DE4190516C2 - Electrolytic device for protecting a fresh water piping system against corrosion - Google Patents

Description

Technical field

The invention relates to an electrolytic device for Corrosion protection of a fresh connected to a water tank water piping system, the electrolytic Vorrich device at least two electrodes, which are arranged in the tank, and has a control unit with a power source, and one of the electrodes being an aluminum anode.

Technical background

DE-PS-24 45 903 discloses an electrolytic device for corrosion protection in connection with a water tank standing fresh water piping system, one through the Tank formed cathode and a system of soluble anodes Aluminum and a system of inert anodes, all Anodes arranged in the tank and ver with a DC power source are bound. While using such a device Usually large amounts of digested sludge and Lime (calcium) as deposits on the walls and floor of the Water tanks. The deposits can be cheap growth represent conditions for bacteria, which is why the presence an excessive amount of bacteria in known devices has caused a problem.

US-A-4,063,716 describes a steam generator comprising one Tank with a supply line for water and a drain pipe on the bottom  of the tank. There are three in the top of the tank inert main electrodes arranged. These are with change operated electricity, whereby the water vapor is generated. Ver Avoid incrustation on the main electrodes Alternating current is superimposed on a direct current that is between Main electrodes and an inert one, also in the upper area of the tank attached auxiliary electrode flows. The polarity of the DC current is reversed at regular intervals. By the reversal of polarity loosen incrustations that adhere have formed an electrode in the next step. As an alternative to using an auxiliary electrode, alternating one of the three main electrodes as cathode, the other two operated as an anode, based on the direct current.

EP-A-0 231 100 discloses an apparatus for cleaning contaminated water. The device has a tank in which a number of electrodes, and that side by side alternate selnd anodes and cathodes are arranged. The anodes and Cathodes are preferably made of aluminum. they are connected to a DC power source. Will that of this source le generated direct electrical current passed through the water, so the impurities are excreted and the water ge cleans.

Disclosure of the invention

The object of the invention is an electrolytic Vorrich device of the type known in DE-B-24 45 903 to provide which essentially prevents the bacteria from settling in the Spread device and at the same time protect the Fresh water piping system guaranteed against corrosion.

The electrolytic device according to the invention is thereby characterized in that the other electrode is a cathode Is aluminum and that the electrodes with a pole changer the power source are connected so that the electrodes alternate  working selectively as an anode and cathode. As a result of this Can build up the electrodes and the water between them Electrodes viewed as an isolated electrolytic cell be connected to an alternating power source is. During use of the electrolytic device can therefore the calcareous deposit to a predetermined Range be restricted, d. H. on the electrode that during serves as the cathode for the period in question. If the pole with changed the pole changer, can be on the Cathode formed limescale and sink, whereupon they are washed out. Compared to the well-known electro lytic devices is thereby a significant reduction change in the amount of sludge and lime present in the tank reached. As a result, the bacteria find it less beneficial Growth conditions before, resulting in a lower germ index leads. Furthermore, the electrolytic dissolve during operation Device both electrodes during the time they are as Anodes serve up, gradually, and the dissolved aluminum forms aluminum hydroxide. The aluminum hydroxide has a favorable ge effect, since it is released together with calcium carbonate the inner surfaces of the fresh water piping system with a corrosion-resistant layer covered.

According to the invention, the electrodes can be identical. To this Way is a simple and cheap embodiment of the elek trolytic device achieved.

In addition, according to the invention, at least one additional one soluble anode can be placed in the tank, the anode is made of aluminum or zinc and has its own power supply from the control unit. The additional, soluble anode provides cathodic protection against corrosion of the tank itself.

According to the invention, an electrode can also be a separate derte power supply from the control unit. As a result of this, cathodic corrosion protection of the tank per se achieved without the use of an additional anode, thereby a particularly simple embodiment of the electrolytic Device is obtained.  

In addition, the tank can be conical in accordance with the invention have lower cover plate, the lower tip with a Exhaust valve is provided. By means of gravity a large proportion of the precipitated lime in the conical Tip of the cover plate, d. H. just above the exhaust valve, ge collects, and the washing out of the lime is simplified.

Finally, the electrolytic device fiction according to be constructed so that a flushing ring at the bottom of the tank is provided, which extends near the edge of the tank, the flushing ring being provided with a number of flushing nozzles, and that an outlet valve in the bottom bottom plate of the tank is arranged. This way the electrodes limescale released by changing the poles quickly rinsed.

Brief description of the drawings

The invention is he with reference to the drawing clarifies in the

Fig. 1 is a schematic view of a first form of execution of an electrolytic invention is Before direction, an additional, soluble anode is disposed in the tank,

FIG. 2 is a view of the tank from FIG. 1 cut vertically in the middle on a larger scale, FIG.

Fig. 3 is a plan view of the tank of Fig. 2, wherein the upper cover plate of the tank is removed,

Fig. 4 is a schematic view of a second execution form of an electrolytic invention is Before direction without an additional anode in the tank,

FIG. 5 is a vertical central section view of the tank of FIG. 4 on a larger scale;

Fig. 6 is a plan view of the tank of FIG. 5, the upper top plate of the tank is removed,

Fig. 7 is a schematic view of a modification of the electrolytic apparatus of FIG. 4, wherein the tank is provided with a convex lower cover plate,

Fig. 8 is a vertical central section view of the tank of Fig. 7 on a larger scale, and

Fig. 9 is a top view of the tank of Fig. 8 with the top cover plate of the tank removed.

Best mode for carrying out the invention

The electrolytic device shown in Fig. 1 is intended for corrosion protection of a fresh water piping system (not shown), which is connected to a water tank 1 . The electrolytic device has at least two electrodes 2 and 3 arranged in the tank 1 made of aluminum and a control unit 4 with a power source. The control unit 4 is designed to transform the voltage down from the current source and to rectify it to an appropriately low DC voltage.

The electrodes 2 and 3 are so connected via a pole changer 5 to the positive and negative poles of the voltage source that the electrodes 2 and 3 work alternately as anode and cathode. At a given time, the electrode 2 therefore serves as the anode and the electrode 3 as the cathode. After the subsequent pole change, the opposite is the case, ie the electrode 2 serves as the cathode and the electrode 3 as the anode. In an electrolytic device constructed in the above manner, the electrodes 2 and 3 and the water between them can be seen as an insulated electrolytic cell connected to an AC power source.

As a result, the limescale can be limited to a certain area during use of the electrolytic device, that is, to the electrode, e.g. B. 3, which serves as the cathode during the period in question. When the polarity is reversed by the pole changer 5 , the limescale formed on the cathode 3 is released , whereupon they settle. They are then flushed out through an outlet valve in the bottom of the tank. Compared to the known electrolytic devices, a considerable reduction in the amount of sludge and lime present in the tank is achieved. As a result, the growth conditions for the bacteria are poorer, which leads to a lower germ index.

Further, during the operation of the electrolytic device, the electrodes 2 and 3 made of aluminum gradually dissolve during the period in which they serve as anodes, and the dissolved aluminum forms aluminum hydroxide. The aluminum hydroxide has a favorable effect because it covers the inner surfaces of the fresh water piping system together with the calcium carbonate released with a corrosion-inhibiting layer.

Figs. 2 and 3 show the tank 1 of Fig. 1 in a larger scale and with more details. In this embodiment, two essentially identical, soluble electrodes 2 and 3 made of aluminum have been used. The electrodes 2 and 3 are rod-shaped, arranged diametrically opposite one another within the tank ( FIG. 3) and fastened to the tank 1 in a suitable manner. However, more electrodes, e.g. B. four used. The electrodes must then be divided into two groups with mutually opposite polarity.

As can be seen from FIGS. 1 to 3, at least one, but here two additional, soluble anodes 6 and 7 in the tank 1 are arranged, these anodes made of aluminum, zinc or a similar material and a separate power supply from the control unit Have 4 . The anodes 6 and 7 are attached to the tank 1 in a suitable manner. Since the tank 1 , which is assumed to be made of steel or another metal, is connected to the negative pole of the voltage source and therefore serves as a cathode, the additional anodes 6 and 7 provide cathodic corrosion protection for the tank 1 per se.

The tank 1 of FIGS. 2 and 3 is a hot water tank, which is provided at the bottom with an inlet pipe 8 for cold water and at the head with an outlet pipe 9 for hot water. In its upper section, the tank 1 has a return line 11 for hot water which flows back after it has circulated in the hot water circuit, the return line 11 being provided with a circulation pump 10 . The water in the tank 1 is heated by water from the tank which flows through an outlet line 12 , through a heat exchanger (not shown) in which the water is heated, and flows back to the tank 1 through an inlet line 13 .

As shown in FIGS. 1 and 2, the tank is provided with an upper, convex cover plate 14 which has a vent line 15 with a check valve. At the bottom of the tank 1 is provided with a lower, conical cover plate 16 , in the lower tip of which an outlet valve 17 or a mud tap is arranged. By gravity, therefore, a large proportion of the precipitated lime settles in the conical tip of the cover plate 16 , ie exactly above the outlet valve 17 , which makes it easier to flush out.

As can be seen from FIGS. 2 and 3, the tank 1 has a flushing ring 19 which extends near the edge 18 of the tank and which is provided with a number of flushing nozzles 20 . At the end of the inlet line 8 for cold water, an upper inlet valve 21 and a lower inlet valve 22 are connected in parallel to one another. The upper inlet valve 21 leads into the tank 1 , while the lower inlet valve 22 leads into the flushing ring 19 . When the deposited limescale and other sludge are to be flushed out, the inlet valve 21 is closed and the inlet valve 22 is opened. Cold water is then passed into the rinsing ring 19 , from which the water is sprayed diagonally down towards the cover plate 16 through the rinsing nozzles 20 , which have previously been set in this direction. Lime and sludge are quickly flushed from the cover plate 16 and flushed out through the outlet valve 17 . A controller 23 may be designed to automatically close the valve 21 at predetermined intervals, open the valve 22 , stop the circulating pump 10 and open the exhaust valve 17 to allow purging to take place.

Fig. 4 shows a second embodiment of the electrolytic device, in which an electrode 2 or 3 also has a special power supply from the control unit 4 . As a result, cathodic corrosion protection of the tank 1 per se is achieved without the use of an additional anode - see the anode 6 in FIG. 1 - which results in a particularly simple and inexpensive embodiment of the electrolytic device.

FIGS. 5 and 6 show the tank 1 of FIG. 4 in a larger scale and with more details. The two additional anodes 6 and 7 are omitted, which enables many different arrangements of the electrodes 2 and 3 .

FIG. 7 shows a modification of the electrolytic device from FIG. 4, in which the tank 1 'is provided with a convex lower cover plate 16 '.

FIGS. 8 and 9 show the tank 1 'of FIG. 7 in a larger scale and with more details. By using a convex cover plate 16 'instead of a conical cover plate, the tank 1 ' has a lower height, which leads to a more compact structure.

Above is the electrolytic device in connection been described with a hot water tank. However, it can can also be used with a cold water tank.  

The electrodes 2 and 3 and the additional anodes 6 and 7 can have any suitable shape and position according to the given use of the electrolytic device.

The device is significantly cheaper if no flushing ring 19 is used, see FIGS . 2, 3; 5, 6 and 8, 9.

The tank 1 is preferably made of steel or another metal, but can also be made of another material, e.g. B. be plastics. If the tank is made of metal, it can have a surface layer of e.g. B. plastic fen, enamel or paint.

Claims (6)

1. Electrolytic device for protecting a fresh water piping system connected to a water tank ( 1 , 1 ') against corrosion, the electrolytic device comprising at least two electrodes ( 2 , 3 ) which are arranged in the tank ( 1 ; 1 ') and one Control unit ( 4 ) with a power source, and wherein one of the electrodes ( 2 ) is an anode made of aluminum, characterized in that the other electrode ( 3 ) is a cathode made of aluminum and that the electrodes ( 2 , 3 ) with the current source are connected via a pole changer ( 5 ) in such a way that the electrodes ( 2 , 3 ) work alternately as anode and cathode. 2. Electrolytic device according to claim 1, characterized in that the electrodes ( 2 , 3 ) are identical. 3. Electrolytic device according to claim 1 or 2, characterized in that at least one soluble, additional anode ( 6 , 7 ) is arranged in the tank ( 1 ), this anode made of aluminum or zinc and a separate power supply from the control unit ( 4 ). 4. Electrolytic device according to claim 1 or 2, characterized in that an electrode ( 2 or 3 ) further comprises a separate power supply from the control unit ( 4 ). 5. Electrolytic device according to one of claims 1 to 4, characterized in that the tank ( 1 ) is provided with a conical lower cover plate ( 16 ), the lower tip of which has an outlet valve ( 17 ). 6. Electrolytic device according to one of claims 1 to 4, characterized in that at the bottom of the tank ( 1 ; 1 ') a near the edge ( 18 ) of the tank extend the flushing ring ( 19 ) is arranged, with a number of flushing nozzles sen ( 20 ) is provided, and that an outlet valve ( 17 ) is arranged in the lower cover plate ( 16 ; 16 ') of the tank.