Here, usual timepieces can be used. According to the invention it is now provided that the adjustment of the inclination angle of the plane via an angle measuring device, whereby the rolling angle can be detected, in which the body comes into motion and the first sensor and the second sensor of the plane to determine the rolling time. Preferably, the rolling track comprises a semicircular groove for guiding the

 Liquid drop or liquid-filled body (e.g., a polymer body filled with liquid). Preferably, the groove is coated with a hydrophobic surface, such as PTFE. In aqueous solutions, preferably superhydrophobic surfaces are used.

In a further variant of the invention, the body is a reaction capsule filled with medium. The liquid may be, for example, water or a solvent. The reaction capsule preferably comprises a hydrophobic, preferably a superhydrophobic surface of magnetic particles. Preferably, the reaction capsule comprises a shell of a silane compound, preferably one

Fluoro-silane compound, or a dextran shell. Further, iron oxide nanoparticles are also useful as the reaction capsule. Inside the reaction capsule is a liquid, for example an aqueous solution, which may contain one or more chemical substances.

The method according to the invention is now suitable for determining the presence or the content of a substance in the aqueous solution of the reaction capsule. Depending on the type and concentration of the substance contained in the aqueous solution, the individual rolling times of the reaction capsules differ when passing the sensors. As a result, unknown proportions of a substance in the aqueous solution can be determined. In addition to the detection of substances, the reaction capsules can also be used to determine if a reaction has taken place since the reaction products alter the contents of the reaction capsule and thus also their rolling time on the surface of the plane.

To adjust the inclination angle of the plane, the carrier comprises a guide rod, via which the plane is height-adjustable by means of a motor. Preferably, the motor is a stepper motor or other continuously variable

Driving means. The sensors arranged on the plane are preferably light barriers. As soon as the liquid or liquid-filled body (for example the reaction capsule) passes the first light barrier arranged at the upper end, the rolling start time is detected and thus the time measurement is started. At the

Passing the sensor (photocell) located at the lower end of the plane stops the time measurement. In addition to light barriers, contact sensors can also be used as sensors in the sense of the invention.

In a preferred embodiment, the plane transverse to the rolling track comprises a locking slide, which preferably has a recess for blocking the groove. The gate valve prevents accidental unrolling of the body.

According to the invention, the plane is gradually raised by the drive device until the liquid or liquid-filled body comes into motion and passes the first light barrier. About a control device, the drive device is stopped and the

 Time recording started. When passing the second light barrier, the time measurement is stopped. An angle measuring device indicates the roll-off angle, which also corresponds to the angle of inclination of the plane. The size of the contact angle between the liquid drop and the liquid filled body and the solid (i.e., the surface of the rolling path) depends on the interaction between the substances at the contact surface. The lower this

Interaction, the larger the contact angle. From the determination of

Contact angles, certain properties of the surface of a solid can be determined, for example, the surface energy. According to the invention, the contact angle is correlated with the rolling behavior of the liquid drop or the liquid-filled capsule on the surface. In this case, the contact angle with the determined Rolling angle, the rolling time are correlated. For example, the contact angle can be determined by means of the rolling period of a capsule filled with medium by means of a calibration line

different media concentrations are determined. To determine the contact angle of a liquid, the respective straight line calibration is used. Furthermore, known interfaces can also be used for the calibration, i. Interfaces and materials whose contact angles have already been determined by alternative methods. As an alternative method, the contact angle of a known solid surface (e.g.

Rubber mat) are divided by the contact angle of a specimen. The rolling time of the solid surface is then divided by the rolling time of the specimen. Of the

Contact angle can in turn be based on the relative values, as determined by a

Get calibration lines over a multiplication with the contact angles of the liquid body, determine. Once calibrated, the device of the invention allows the analysis of different properties of the liquid or liquid-filled body or the surface of the solid.

Very small angles of contact of about 0 ° (as in the case of water as a liquid) occur in hydrophilic surfaces, angles of 90 ° occur in hydrophobic and even larger angles occur in superhydrophobic surfaces. The surfaces at very large angles (> 120 °) tend to have extremely low wettability. By surface treatment, the contact angle can be changed, which can be determined by means of the device or the method according to the invention.

The method according to the invention also makes it possible to determine the hydrophobicity of surfaces, for example the surface of a liquid or liquid-filled body or the surface of the rolling track. In this way, different interactions between the surfaces of the liquid or liquid-filled body and the surface of the rolling track can be determined. Thus, the suitable

Device according to the invention and the method for determining the hydrophobicity of liquids and solids as well as for testing different surfaces or surface coatings on the solid. The determination of the contact angle allows the testing of different materials on the surface of the rolling track and it can draw different conclusions regarding the material properties of the material staked. Preferably, therefore, the rolling track is interchangeable with different materials. In a preferred embodiment, the device according to the invention is used to perform a force calculation. For example, the adhesive force between the body filled with liquid and the surface of the solid can be determined. In contrast to camera systems, the device according to the invention is easy to install and inexpensive to produce. Due to their size and the low energy requirement, the device can also be used in places where the use of camera measuring devices is not possible (for example, in the open-air area). The compact design also allows easier portable transport to the job site. The mechanical determination of the contact angle also eliminates the need for visual detection or subsequent determination of the contact angle.

In various experimental examples, the inventors have shown that the

The device according to the invention and the method are also suitable for determining the composition of a substance in aqueous solutions via the contact angle. This eliminates, for example, time-consuming chromatographic analyzes. Differently composed solutions in the form of a liquid drop or a reaction capsule filled with liquid result in different rolling times along the rolling path defined in the rolling track. The reaction of a chemical or physical reaction can be determined by determining the contact angle by means of the device or the method, since the reaction products have changed in contrast to the starting products and thus also change the composition of the aqueous solution. As a result, it can be determined, for example, whether a chemical or physical conversion of starting materials has taken place. Compared to the known visual methods (for example camera systems), the device according to the invention and the method according to the invention therefore represent a more cost-effective and at the same time easy-to-handle method. The device and the method make it possible to detect the rolling angle, rolling time simultaneously and automatically. In this way, any surfaces or liquids can be analyzed. Another advantage of the device according to the invention is that the examination of the surfaces is very practical, since the spherical test body can be reused without wear and can be easily stored or used.

Brief description of the drawings:

The invention will be explained in more detail in the following drawings. Show it 1 shows the basic structure of the device according to the invention and the principle of the method,

2 shows an embodiment of the device according to the invention,

3 the plane from the front side,

4 shows the tiltable plane with rolling track in side view, FIG. 5 test results with different reaction capsules.

Fig. 6 is a calibration line for the determination of the contact angle

Fig. 7 is a comparison of the contact angle measurements on different

surfaces

Ways to carry out the invention and commercial usability:

In Fig. 1, the principle of the device according to the invention is shown. This consists of a vertically arranged support 1 and a guide rod 2 attached thereto. A tiltable plane 8 is connected to the support 1 via lateral rails 6, 7. The plane 8 is moved by a motor either up or down, which can be set different inclination angle. This is done via a connecting means 3, which connects the rails 6, 7 with each other. The connecting means comprises

preferably lubricants that slide in the rails 6, 7 and for different

Adjust the angle via the threaded rod 2 to the motor. The shown

Drive unit consists of different coupling elements 3, 19, buffer discs 21, 23 and a spring element 20. The operation takes place via a control panel 15. While the upper end of the plane 8 is held by the carrier 1, the lower end of the plane 8 lies on a pedestal 13 and an associated console 29.

In level 8, a roller conveyor 9 is introduced, in which a round groove 24 is located. The liquid or liquid-filled body is introduced at the upper end of the plane 8 in the groove 24, for example by pipetting, manual application or by means of a dispenser. The slider 5, which is arranged transversely to the rolling track 9 within a groove 4, prevents unintentional rolling of the body. At the upper end of the plane 8 is a first sensor 1 1 and at the lower end of the plane 8, a second sensor 12. Both sensors 1 1, 12 are in the embodiment shown to light barriers. The plane 8 is gradually moved upwards with the applied body (for example a drop of liquid or a reaction capsule) via the drive device until the body starts to move. When passing the first sensor 1 1, a time detection triggered by a time detection device 14, which holds the Abrollstartzeit. When the body passes the arranged at the end of the roll-off second sensor 12, the roll time on the

Time detecting device 14 stopped. At the same time also stops the drive unit, which puts the plane 8 via the connecting means 3 and the guide rod 2 in inclination.

 By means of an angle measuring device 10, the inclination angle of the plane 8 and thus the rolling angle of the liquid or liquid-filled body can be determined.

2, a further embodiment is shown. Here, the time recording device and the angle measuring device are integrated in a console 18. Via a display device 17, the rolling time is displayed. The roll-off angle can be read in a further display 16.

In Fig. 3, the structure of the rolling track 9 and the function of the slider 5 is seen closer. The slider 5 is designed pivotable along an axis 26. In the rolling track 9 is the semicircular groove 24. On one leg of the slider 5, a nose 25 is formed on the underside, which engages in the groove 24 of the rolling track 9 of the plane 8.

In Fig. 4, the plane 8 is shown from a different perspective. The slide 5, the rolling track 9 and the two sensors 11, 12 can be seen. The plane 8 is held by means of a bracket 29 and is designed to be pivotable thereon.

Fig. 5 shows the experimental results obtained with reaction capsules obtained with an aqueous solution of an ethanol-water mixture or water. In Fig. 5A, a reaction capsule having a volume of 10 μί was applied to the plane 8. The highest contact angle is achieved with water. With increasing ethanol concentration (concentrations of 0%, 5%, 10% to 45%), the contact angle of the reaction capsules decreases. In addition to the experimental values, the theoretical values are also listed. As a comparison, a steel ball was also used. The experimentally determined values show a linear course.

In Fig. 5B, the rolling time of reaction capsules having a volume of 10 μί in

Dependence of ethanol concentration shown. With increasing ethanol concentration decreases the rolling time of the reaction capsules too. As a result, the invention are suitable

Method and device for determining the hydrophobicity of a surface, either the surface of the liquid or liquid-filled body, so the reaction capsule or the drop, or the surface of the rolling track. Experimentally, different materials can be applied to the rolling track, for example, hydrophobic or superhydrophobic surfaces. The method is also useful for the determination, analysis or detection of substances or reaction products in a body filled with fluid. Should the concentration of a

Reaction product increase or decrease, this would be based on the

Rolling behavior (e.g., rolling time) of the reaction capsule.

In Fig. 6 is a calibration line for the determination of the contact angle with reference to

Rolling time of a capsule with different ethanol concentrations from 0 to 45% shown as an example. To determine the contact angle of a liquid, the respective straight line calibration is used. In the example shown, y = -76.484x + 96.944. For x, the rolling time is used, so that the contact angle y can be calculated.

FIG. 7 shows a comparison of the contact angle measurements on different surfaces. As a comparison, a contact angle measuring device using a water drop was used. The device according to the invention (= STEG) was equipped with a simple solid specimen (ball). Since the measurement units of the two systems are fundamentally different, the results were based on the respective

Contact angles or roll times normalized on a Teflon surface (i.e., to the value of 1). Furthermore, the determined contact angle of the rubber mat was divided by the contact angle of the Teflon. The rolling time of the rubber mat was accordingly divided by the rolling time of the teflon film. To close again on the contact angle, the relative values from Figure 6 are multiplied by the contact angle of water on Teflon (106.5 °). It can be seen that both methods according to FIG. 6 and FIG. 7, the different

Surfaces reproduced with very high accuracy. The respective bar pairs are in the first approximation the same height.

Claims

 claims:

Device for determining the contact angle of a liquid or liquid-filled body and a surface of a solid, comprising a support (1) and a plane (8) inclinable therewith in an angle range of more than 0 ° to a maximum of 90 ° with a formed therein Rolling track (9) for the liquid or liquid-filled body, wherein at an upper end of the plane (8) a first sensor (1 1) for detecting the Abrollstartzeit and at one along a defined rolling path lower end of the plane (8) another Sensor (12) for detecting the Abrollendzeit of the body is arranged, wherein for detecting the rolling time of the body along the rolling path between the two sensors (1 1, 12) a time detecting means (14) is provided, characterized

 characterized in that the inclination angle of the plane (8) via an angle measuring device (10) is adjustable, whereby a rolling angle is detectable, in which the body comes into motion and the first sensor (1 1) and the second sensor (12) of the plane

(8) for determining the rolling time, wherein from the measured rolling time, the rolling distance and / or the rolling angle of the liquid or liquid-filled body, the contact angle of the body between the surface of the body and the surface of the solid can be determined.

Apparatus according to claim 1, characterized in that the rolling track (9) consists of a hydrophobic surface or coated with such.

Apparatus according to claim 1 or 2, characterized in that the rolling track

(9) comprises a semicircular groove (24).

Device according to one of the preceding claims, characterized in that it is the liquid or liquid-filled body is a drop of liquid or filled with a medium reaction capsule.

Apparatus according to claim 4, characterized in that the reaction capsule consists of a silane shell, a dextran shell or a polymer shell.

Apparatus according to claim 4, characterized in that the reaction capsule comprises a superhydrophobic surface of magnetic particles.

7. Device according to one of the preceding claims, characterized in that the carrier (1) comprises a guide rod (2) through which the plane (8) by means of a drive unit in an angular range between 0 ° and 90 ° can be tilted. 8. Device according to one of the preceding claims, characterized in that it is at the sensors (1 1, 12) to light barriers or contact sensors.

9. Device according to one of the preceding claims, characterized in that transversely to the rolling track (9) of the plane (8), a slide (5) is arranged.

10. Device according to one of the preceding claims, characterized in that the surface of the rolling track (9) is replaceable. 1 1. Method for determining the contact angle between the surface of a

 liquid or filled with a liquid body and the surface of a solid in which the liquid or liquid-filled body is applied to an inclined plane, the inclination angle of the inclined plane

 is then changed until a rolling angle of the body is reached, at which the liquid or liquid-filled body gets into motion and along a

Rolling a first sensor passes through the Abrollstartzeit is triggered, to another sensor over which the Abrollendzeit is detected, wherein from the rolling time, the rolling distance and / or the Abrollwinkel the contact angle of the body between the surface of the body and the surface of the solid is determined.

12. Use of a device according to one of claims 1 to 10 or one

 A method according to claim 1 1 for determining physical properties of the surface of the solid or the liquid or filled with a liquid body.

13. Use according to claim 12, characterized in that the contact angle between the surface of the liquid or filled with a liquid body and the surface of the solid, the surface of the solid for determining the hydrophobicity of the surface is determined.

14. Use of a device according to one of claims 1 to 10 or a method according to claim 1 1 for the determination, analysis or detection of substances or reaction products in a body filled with liquid.