NO169532B - PROCEDURE FOR THE TREATMENT OF A VARIOUS LIQUID AND DEVICE FOR IMPLEMENTATION OF THE PROCEDURE - Google Patents

Abstract

According to the process used in particular for removing scale and corrosion, and to prevent the formation of scale and corrosion in vessels and pipelines through which the liquid to be handled passes, the liquid is fed during treatment, through a treatment chamber (1), on the side of which is arranged an electrode (4), which is electrically insulated from the liquid. A high-voltage source (8) is connected via a high-voltage terminal (7) with the electrode (4) and the other terminal (10) is connected electrically with the liquid.

Description

The invention relates to a method for treating an aqueous liquid, where this liquid in flow between two opposite electrodes, which are separated from the liquid by insulating material, is subjected to the influence of an electric field, in order to remove scale and corrosion, respectively to prevent scale formation and/ or corrosion in the containers or pipe systems through which the liquid flows. The invention also relates to a device for carrying out the method, with a treatment room provided with an inlet opening and an outlet opening and with two oppositely arranged electrodes on both sides of the treatment room, electrically isolated from the treatment room, and further with a high-voltage electric source connected to the electrodes.

Depending on the different types of substances in the water, especially lime dissolved in the water, scale and corrosion will form in containers and pipelines where the water is exposed to physical influences, for example intensive heating in hot water boilers and steam boilers. It is known that you can counteract the "unwanted precipitation of such substances, which give rise to the formation of scale, and that you can counteract the occurrence of corrosive properties in the water by exposing the water to an electric and/or magnetic field before the water runs to the containers or pipelines where the water will be exposed to the special conditions. In this way, the tendency to material precipitation and the tendency to develop corrosive properties in the water can be reduced to a greater or lesser extent, and it is also possible to reduce the formation of scale and corrosion, which occurs in containers or pipelines when untreated water is supplied to these, by the containers or pipelines being fed with water treated in the above-mentioned manner. The impact of magnetic and/or electric fields on the water or aqueous liquids will also depend to a significant extent on the physical conditions affecting the water or the aqueous liquid after such a pre-treatment.Thus it decreases with the hitherto known methods the effect obtainable is stronger the higher the thermal loads to which the pre-treated water is subjected. Various known devices only have a modest effect, and these devices often have a proportionately demanding structure. They require constant expensive maintenance and for this reason alone are unlikely to be suitable for general use. Many of these devices require the connection of special filters, which means increased acquisition and maintenance costs.

It is an aim of the present invention to provide a method and a device of the type mentioned at the outset, with which a better effect can be achieved than with the known methods of the type in question here, and which can be realized on simple way, with low costs.

From US-PS 4,073,712, a device is known for treating water by means of an electrostatic field between a pair of concentric cylindrical electrodes, both of which are insulated from the water flowing between them. One of the electrodes is connected to the positive terminal of a direct current source, while the other electrode is connected to the negative terminal of the direct current source. There is no electrically conductive connection with the water. The water therefore flows isolated between two electrodes with different polarity.

GB-A 1,274,902 also shows the treatment of water with an electrostatic field between a pair of electrodes. One electrode is connected to the positive terminal of the direct current source, while the other electrode is connected to the negative terminal. At least one of the electrodes is insulated from the water. This means that one of the electrodes can have an electrically conductive connection with the water (the design in Fig. 6,7 in GB-PS. The water thus flows between two electrodes with different polarity.

Neither US-PS 4,073,712 nor GB-A 1,274,902 enables a treatment between two electrodes, particularly advantageously two planar electrodes, with the same potential and polarity, where both are isolated in relation to the water and are connected to one pole or terminal of a direct current source, while the water itself is connected to the other pole or terminal of the direct current source.

The method according to the invention is characterized by the fact that the liquid to be treated is subjected to the electric field effect which is formed by an equal-high voltage potential, one pole of which is connected to the two aforementioned, mutually opposite and isolated from the liquid electrodes and the other pole of which is electrically conductively connected to the liquid. With this method, the aforementioned objectives can be achieved in a satisfactory manner. It is to be assumed that the advantageous properties of the method according to the invention are due to the fact that the water or the aqueous liquid is subjected to a change in the area of the surface layers flowing along the insulation of the electrode or the electrodes, as this change counteracts the precipitation of substances from the liquid and the occurrence of corrosive properties in the liquid. In this context, it should be mentioned that aqueous liquids react to the described field effect because the water molecules themselves represent dipoles and the (dissolved or undissolved) substances of a positive or negative nature contained in the water exist as ions and can therefore be arranged in accordance with the polarity. When preparing boiling water using rod heaters, it has been found in practical experiments that the deposits that occur when heating strong, calcareous water can be reduced to less than 1/4 of those found when using untreated water if the water is pre-treated in a determined, the quantity of water used for the preparation of the boiling water. By using the water pretreated with the method according to the invention, the advantageous effect was also achieved that the amount of deposits on the rod-shaped heating elements during the preparation of boiling water does not exceed a certain limit value, even after a very long operating time. It was also found that deposits or boiler scale, which previously formed when using untreated water for the preparation of boiling water, were clearly broken down by the subsequent use of water treated with the method according to the invention. It appears that the absolute value of the applied high voltage plays less of a role in the effect that can be achieved. On the other hand, the electric field strength present on the electrode(s) or in the insulation thereof against the liquid forming the electrode layer seems to be of importance and in this connection also the charge density in the liquid as well as the electrode surface. When using several or two mutually opposite electrodes, between which the liquid is directed, the electrode distance is also important.

It is possible to lead the liquid to be treated over an electrode arranged on one side of the liquid flow. At the same value of the applied high voltage, a significantly better effect is achieved if the liquid is led between two electrodes which have a high voltage potential of equal polarity to the liquid, and therefore this embodiment of the method according to the invention is preferred.

If, as mentioned above, one exposes the liquid to an electric field effect formed with an equal-high voltage potential, then for the desired achievement of the greatest possible braking of the precipitation of substances in the liquid, it will be advantageous if the liquid in the electrode area is kept at a level in relation to the electrode(s) negative potential. However, it is also possible to keep the liquid in the electrode area at a positive potential in relation to the electrode(s) and thus prevent the migration of liquid particles or substances into the insulation covering the electrode.

The effect of the treatment of the liquid carried out with the method according to the invention can be significantly improved if the liquid in the electrode area is given a flow direction of approximately 180°.

The device according to the invention is characterized by the fact that the two mutually opposite electrodes are electrically connected to each other and that one connection of the electric high-voltage source is connected to the two electrodes, while the other connection of the electric high-voltage source is connected to a connection electrode that provides an electrically conductive connection with the liquid, and in that the high voltage source is a direct voltage source. It would also be beneficial if the high-voltage source's positive connection is connected to the electrically insulated electrode or electrodes, while the negative connection is connected to the connection electrode that provides the electrically conductive connection with the liquid.

In a simple way, a favorable shape for the treatment of the liquid is achieved by the liquid surface flowing along the electrodes if you ensure that the treatment room has the shape of a flat box, on the two flat sides of which a respective electrode is arranged, as these electrodes are electrically conductively connected to each other . The treatment effect achievable with the device can be further improved in a simple way if it is ensured that a U-shaped flow-through section is formed in the treatment room by means of a step and the openings for the inflow and outflow of the liquid are arranged next to each other, but on each his side of the step. With regard to the constructive design of the facility's treatment room and the arrangement of the insulated electrodes used for the treatment of the liquid flowing through the treatment room, which electrically form capacitor plates, it is particularly advantageous if the box consists of two box halves made of plastic in whose flat wall sides the insulated electrodes are inlaid, as the box halves are arranged between two tension plates made of metal and are compressed between them. The individual components in this embodiment of the device according to the invention can be produced in a simple manner, and good protection of the insulated electrodes is ensured both electrically and mechanically. In addition, the electrodes are also well protected against chemical influences. Furthermore, should this turn out to be necessary or desirable, maintenance and cleaning of the device can take place in a simple way precisely as a result of the construction of the box in the form of two box halves made of plastic, which enables easy dismantling of the device. In and of itself, however, it must be emphasized here that the device according to the invention is practically maintenance-free. The two clamping plates provide a mechanically very stable structure which also gives the box a high compressive strength. Furthermore, these clamping plates will not only provide good mechanical protection for the box, but will also provide effective electrical shielding, which is advantageous for safety reasons.

The treatment of aqueous liquids with the method according to the invention and with the device according to the invention is not only important for avoiding precipitation of substances and for slowing down corrosion in containers or in the pipelines through which the liquid flows, as well as for the subsequent breakdown of the boiler stone and corrosion damage that has already occurred. The property changes given to the liquid as a result of the treatment according to the invention can also be used in various other areas. For example, the treatment according to the invention offers an opportunity for conditioning swimming pool water with lower chemical addition than usual. Thus, a specific disinfection effect can be achieved with less chlorine addition than hitherto usual in connection with untreated water, and a pH value correction of the swimming pool water can also be achieved with less additions of pH~ or pH<+->substances.

It should be mentioned in particular that with the method according to the invention, in practice, there is no current line between the electrically conductive liquid connected to a high voltage potential relative to the insulated electrode and the electrically insulated electrode. At most, an insignificant leakage current can occur in the final insulation resistance formed by the insulation material covering the electrode. In the method according to the invention, the treatment effect will be significantly influenced by the field strength and the charge density in the surface layer of the liquid facing the insulated electrode.

The invention will now be explained in more detail with reference to the examples shown in the drawings.

The drawings show:

Fig. 1 a first embodiment of a device

according to the invention,

fig. 2 shows this embodiment in section along the line

II-II in fig. 1, and

fig. 3 shows this embodiment in section according to the line

III-III in fig. l.

Fig. 4 shows the connection in connection with a high-voltage source and

fig.-5 and 6 show a further embodiment in two sections,

as fig. 5 shows a section along the line V-V in fig. 6, and fig. 6 shows a section along the line VI-VI in fig. 5.

The one in fig. The embodiment shown in 1-3 of a device designed according to the invention has a treatment room 1 through which the liquid to be treated flows. Inlet and outlet openings 2,3 are provided for the inflow and outflow of the liquid. The flow direction is arbitrary. An electrode 4,5 is arranged on both sides of the treatment room 1. These are electrically isolated from the treatment room 1. The electrodes 4,5 are electrically conductively connected to each other by means of a wire 6. The one connection 7 for an electrical high-voltage source 8 is connected to the electrodes 4,5. The high-voltage source 8 is supplied with electrical energy, for example from an electrical power supply network, via the clamps 9. The second high-voltage connection 10 is connected to a connection electrode 11. This connection electrode forms an electrically conductive connection with the aqueous liquid located in the treatment room 1. The connection electrode 11 can, as shown in fig. 1-3, be a separate electrode arranged in the treatment room 1, but this connection electrode can also be formed by other metallic conductive parts that have a connection with the liquid that flows through the treatment room 1. This could, for example, be metal pipes that lead to devices ning's inlet or outlet opening.

The high-voltage source 8 can be designed as a capacitor-rectifier, cascade connection, as shown in fig. 4. You can also use other designs of high-voltage sources, for example so-called switching network parts with high-voltage output, and you can, if desired, supply the high-voltage source with an isolation transformer to thereby separate it galvanically from the power supply.

The treatment room 1 has the shape of a flat box which consists of two box halves 14,15 made of plastic. The electrodes 4,5 are embedded in the flat wall sides 16,17 of the box halves 14,15. The box halves 14,15 are arranged between two metal clamping plates 18,20 which are held together by means of clamping screws 21. By means of the clamping plates 18,20, the box halves 14,15 are pressed together. Between the opposite edges of the box halves 14, 15, a sealing ring 22 is inserted.

In the treatment room 1, a step 23 formed by ribs formed on the box halves 14,15 is arranged which forms a U-shaped flow-through section in the treatment room 1. This flow-through section is shown in fig. 1 shown with an arrow 24 and runs from the inlet opening to the outlet opening. These openings 2,3 are arranged next to each other, but on opposite sides of the step 23.

In the case of practically implemented devices, intended for treating water to prevent the formation of scale or to remove scale, a high voltage of between 3.5 and 6 kV was used, preferably a high voltage of 5 kV. The walls 16,17, which separate the electrodes 4,5 from the water in the treatment room 1, had a thickness of 3 mm.

At the 1 fig. 5 and 6 shows the embodiment of a device according to the invention, the treatment room 1 has an oblong shape and is designed as a cavity in a plastic container 26 in whose walls 27,28 the electrodes 4,5 are embedded. Analogous to the embodiment in fig. 1-3, the electrodes 4,5 are electrically connected to each other by means of a wire 6 and are located on a high-voltage connection 7 in a high-voltage source 8. The second high-voltage connection 10 is located on a metallic pipe through which the liquid medium flowing from the treatment room 1 passes.

Claims (9)

1. Method for treating an aqueous liquid, where this liquid in flow between two opposite electrodes, which are separated from the liquid by insulating material, is subjected to the influence of an electric field, in order to remove scale and corrosion, respectively to prevent scale formation and/or corrosion in the containers or piping systems through which the liquid flows, characterized in that the liquid to be treated, is subjected to the electric field effect formed by an equal-high voltage potential, one pole of which is connected to the two mentioned, mutually opposite and isolated from the liquid electrodes (4,5) and whose other pole is electrically conductively connected to the liquid. 2- Method according to claim 1, characterized in that the liquid in the electrode area is kept at a negative potential in relation to the electrode/electrodes (4,5). 3. Method according to claim 1 or 2, characterized in that the liquid is subjected to the field effect between two essentially planar, mutually conductive connected electrodes (4,5) and the fluid flowing between them. 4. Method according to one of claims 1-3, characterized in that the liquid in the electrode area is subjected to a flow direction change of approximately 180°. 5. Device for carrying out the method according to one of claims 1-4, with a treatment room (1) provided with an inlet opening (2) and an outlet opening (3) and with two on both sides of the treatment room oppositely arranged electrodes (4,5) electrically isolated from the treatment room, and further with a high-voltage electrical source (8) connected to the electrodes (4,5), characterized in that the two mutually opposite electrodes (4,5) are electrically connected to each other and that the high voltage source's (8) one connection (7) is connected to the two electrodes (4,5), while the high voltage source's (8) other connection (10) is connected to a connection electrode (11) which provides an electrically conductive connection with the liquid, and in that the high voltage source (89) is a DC high voltage source. 6. Device according to claim 5, characterized in that the positive connection of the high-voltage source (8) is connected to the electrodes electrically isolated from the liquid and that the negative connection of the high-voltage source is connected to the connection electrode that provides the electrically conductive connection with the liquid. 7. Device according to claim 5 or 6, characterized in that the two electrodes (4,5) standing in mutually electrically conductive connection are arranged on a respective flat side of a treatment room (1) designed as a flat box. 8. Device according to claim 7, characterized in that a U-shaped flow path is formed in the treatment room (1) by means of a step (23), and that the openings (2,3) for the liquid's inlet and outlet are arranged next to each other, on each side of the step. 9. Device according to claim 7 or 8, characterized in that the box consists of two box halves (14,15) made of plastic, in whose flat wall sides the insulated electrodes (4,5) are embedded, the box halves being arranged between two metal tension plates (18 ,20) and are pressed together using these.