EP3104950A1

EP3104950A1 - Device and method for treating a liquid containing oil droplets

Info

Publication number: EP3104950A1
Application number: EP15708162.1A
Authority: EP
Inventors: Manfred Baldauf; Werner Hartmann
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2014-03-13
Filing date: 2015-02-26
Publication date: 2016-12-21
Also published as: WO2015135764A1; DE102014204645A1

Abstract

The invention relates to a device for treating a liquid containing oil droplets, said device comprising a supply line that conducts the liquid and a reaction device comprising at least one ultrasonic transducer for forming a stationary ultrasonic wave in the flowing liquid, said wave causing the formation of larger oil droplets. The reaction device (4) is arranged either at the end of the supply line (3) in the transition zone to a tank (5) that receives the liquid (7) together with the oil droplets (18), or in the tank (5), downstream of the end of the supply line (3).

Description

description

DEVICE AND METHOD FOR TREATING LIQUID CONTAINING OLD POTS

The invention relates to a device for the treatment of a liquid containing oil droplets, comprising at least one supply line leading the liquid, and a reaction ^¬ device comprising at least one ultrasonic transducer for forming a standing ultrasonic wave in the flowing liquid to form larger oil drops.

In many applications, such as the mining industry, oil and gas extraction or well drilling falls to wastewater, which in addition to possibly suspended

Solid particles in particular also contains oil droplets. These contaminants must be removed before the water is returned to the environment. While there are sufficient technical approaches to remove the suspended solid particles, such as by sedimentation, by hydrocyclones or centrifuges, in particular the small oil droplets with diameters of 20 microns and less pose a problem. It comes to emulsion formation, so that these small Oltröpfchen due The extremely fine distribution in the liquid can be difficult to separate. The use of filters is very expensive, in particular, only a semi-continuous operation is possible because the filters are often cleaned. One way to bind the fine oil droplets in the form of larger drops of oil provides for the use of a reaction device comprising at least one ultrasonic transducer. This ultrasonic transducers respectively in the reaction apparatus an ultrasonic standing wave sufficient intensity is generated that should he ^¬ grasp the entire flow cross section. Akustophoretische forces within this Ult ^¬ raschallfeldes cause a drift of the emulsified Oltröpf ^¬ chen to the vibration nodes, respectively, correspond to nending node levels of the standing wave pattern. There, the fine droplets of oil can coagulate, so that larger oil drops form, which can be separated with already known technical methods. To make this possible, the ultrasonic transducer is at frequencies of typically

0.5 - 2 MHz operated with a power of a few W / cm ² . Optionally, a reflector or a second ultrasonic transducer operating in phase with the first ultrasonic transducer is associated with the ultrasonic transducer in order to generate a sufficiently intense wave pattern. In order to achieve a high throughput, a large number of such ultrasonic transducers is provided in the manner of an array, so that a corresponding amount of accumulating water can be treated. It is known to build in the reaction apparatus, respectively the UI ^¬ traschallwandler directly quasi in-line in a water line, and corresponding fluid flow dividing tube devices are provided in array-like arrangement to supply the water to the individual transducers, and thus the separate wavefields. Due to the integration of such a larger array in the pipeline, it is common that the supply extends from a narrower diameter to a larger diameter, in which area the reaction device is provided with the plurality of ultrasonic transducers and the corresponding power split, after which the pipe again tapers to continue the treated ^water with the larger oil drops. However, it has now been found that the larger oil ^droplets adhere behind the ultrasonic transducers respectively behind the standing wave fields on the surface of the current distribution respectively of the discharging tube, so that in the area of the ultrasonic transducers themselves, on the reflectors and the surrounding side walls, as well Immediately behind the ultrasonic transducers, ie still in the area of the reaction device, respectively behind it, forms an oil film on the corresponding walls, which on the one hand limits or obstructs the flow, and on the other hand adds the system so that it can be cleaned again. Often This oil film consists of agglomerates of fine oil droplets and can be due to unfavorable flow conditions or strong accumulations in places solve again in the form of large flake-like structures. Will these detached flocs in areas of high shear forces, such. As in the range of pipe constrictions or curvatures, these agglomerates can be sheared again into very small droplets so that they can no longer be separated from the carrier fluid (water) due to their small size in the subsequent separation process.

The invention is therefore based on the problem to provide a device which is improved in contrast and in which a safe oil separation without risk of clogging is possible.

To solve this problem is provided according to the invention in a device of the type mentioned that the Re ^¬ action device either at the end of the supply line in the transition to a liquid including the oil droplets receiving tank or directly in the tank, the end of the supply line is arranged ,

According to the invention, the reaction apparatus is not used in-line in a pipeline, but is UNMIT ^¬ telbar in the region of the transition of a lead in a phase separation of oil / carrier fluid (eg water) serving tank. The reaction apparatus may be either at the end of the supply line and directly in the transition be disposed adjacent to the tank or to the, or already in the tank, so that UNMIT ^¬ telbar the end of the feed line following. This makes it possible to design the reaction device in such a way that ultimately no fluid flow restricting or influencing pipeline follows behind the standing wave field, but the treated liquid together with the oil droplets formed in the ultrasonic field flows directly into the tank. In the tank then inevitably leads to a corresponding separation of the oil droplets from the carrier liquid, for example se water by the oil droplets float on the water surface and form there an oil film that can be deposited with a corresponding separator. The water purified in this way in the tank can then be taken out of the tank via a suitable discharge line and either further treated or fed to the environment.

A line wall side adhesion of an oil film with the adverse consequences, namely the slow clogging or detachment of large oil agglomerates respectively an impairment of the fluid flow and thus the cleaning performance and the need for a cleaning of the system is no longer given in the inventive device with particular advantage. Because the reaction device respectively the ultrasonic transducer and thus the ultrasonic field is as described no downstream of the fluid flow impairing pipeline, but rather the treatment liquid pours directly into the Tankvolu ^¬ men.

It is useful as described, if the reaction ^¬ device has an array of individual line sections, each with an ultrasonic transducer. The z. B. paralle ^¬ len line sections are dimensioned so that they cause only a current distribution directly in the ultrasonic transducer, so that form in the respective line sections dedicated standing wave fields through which flows a defined volume of liquid. They are therefore essentially provided only in the area of the corresponding fields, and do not extend in the direction of the tank. A certain extent in the direction of the supply line is of course possible, since in this area only the finely emulsified oil droplets are present and there is no formation of oil film. It is therefore a kind of honeycomb structure in the form of an axially short pipe array, the distribution of the inflow to the individual reactors or reactor pairs in the case of using an ultrasonic transducer with associated reflector or two in phase se working ultrasonic transducer is used. Thus, a liquid throughput of several cubic meters per day with appropriate cleaning performance is possible with the device according to the invention.

Depending on the embodiment, the supply line can open at different positions of the tank. According to a first embodiment of the invention, the supply line can open at the bottom of the tank. In this case, if the reaction device is still incoming line each installed, consequently, the reaction device may be installed directly in front of the tank, so that the treated, the oil drops having water with the relying ^¬ sen of the reaction apparatus, respectively, of the ultrasonic field directly into the tank pours. If the reaction device is located in the tank, it is immediately downstream of the bottom-side supply line.

Alternatively, it is conceivable to arrange the supply line to a side wall of the tank, depending on the embodiment, the reaction onsvorrichtung either supply side immediately before the mouth in the tank or tank, immediately following the supply line is arranged. Regardless of where the supply line opens, it is of course also possible to have several supply lines, which are associated with corresponding reaction devices, open in parallel in the tank.

The device is further characterized by a separating device for separating the floating in the tank on the surface of the liquid oil, in particular in the form of a skimmer. About this separator, the superficially accumulating oil can be easily separated and thus the water to be cleaned.

In addition to the device, the invention further relates to a method for treating a liquid containing oil droplets using a device of the type described, wherein the liquid is supplied via the supply line of the reaction ^¬ device in which the liquid at least a standing ultrasonic wave happens during which the oil droplets combine to form larger oil droplets, the liquid together with the oil droplets flowing from the reaction device directly into the tank where the oil droplets surface float and are separated from the liquid by means of a separator. The direct inflow of the liquid from the reaction device into the tank avoids the risk of clogging of the reaction device due to oil film formation.

In this case, the liquid stream can be divided into a plurality of individual streams via line sections, wherein at least one ultrasonic transducer is arranged in each line section, so that each storm passes through a separate stationary ultrasonic wave. Through this quasi the ultrasonic transducers ^¬ upstream, such as honeycomb Stromaufteilerstruktur the throughput can significantly increased and thus the cleaning performance significantly. As a separation device is preferably as described

Skimmer used, over which can be skimmed off the oil surface in the tank forming oil film.

Further advantages, features and details of the invention will become apparent from the embodiments described below and from the drawing. Showing:

1 shows a schematic diagram of an inventive

Device of a first embodiment,

2 shows an enlarged detail view of the area II in FIG

1, in section,

3 shows an enlarged detail view of the area III in FIG

2, and

4 shows a schematic diagram of an inventive

Apparatus of a second embodiment. 1 shows an inventive device 1 for treatmen ^¬ development of an oil droplet-containing liquid 2 which is supplied via a supply line. 3 At the end of the feed line 3, a reaction device 4 is arranged, which passes directly into a tank 5. The liquid 2 flows to the reaction ^¬ onsvorrichtung 4 and is treated in this ultrasonic wave fields, formed from separate standing ultrasonic waves, for the agglomeration of fine oil droplets. The treated liquid flows from the outlet of the reaction device 4 directly into the tank 5. The larger agglomerated oil drops contained in the treated liquid float in the treated liquid, so that an oil film 6 on the quasi oil-free, purified liquid 7 abschei ^¬ det. The oil film 6 can be separated with a suitable separator 8, for example a skimmer 9. The ge ^¬ purified liquid 7 is withdrawn via a discharge line 10 from the tank. 5

FIG. 2 shows an enlarged detail view of the region II from FIG. 1. Shown is a section through the reaction device 4 in the form of a schematic representation. This comprises a flow divider 11 which is in the form of a multiplicity of individual line sections 12 which divide the liquid flow. The individual line sections 12 may be formed, for example, by a plurality of individual, in cross section, for example, four-, six- or octagonal short pipe sections, which are assembled into a kind of honeycomb structure. In the interior of each such line section 12, at least one ultrasonic transducer 13 is arranged, in the embodiment shown at an opposite

Wall is associated with a reflector 14. The ultrasonic transducer

13 generates a standing ultrasonic wave from the reflector

14 is reflected back. It is consequently at Reso ^¬ nanzbedingung in each line cross section of an ultrasonic field 15 having a plurality of lying in the flow direction nodal planes 16 due to the geometry of the respective wall ^¬ ler-reflector pairs. That is, consequently, over the line cross-section, a standing ultrasonic field is generated with several excellent node levels. This takes place in each line section 12. Since the reaction ^device 14 ^{engages over} the entire cross-section of the feed line 3, consequently the entire inflowing, contaminated liquid 2 must flow through the corresponding ultrasonic fields 15, where it is exposed to the respective field.

The contaminated liquid 2 comprises, on the one hand, the carrier liquid, which is ^deposited as purified liquid 7 in the tank, and fine oil droplets 17 emulsified in the carrier liquid. In the ultrasonic field 15, the fine oil droplets 17 are subjected to acoustophoretic forces, which are the transport fine ultrasonic droplets 17 to the vibration node planes 16, as shown in principle in FIG. This means that in the vibration node planes 16 the

Collect ultrasonic droplets 17. There inevitably comes to an agglomeration of the ultrasonic droplets and thus the formation of larger ultrasonic drops 18, as shown in FIG 3, on coalescence of the agglomerates forming droplets.

Since the liquid 2 flows continuously through the cleaning device 4, consequently, the oil drops 18 formed are also discharged again. Due to the arrangement of the reaction device 4 directly in the transition to the tank 5, therefore, the ultrasonic drops 18, if they leave the respective ultrasonic field 15, directly and directly into the volume of the tank 5, without them still by a reaction device 4 downstream pipeline or the like stream. They are therefore distributed inside the tank 5 and float superficially, where they form the oil film 6. That is, the oil drops 18 are, if at all, only for a very short time in a geometrically circumscribed tube volume, namely, when they are within their formation in the reaction device 4. Since they only form there, it can inevitably come to no clogging in this area, since the flowing liquid after formation also immediately transported back from the reaction device 4 and get into the tank volume. Although a pair of reactors consisting of ultrasound transducer 13 and reflector 14 is provided in FIGS. 2 and 3, in a simple embodiment it would also be conceivable to use only one ultrasonic transducer 13 to generate the standing wave. Alternatively, two ultrasonic transducers 13 could be provided opposite each other, which operate in phase, so that the intensity of the ge ^¬ formed wave can be significantly increased. 4 shows a further embodiment of an inventive ^¬ SEN device 1, the same reference signs ^¬ are provided for the same components. In this embodiment of the invention, the supply line 3 transporting the contaminated liquid 2 does not open at the bottom of the tank, as in the above-described embodiment, but at a side wall of the tank 5. Provided again is a reaction device 4, but here immediately following the end of the supply line 3 is arranged inside the tank 5. The operating principle is as ^¬ derum the same. The oil droplets 18 are formed in the same manner as with respect to Figures 2 and 3 in the reaction device 4 while flowing through the same with the contaminated liquid 2. In turn, they pass directly into the volume of the tank 5 immediately after the reaction device 4; here, too, the individual reactors, ie the ultrasonic transducers or the reactor pairs, that is to say the converter / reactor pair or the converter / converter pair, do not have the fluid flow downstream or constricting piping or the like downstream. Of course, it is possible to set, in the case of the off ^¬ design according to FIG 1, the reaction apparatus 4 to the interior of the tank 5, downstream of immediacy ^¬ bar the end of the feed line 3, as in the embodiment of Figure 4 is the possibility of the reaction apparatus 4 similarly to FIG. 1, to be arranged at the end of the supply line 3 in the immediate transition to the tank 5. Of course, there is also the possibility of the supply line 3 and thus the reaction device 4 on a different side wall than the the discharge 10 opposite wall, as shown in FIG 4, to arrange.

Although the invention in detail has been illustrated approximately example in more detail by the preferred execution and described, the invention is not ^¬ limited by the disclosed examples and other variations can be derived by those skilled thereof, without departing from the scope of the invention.

Claims

claims

1. A device for treating a liquid containing oil droplets, comprising at least one supply line leading the liquid, and a reaction device comprising at least one ultrasonic transducer for forming a standing ultrasonic wave in the flowing liquid to form larger oil drops, characterized in that the reaction device (4) either at the end of the supply line (3) in the transition to a liquid (7) together with the oil drops

(18) receiving tank (5) or in the tank (5), the end of the supply line (3) following, is arranged.

2. Apparatus according to claim 1, characterized in that the reaction device (4) has an array of individual line sections (12) each having an ultrasonic transducer (13).

3. Device according to claim 1 or 2, characterized marked, that the supply line (3) at the bottom of the tank (5) opens.

4. Apparatus according to claim 1 or 2, characterized in that the feed line (3) on a side wall of the tank (5) opens.

5. Device according to one of the preceding claims, characterized in that a separating device (8) for the separation ^{¬ off} in the tank 85) on the surface of the liquid (7) floating oil (6), in particular a skimmer (9), vorge see is.

6. A method for treating a liquid containing oil droplets using a device (1) according to one of the preceding claims, wherein the liquid (2) via the feed line (3) of the reaction device (4) is supplied, in which the liquid (2) at least a standing Ul ^¬ traschallwelle (15) passes during which the Oltröpf ^¬ chen (17) combine to larger oil drops (18), wherein the Liquid together with the oil drops (18) from the reaction device (4) flows directly into the tank (5), where the oil drops (18) float superficially and by means of a separator (8) are separated from the liquid (7).

7. The method according to claim 6, characterized in that the liquid flow over line sections (12) is divided into a plurality of individual streams, wherein in each line section (12) at least one ultrasonic transducer (13) is arranged so that each stream is a separate standing ultrasonic wave (15) happens.

8. The method according to claim 6 or 7, characterized in that a skimmer (9) is used as the separating device (8).