APPARATUS AND METHOD FOR PICKING UP OIL FROM THE SURFACE OF WATER

Abstract

The invention relates to a device for taking up oil from a water surface, comprising a container for receiving the oil and an oil-transporting means, wherein a portion of the oil-transporting means can be brought into fluid communication with the water surface and another portion of the oil-transporting means is disposed within the container, wherein the oil can be transported into the container via the oil-transporting means, wherein the oil-transporting means is formed from a hydrophobic fabric, the surface of which comprises filament-shaped and/or grid-like structures which are designed in such a way that they retain a gas layer on the surface of the hydrophobic fabric under water. The invention further relates to a corresponding method for taking up oil from a water surface.

Claims

1. A device for taking up oil from a water surface, comprising a container for receiving the oil and a hydrophobic fabric for transporting oil having a surface which comprises filament-shaped and/or grid-like structures, wherein a portion of the fabric can be brought in fluid communication with the water surface and another portion of the fabric is disposed within the container, wherein the oil can be transported into the container via the fabric, characterized in that the filament-shaped and/or grid-like structures are designed such that they retain a gas layer on the surface of the hydrophobic fabric under water.

2. The device according to claim 1, characterized in that a plurality of filaments are arranged on the surface of the fabric.

3. The device according to claim 1, characterized in that the fabric is designed as a spacer textile.

4. The device according to claim 1, characterized in that the fabric is designed in the form of a plurality of strip-shaped surfaces.

5. The device according to claim 1, characterized in that the container floats in the water, wherein the bottom of the container in the unfilled state is disposed below the water surface.

6. The device according to claim 1, characterized in that the fabric is guided into the container over the side wall of the container.

7. The device according to claim 1, characterized in that the container comprises a lid.

8. The device according to claim 1, characterized in that the container is a closed container, wherein the closed container comprises a pressure compensation valve.

9. A methods for taking up oil from a water surface using a container for receiving the oil and a hydrophobic fabric for transporting oil having a surface which comprises filament-shaped and/or grid-like structures, wherein a portion of the fabric can be brought into fluid communication with the water surface and another portion of the fabric is disposed within the container, wherein the filament-shaped and/or grid-like structures are designed such that they retain a gas layer on the surface under water, wherein the oil is transported into the container via the fabric.

10. (canceled)

11. The device according to claim 2, wherein the fabric is a flock textile.

12. The device according to claim 1, characterized in that the fabric is designed in the form of a continuous surface arranged around the container.

13. The device according to claim 1, characterized in that the container is locked on the water surface, wherein the bottom of the container in the unfilled state is disposed below the water surface.

14. The device according to claim 1, characterized in that the fabric is guided into the container through slot-shaped openings in the side wall.

15. The device according to claim 7, wherein the lid comprises a valve for pressure compensation.

Description

[0045] In the figures:

[0046] FIG. 1 is a schematic representation of a principle for taking up oil from a water surface by means of a device according to a first embodiment of the invention in FIGS. 1A, 1B, 10 and 1D;

[0047] FIG. 2 is a schematic representation of a device for taking up oil from a water surface according to a first embodiment of the invention; and

[0048] FIG. 3 is a schematic representation of a device for taking up oil from a water surface according to a second embodiment of the invention.

[0049] FIG. 1 shows in FIGS. 1A, 1B, 1C and 1D a schematic representation of a principle for taking up oil 10 from a water surface 8 by means of a floating device. FIG. 1A shows a floating device for taking up oil 10 from a water surface 8. The device comprises a container 2 for receiving the oil and an oil-transporting means designed as a superhydrophobic fabric 4. The container 2 floats on the water, wherein the bottom of the container 2 is disposed deeper in the water than the superhydrophobic fabric 4. The edge of the collection container 2 protrudes above the water surface 8. One end of the fabric 4 is fixed at the bottom of the container 2, as a result of which a part of the fabric 4 which is disposed within the container 2 is below the level of the water surface 8. The fabric 4 is laid over the edge of the container 2. The surface floats on the water surface 8, wherein the end facing away from the container 2 is held under the water surface 8, for example by a small weight. A part of the fabric 4 is thus located below the water surface 8 and is in fluid communication with the water. The superhydrophobic fabric 4 comprises filament-shaped structures on the surface which are designed in such a way that they retain an air layer 6 on the surface under water.

[0050] FIG. 1B shows a further representation of the device shown in FIG. 1A. An oil film 10 has spread over the water surface 8. In FIG. 1C the oil 10 on the water surface 8 comes into contact with the fabric 4. The oil 10 is adsorbed by the filament-shaped structures of the fabric 4. Thus, the air layer 6 is replaced by the oil 10. The fabric 4, for example a flock textile, is preferably not only superhydrophobic but also oleophilic. To be wetted with water under water means an energetically very unfavorable state, therefore air is drawn under water and retained as an air layer 6 on the surface. In terms of energy, this is also a very unfavorable state, since the air has to be retained against the buoyancy, but it is more favorable than if the superhydrophobic, oleophilic fabric 4 were wetted with water. If the oil 10 comes into contact with the fabric 4, the oleophilic surface is wetted with oil 10. An energetically more favorable state is achieved when the air layer 6 is replaced and the textile fabric 4 is wetted with oil 10 and the air retained on the surface can rise. The oil 10 is transported downwards and the energy stored by the energetically unfavorable process of retaining the air is set free hereby. A transport also takes place on the water surface, wherein the oil 10 can flow into the container 2. The oil 10 is thereby transported in the filament-shaped structures of the fabric 4 along the surface into the container 2. If the edge of the container 2 does not protrude too much above the water surface 8, the oil 10 can flow over the edge into the container 2. As long as the end of the superhydrophobic fabric 4, which is located within the collection container 2, is below the water surface 8 and/or the oil film 10, the oil 10 is discharged again. If the end in the collection container 2 is above the water surface 8 and/or the oil film 10, the transport stops at the point in time at which the flock is completely wetted.

[0051] As a result of the entry of the oil 10 into the container 2, the oil level rises in the interior of the container 2 and its weight increases. As a result, the container 2 sinks deeper into the water. As long as the level of the oil 10 inside the container 2 is below the water surface 8, oil 10 is collected from the water surface 8 and will flow into the container 2. In FIG. 1D there is no longer any oil 10 on the water surface 8.

[0052] FIG. 2 shows schematically an embodiment of a device 1 for taking up oil 10 from a water surface 8 which is designed as a floating device 1, a so-called “oil float”. The device 1 comprises a container 2 for receiving the oil and an oil-transporting means formed by a superhydrophobic fabric 4. This comprises filament-shaped structures on the surface, which are formed such that they retain a layer 6 of gas on the surface under water. The fabric 4 has the form of a continuous surface which is arranged around the container 2. The fabric 4 is guided into the container 2 through slot-shaped openings 18 in the side wall. The container 2 is provided with a lid 12.

[0053] FIG. 3 shows schematically an embodiment of a device 1 for taking up oil 10 from a water surface 8, which is designed as a diving device, a so-called “oil diver”. The container for receiving the oil 10 is a closed container 14 in the form of a hollow sphere. This is held under the water surface 8 by means of an anchorage 20. The closed container 14 comprises two inlet openings 26 through which the superhydrophobic fabric 4 is introduced into the closed container 14. The driving force for the oil transport results from the height difference between the water surface 8, at which the oil 10 is taken up, and the lower-lying container 14, into which the oil 10 is transported. In the diving embodiment the transport is directed exclusively downwards. The device 1 comprises a means for venting and for pressure compensation 16 within the container 14. The means for venting and for pressure compensation is protected against rain and splash water by a lid 24.

EXAMPLE 1

[0054] Taking Up Oil by Means of a Floating Device

[0055] In order to prepare a device for taking up oil, a laboratory glass container with a height of 5 cm, a diameter of 2 cm (wide-mouth vial with rolled edge for snap-on caps, 45×22 mm, Scherf Prazision Europa GmbH) was fixed on a Petri dish with washers as anchoring, whereby a pedestal and sufficient weight were ensured. A flock textile with a fiber length of 1.2 mm and a density of 13 fibers per mm.sup.2 (SwissFlock AG) was cut to strips with a length of 15 cm and a width of 1 cm. The surface of the flock textile was hydrophobized with Tegotop 210 (Evonik Industries). One end of the flock textile strip was glued to the inside of the glass container so that the end rested on the bottom of the container.

[0056] The device was placed in an aquarium. The aquarium was filled with water, wherein the edge of the collection container protruded approximately 5 mm above the water surface. The flock textile floated on the water surface. The end resting on the water was held under the water surface by a small weight and retained an air layer. Due to the superhydrophobic property of the flock textile, a meniscus formed between the water surface and the textile.

[0057] Subsequently 10 ml of an oil (isopropyl myristate, Sigma Aldrich) which was colored with Sudan black (Sigma Aldrich) was placed on the water surface. While spreading over the water surface it finally reached the flock textile. Due to the oleophilic property of the textile and supported by the meniscus of the water, the oil was adsorbed on the surface of the flock textile. It only took a few seconds for the oil to displace the air layer under water. The transport into the glass vessel lasted a little longer. However, as soon as the flock textile was completely wetted, oil was separated out again within the glass vessel.

EXAMPLE 2

[0058] Taking Up Oil by Means of a Diving Device

[0059] For the oil diver, a plastic Petri dish was glued onto a plastic hemisphere with epoxy resin so that a closed volume was created. The joints were additionally sealed with hot glue (UHU). Weights were attached to the underside of the sphere in order to be able to keep the air-filled volume under water. Two holes were drilled in the top side formed by the Petri dish. Two cut strips of a flock textile (fiber length 1.2 mm, density 13 fibers per mm.sup.2, SwissFlock AG) with a length of 12 cm and a width of 1 cm were hydrophobicized with Tegotop 210 (Evonik Industries). The two strips were placed one on top of the other at the fiber side and fixed at one end by means of a shrink tubing. This end was passed through one of the holes into the inside of the oil diver. The sealing was carried out again with hot glue. A PVC hose with a diameter of 4 mm was inserted into the remaining opening of the oil diver, via which a pressure compensation between the internal volume of the diver and the environment can be established. The whole device was placed in an aquarium filled with water. The diver was disposed below the water surface. The two loose ends of the two flock textiles laid against the water surface. The PVC hose protruded from the surface of the water. The sealings withstood the water and the inside of the diver remained dry.

[0060] Then 10 ml of an oil (isopropyl myristate, Sigma Aldrich) which was colored with Sudan black (Sigma Aldrich) were placed on the water surface. This was adsorbed onto the surface of the flock textile and covered it completely after just a few seconds. Moreover a transport to the oil diver took place. The oil dripped down from the fixed ends, which were fixed within the volume to its lid. It was found that approximately to the same extent also water got into the interior of the oil diver via the flock textile. It is assumed that the reason for this was that the gap between the flock textiles pressed together was too large. It is accordingly assumed that an improved fixation by pressure, for example by a clamp, should provide a remedy. All in all, the principle of collecting oil underwater with a diving device could be demonstrated.

LIST OF REFERENCE SYMBOLS

[0061] device 1 [0062] container 2 [0063] superhydrophobic fabric 4 [0064] gas layer 6 [0065] water surface 8 [0066] oil 10 [0067] lid 12 [0068] closed container 14 [0069] pressure compensation device 16 [0070] openings 18 [0071] anchorage 20 [0072] lid 24 [0073] inlet openings 26