DE4443297C1 - Emulsion splitting by electro:coagulation, flotation and decanting - Google Patents

Abstract

A device for separating oil-in-water emulsions and for regenerating cleaning and degreasing baths by electrocoagulation is disclosed. The device for regenerating cleaning and degreasing baths, in particular by separation in an electrophysical cell (3), is characterised in particular in that at least two independent electrode devices (1, 2) have their own independent and separately adjustable current circuits (7-10). The formation of coagulation seeds and the electrocoagulation process may thus be both independently adapted to operation conditions and optimised. The separate circuits for both electrode devices (1, 2) allow the process to be carried out with a small gap between electrodes, low voltages and high current densities, when coagulation seeds are to be formed on the soluble electrodes (2), and allow the electrocoagulation process on the permanent electrodes (1) to be carried out with a larger gap between electrodes, high voltages, high field intensities, low current densities and little gas generation.

Description

The invention relates to a device for splitting oil in water emulsions using electrocoagulation Large quantities fall in industrial manufacturing processes wastewater containing oil. In many cases they form oil and Water an emulsion, d. H. the oil is in the form of Microdroplets in the water. Carrying these oil droplets surface electrical charges, which causes them Drop an even distribution in the water take in. An additional and often crucial The oil-water emulsion is stabilized by Wetting agents, such as part of Are detergents. The loads of those with these surfactants enveloped oil droplets prevent the droplets flow together and rise to the surface.

The disposal of the oil-water emulsions, which is a strong environmentally harmful waste is becoming more and more one important factor in production costs. Furthermore calls for increasingly stringent legislation to protect the Environment the avoidance or reduction of waste materials. For this reason, processes are also gaining economically Importance that a cycle management in particular of Allow cleaning water.

When splitting emulsions with organic substances the splitting agents are insufficiently discharged with the oil. To One disadvantage of these processes is the entry of Fission chemicals or their reaction products in the Water, causing water reuse only is conditionally possible.

The use of inorganic splitting agents leads to Rule for salting the water. With the widespread Use of hydroxide-forming metal salts arise  in addition, large quantities of sludge, their disposal is becoming increasingly difficult.

The problem of salting is avoided in the case of processes which the hydroxides cannot by using metal salts be generated chemically, but electrophysically. This happens with an electrode device at the Aluminum plates as cathode and iron plates as anode be switched. The formation of electrically non-conductive layers on the Electrode surfaces. This causes the current to flow back, the process comes to a standstill. The need the result is frequent cleaning of the electrodes. On The big disadvantage of this method is the big one Amounts of difficult to dispose of, oil-laden hydroxide sludge. With electrocoagulation, as in the script DE-PS 37 39 580 C2 is described, the surface charge the oil drop used for phase separation. Under the influence an electrical field between two electrodes the negatively charged droplets to the positive electrode and coagulate into larger drops, which are then decanted can be separated. The gas formation by means of Electrolysis of the water supports the oil / water Separation.

DE-AS 21 25 741 describes a method in which the wastewater which contains emulsified impurities can, by several perpendicular to the flow direction and fields arranged next to each other with the same or different field strength is passed.

Another method is disclosed in DE-OS 37 17 633, an oil / water emulsion through an electrolytic cell leads, in the anode and cathode at a short distance are arranged from each other and the cell voltage is brief can be switched on or off.  

The disadvantage of this principle of oil / water separation is that long treatment times, which is why these procedures so far have found little practical application.

A significant reduction in treatment times at the Emulsion splitting through electrocoagulation is caused by Entry of coagulation kernels in the oil to be split Water mixture reached. The coagulation cores are in the Usually microscopic, inorganic structures on which the Coagulation of the oil droplets discharged at the electrodes takes place. Cores of this type reduce the energy barrier the surface tension and those caused by surfactants steric effects. This will cause the Droplets discharged in the electric field are relieved.  

The presence of a sufficient amount of For these reasons, coagulation cores are more crucial Significance for emulsion splitting according to the principle of Electrocoagulation.

In a known method for electrocoagulation, which in EP 0 220 189 B1 is disclosed, the Coagulation cores from between the electrodes Metal inserts formed. The one caused by influenza Dissolution of these metal inserts at certain pH Values for the formation of hydroxides as coagulation nuclei accelerate the coagulation of the oil droplets. Disadvantageous in this process is that only limited amounts of Hydroxides are formed as coagulation nuclei. About that in addition, there are only very limited ones with this method Ways to increase the number of coagulation cores vary.

Another disadvantage is that emulsions or aqueous Cleaning media with different or fluctuating Properties or compositions are difficult to process can be, among other things, that the necessary Remodeling to change the area ratio of the To reach electrodes requires a lot of effort. The limited formation of coagulation nuclei and their difficult to influence leads to more limited Possible application of this method.

The invention was based on the object, the area of application to expand electrocoagulation and increase flexibility increase as well as the disposal costs by reducing the to minimize waste quantities requiring disposal.

To solve the problem it is assumed that Device for splitting emulsions and for regeneration of cleaning and degreasing baths, in particular by Electrocoagulation in an electrophysical cell, at that according to the invention at least two independent of each other Electrode devices, each with its own circuit are arranged. This means that each circuit can be operated independently of  the other be regulated. This way both the formation of the coagulation nuclei as well as the process of Electrocoagulation to each other independently Operating conditions are adapted and optimized. The separate circuits for the two Electrode devices offer the possibility of the process with small electrode spacings, low voltages and high current densities to form coagulation nuclei at the soluble electrodes, and with larger distances, high Voltages, high field strengths, small current densities and low gas development for electrocoagulation at the operate stable electrodes.

In the electrophysical cell, polarity reversal is possible Electrode devices arranged with cathode and anode of each electrode device from the same Material. This has the advantage that in particular periodic change in the current direction Formation of coagulation nuclei on the one hand as well as the Electrocoagulation process, on the other hand, at a high level is stabilized. The cathode of an electrode device becomes the anode and vice versa. So that is education of electrically non-conductive layers on the electrodes, which leads to a reduced current density with the consequence of a lead to deficient coagulation, advantageously avoided.

The arranged electrode devices are included Power supplies for clocked and variable adjustable voltage, especially DC voltage connected. This advantageously results in a given Tension, which the Coulombs attraction of Droplets determined to the electrodes, lower integral Current flows and therefore a much lower one Energy consumption and significantly reduced gas formation reached. The adjustability of the voltage serves advantageously the optimization of the process and thus the economic efficiency of the system.  

At least two of the independent Electrode devices consist of different ones Materials. The one for the formation of Coagulation cores provided advantageously exist from a metal that is formed by electrolysis Hydroxides, insoluble salts, etc. leads. For example these electrodes can be made of an aluminum alloy be used, a passivation of the surface counteracts. For another, for the process of Electrocoagulation provided electrode device preferably an insoluble or insoluble material used. This serves to optimize the implementation of the Processes and leads to long downtimes. For example here as the electrode material of high-alloy steel (preferably V4A, material number 1.4576) will.

The electrode devices with different Material composition are interlocking arranged. The interlocking construction will preferably with an average power consumption of less than or equal to 2 kWh / m³. It is advantageous that the Formation of coagulation nuclei, the confluence of the Droplets of oil and the one supported by flotation Oil separation takes place in a cell. This allows one very compact design that works in tight spaces can be used.

Alternatively, the electrode devices are included different material composition spatially separated arranged from each other. High power consumption (preferably greater than 2 kWh / m³) during the splitting process leads to a intensive gas formation with the consequence of turbulent Currents in the cell, the process of coagulation affect negatively and with the proposed arrangement be avoided because the medium flowing through the cell first the soluble and then the insoluble Flows through electrode devices.  

Guide devices for discharging gas generated by electrolysis on the soluble electrodes ( 2 ) of the electrode arrangement ( 6 ) are arranged in the housing. This constructive design of electrode devices and housing advantageously ensures that a largely laminar flow is generated between the electrodes and that turbulent flow, convection currents or backmixing, in particular between the electrode devices, is effectively prevented. In addition, the electricity consumption is reduced by optimizing the flow behavior in the cell.

An exemplary embodiment should be based on the figures are explained. Show

Fig. 1 is an electro-physical cell having two electrode means, each with 4 electrodes which are separated from each other,

Fig. 2 shows an electrophysical cell with two electrode devices, each with 4 electrodes, which are arranged interdigitated, and

Fig. 3 shows a formation of baffles in an electrophysical cell.

Fig. 1 shows a housing 3 of an electro-physical cell with a guide plate 4 and an electrode device for the Koagulationskernbildung 6 as well as an electrode device for the electrocoagulation 5, both of which have their own controllable current sources. One current source is connected to the alternating and symmetrically arranged anodes 7 or cathodes 8 of the electrode device for electrocoagulation 5 , another to the also alternating and symmetrically arranged anodes 9 or cathodes 10 of the electrode device for coagulation core formation 6 . In particular, the polarity reversal of the soluble metal electrodes of the coagulation core formation electrodes 2 results in the controlled dissolution of deposits or their prevention, which enables continuous coagulation core formation.

The polarity reversal of the permanent electrodes 1 of the electrode device for the electrocoagulation 5 is preferably carried out in periods between 1 s and 100 min.

The frequency of the clocked DC voltage, in particular at the electrode device for electrocoagulation 5, is preferably between 1 and 1000 Hertz.

The emulsion splitting is preferably carried out in pH Value range 7 to 12 and at temperatures between 1 ° C and 100 ° C carried out.

The emulsion to be split is introduced into the electrolysis cell in task 13 and is split up in the area of the electrode devices 6 and 5 , the gas bubbles formed on the electrodes floating free and demulsified oil as well as flotatable metal hydroxides and solid particles in the oil layer 14 . There, the oil and the flotatable solids are removed via the oil drain 12 , while sedimentable substances accumulate on the bottom of the secondary clarification zone 15 and are removed if necessary.

The treatment times of the emulsion are preferably in Range between 10 s and 60 min, the energy requirement is between 0.1 and 50 kWh / m³.

In FIG. 2, the interlocking arrangement of the electrode means is shown, which is particularly vorteilhaftig used due to their compact design. Fig. 3 shows a particularly advantageous variant showing the arrangement of guide plates 4 in the housing of the electro-physical cell 3 which cause the emulsion to be treated or their cleavage products in a uniform flow as possible. In the process of electrocoagulation as well as the formation of the coagulation nucleus, gas formation necessarily results from the electrolysis of the water. Gas formation generally leads to turbulent flow, with the result that the coagulation process is disturbed. This is therefore avoided by the arrangement of the electrode devices 5 and 6 according to FIG. 3, in which the electrolysis gas is derived from the soluble electrodes 1 by a suitable design of the housing 3 and the guide plates 4 .

So far, only two electrode devices 5, 6 have been shown. Arrangements with multiple electrode devices are expedient as required, in particular in order to increase the throughput and the separation quality. Blocks of electrode devices can be formed ( 5, 5, 5,... ; 6, 6, 6, 6 ...) As well as alternating arrangements ( 5 , 6 , 5 , 6 , ... ).

Reference list

1 Insoluble electrodes
2 Soluble electrodes
3 housing of the electrophysical cell
4 baffles
5 electrode device for electrocoagulation
6 electrode device for coagulation nucleation
7 connection for the anodes of 5
8 connection for the cathodes of 5
9 connection for the anodes of 6
10 connection for the cathodes of 6
11 discharge of the aqueous phase
12 oil drain
13 Application of the emulsion
14 oil layer
15 Bottom of the clarification zone
16 clarification zone

Claims (6)

1. Device for cleaving emulsions and for the regeneration of cleaning and degreasing baths, in particular by cleavage in an electrophysical cell with an electrocoagulator and subsequent flotation, characterized in that at least two mutually independent electrode devices, each provided with at least one anode and one cathode ( 5 , 6 ) are arranged, each of which has its own circuit and that at least two of the mutually independent electrode devices ( 5 , 6 ) consist of different materials. 2. Apparatus according to claim 1, characterized in that the cathode and anode of each electrode device ( 5 , 6 ) consist of the same material and that the electrode devices are reversible. 3. Device according to claim 1 or 2, characterized characterized that with clocked and variable adjustable voltage operated Electrode devices are arranged. 4. Device according to claims 1 to 3, characterized in that the electrode devices ( 5 , 6 ) are arranged with different material composition interlocking. 5. Device according to claims 1 to 4, characterized in that the electrode devices ( 5 , 6 ) are arranged spatially separated from one another with different material composition. 6. The device according to claim 5, characterized in that in the housing ( 3 ) baffles ( 4 ) for discharging by electrolysis on the soluble electrodes ( 2 ) of the electrode arrangement ( 6 ) are arranged gas.