DE4107708A1 - Treating water against calcium deposits - in which water flows through spring-loaded cavitating injector and then passes between electrodes of uneven surface finish - Google Patents

Abstract

Process consists of subjecting the water to cavitation and an alternating electric field. The water (W) is passed from the inlet (Z) through an injector (1) which operates in accordance with the flow rate of the water. The water is then passed between electrodes with an uneven surface structure so that it moves through areas of greater and lesser electrode surface separation. The device has a cavitation chamber (K) which contains the injector, and at least two electrodes (E1,E2) to which a pulsing alternating voltage is applied., The injector consists of a sealing element (K1) which is pushed back against a spring force (V) by the incoming water pressure. The electric field is switched on only when the water is flowing, as indicated by a device (M,H) which senses movement of the element (K1). At least one of the electrodes has a woven metallic surface structure whose connection points form projections which make up the required uneven surface finish. USE/ADVANTAGE - Used in treatment of water to prevent calcium deposits. The effectiveness of existing devices of similar type is further improved.

Description

The invention relates to a method and an apparatus for Treating water against limescale deposits by cavitation and an alternating electric field with a cavitation chamber and at least two electrodes to which alternating current pulses lie and between which the water flows.  

There are a number of physical water treatment processes drive whose goal is to create turbulence, Cavitation or the application of alternating current impulses flow of lime-carbon dioxide equilibrium. So are described in the patents DE 38 07 876, EP 00 68 760, EP 02 77 112 and EP 02 86 137 methods and devices beat by means of a variable throttle point in the Flow path Turbulence or cavitation in the flowing medium be generated. The turbulences mentioned are said to be in DE 38 07 876 support the effect of a magnetic field, the also attributed an effect - treating the water becomes. Another patent describes a method in which is initially a swirling body in the flow path of the water for its swirling and then the water between two smooth electrode bodies is passed through which electrical AC pulses are applied (DE 38 28 825).

Because the effect of the known methods as insufficient is considered, it is the aim of the present invention that Further improve efficiency.

It is therefore an object of the invention, a method and a Device to enable the efficiency of the genus according to the method and the generic device still improve further.

This task is solved according to the requirements.

According to the water flow on the input side by a ge depending on the water flow injector passes. This creates cavitation and thus zones in the water to be treated, in which the pressure drops significantly below the ambient pressure. There is a local outgassing of the CO ₂ dissolved in the water. At the same time, as a result of the decrease in the CO ₂ concentration in the water, the lime-carbonic acid balance is disturbed. This leads to a reduction in the HCO ₃ ⁻ concentration and thus to a deterioration in the calcium solubility (the water becomes more lime-separating). This solution is now passed through an alternating electrical field. The special electrodes used are designed so that a variety of surface elevations, for. B. knobs, lead to specific areas with a smaller electrode spacing than in the area and thus to a high current density. As a result, it is possible to achieve the desired treatment effect with low voltages.

In these areas of high current density, the negatively charged electrode is concentrated in the positively charged calcium ions. At the same time, (OH) ions arise in the area of this electrode, which lead to a spatially limited increase in the pH value and thus to a shift in the lime-carbonic acid equilibrium from the HCO ₃ ⁻ to the CO ₃ ^2- . The above-mentioned Ca ²⁺ ions precipitate on the electrode elevations together with the carbonate ions as poorly soluble CaCO ₃ (lime). In this way, a microfine lime crystal forms on each electrode elevation.

From the next electrical half wave, the electrodes reversed the polarity and the crystals formed from the now positively gela which electrode - on which H⁺ ions are formed - blasted off. These crystal nuclei are entrained by the inflowing water tore. This way, each electrode will be proportional  on the frequency and the number of surface surveys of the elec trode a large number of crystal nuclei formed.

At these crystal nuclei, especially when heating the water, further CaCO ₃ accumulates, so that these crystals become larger depending on the lime deposit tendency of the water, but are still in the size range of only a few thousandths of a millimeter.

The outgassed CO ₂ partially goes back into solution in areas of low temperature (i.e. outside the area of heating elements etc.) and leads to a greater tendency towards lime dissolving of the treated water via an associated, slight lowering of the pH value. In this way, the crystal nuclei formed are partly dissolved again, but partly also limescale encrustations on the inner tube wall. However, the large, relatively reactive surface of the suspended crystal nuclei reliably prevents the corrosion protection layer on the inside of the tube from being removed down to the metal.

The invention is explained in more detail below with the aid of the drawing described. Show it:

Fig. 1 schematically shows a schematic diagram of the device according to the Invention; and

Fig. 2 shows a central section through a preferred embodiment of the device according to the invention, the water-treating parts of which are essentially circularly symmetrical.

First of all, the principle according to the invention is explained on the basis of the diagram shown in FIG. 1. The water W enters a cavitation chamber K through a water inflow Z. In the Kavita tion chamber K, a throttle point D forming injector is arranged, which works depending on the water flow. In principle, this injector I consists of a centrally arranged and axially movable sealing body K 1 , which is biased by a bias spring V to form an opening between an outer body in the cavitation chamber K as a function of the amount of water flowing through or as a function of the water pressure. On one end face of the central processing body K 1 , a permanent magnet M is arranged opposite a Hall sensor H. After flowing through the cavitation chamber K, the water enters a treatment room B in which, for. B. two parallel electrodes E 1 and E 2 are arranged.

Of course, the principle according to the invention is not limited to two electrodes. It is essential that the electrodes E 1 and E 2 have an irregular surface structure and therefore areas in the field space F between the electrodes are formed with a smaller distance and therefore a higher instantaneous field strength.

This irregular surface structure can e.g. B. by pimples like projections N or the protruding binding points of a metal mesh.

With a predetermined water flow rate through the cavitation chamber K, the Hall probe generates an electrical signal L 1 , which is entered into an electrical control unit S, as soon as the permanent magnet at the bottom of the central sealing body K _{1 has a} sufficiently small distance from the Hall probe H which then applies electrical alternating current pulses L 2 and L 3 to the electrodes E 1 and E 2 .

With reference to FIG. 2, which shows a central section through a substantially radially symmetrical apparatus according to the invention, construction and operation will now be described in this preferred embodiment. The entire device is essentially umschlos sen by three screwed together radially symmetrical base bodies 21 , 22 and 23 . In the screwed state, these base bodies 21 , 22 and 23 are sealed against one another and to the outside by respective sealing rings 24 and 25 .

At a central point, two sealing bodies 2 and 3 , which are movable to and fro in the axial direction, are arranged, the first sealing body 2 being surrounded by the second sealing body 3 and being movable therein. Between the first and the second sealing body 2 and 3 , an annular gap 4 is easily seen, which opens when the sealing body 2 and 3 have been pushed in the direction of the Hall sensor 31 and the sealing device body 2 on the Hall sensor has reached its attachment point . The water Z flowing in at 1 can flow through this annular gap with a small water flow. Cavitation is already generated. The second sealing body 3 is sealed to the inner wall surface of a cylindrical wall body 27 by a sliding seal 5 , which allows axial movement of the two sealing body. This axial movement takes place against the pretensioning of a helical spring 19 arranged axially symmetrically around the second sealing body.

The water flowing through the annular gap 4 goes through opening bores 20 , 20 'in the second sealing body and can then flow into an electrical treatment room 6 , in which axially symmetrical electrodes 7 , 7 ' are arranged. Between the two electrodes 7 and 7 ', the water flows radially outwards through stanchions 10 provided in the peripheral region of a baffle plate 9 , 9 ' and then in a return flow chamber 11 radially inwards to the outlet connection 30 of the device and continues to flow as outflowing water A. A permanent magnet 32 is embedded in the end face of the first sealing body 2 opposite the water inflow side. In contrast to this, a Hall sensor 31 is provided, which is connected to control electronics 16 . When the first sealing member 2 and the recessed in its front side permanent magnet of the Hall sensor 31 almost touched, the Hall sensor 31 outputs a signal to the control electronics 16) and this switches the electric Wech selfeld for the electrodes 7 and 7 ', a . The electrical alternating current pulses are supplied from the control electronics 16 via connections 14 , 15 to the electrodes 7 , 7 '.

With a large water flow, the second sealing body 3 is pushed so far to the right that it is no longer sealed by means of its sliding seal 5 against the inner wall of the cylinder wall body 27 . Instead, 27 holes 13 and 13 'are opened for the main water flow in the cylinder wall body. (This position is shown in Fig. 2). Again, cavitation occurs when water passes and the alternating electrical field between the electrodes 7 , 7 'exerts the described effect on the water flowing through the treatment room 6 .

The entire device is covered by a cover 18 , in the wall of which an indicator lamp 8 is seated, which, for. B. lights up as soon as the alternating electrical field is applied to the electrical 7 , 7 '. Alternatively, a fault display can also be provided as a display. The control electronics 16 is provided by a voltage source 17 with electrical voltage ver.

Claims (8)

1. A method for treating water against limescale deposits by cavitation and an alternating electric field which is present between at least two electrodes through which the water treated by cavitation is passed, characterized by the following steps:

• - Passing the water on the inlet side through an injector that works depending on the water flow; and
• - Conduct the water pretreated in this way between electrodes with an irregular surface structure, so that the water flows through areas of smaller electrodes and through areas of further electrode spacing.

2. The method according to claim 1, characterized in that the water flow monitors and the alternating electric field only the electrodes is created when the water flows. 3. Device for treating water against limescale deposits by cavitation and an alternating electrical field with a cavitation chamber (K) and at least two electrodes (E 1 , E 2 ; 7 , 7 '), to which AC pulses are present and between which the water flows, thereby featured,
that an injector (I; 2 , 3 ) operating in dependence on the water flow is provided in the cavitation chamber, and
that the cavitation chamber in the flow direction is an electrode arrangement (E ₁ , E ₂ ; 7, 7 ') through which the water flows, the electrodes of which have an irregular surface structure, so that when the electrical alternating field is applied, electrode areas with a narrow electrode spacing have a higher current density. 4. The device according to claim 3, characterized in that at least one electrode Has metal mesh, the binding points of surfaces represent surveys and thus to the described irregular surface structure. 5. The device according to claim 3, characterized in that the device is constructed substantially radially symmetrical to a central axis of the injector,
the electrode arrangement has at least two circular disk-shaped electrodes ( 7 , 7 ') which are arranged parallel to one another at a distance,
the injector ( 2, 3 ) projects coaxially through a central circular opening into the electrode space and consists of a first and a second sealing body ( 2 , 3 ) movable in the axial direction, each against a bias, of which the first sealing body is inside the second Sealing body is arranged back and forth and an annular gap ( 4 ) between the outer wall of the first sealing body and the inner wall of the second sealing body is opened even at low water pressure. 6. Device according to one of claims 3 to 5, characterized in that a flow monitor is provided which only applies the alternating electrical field to the electrodes ( 7 , 7 ') when water flows into the device. 7. The device according to claim 6, characterized in that the flow monitor is formed by a Hall sensor ( 31 ) and a movable relative to the Hall sensor ( 31 ) on an end face of the first sealing body ( 2 ) arranged permanent magnets ( 32 ). 8. Apparatus according to claim 6 or 7, characterized in that control electronics ( 16 ) receives a signal from the flow monitor and then the alternating electrical field applies the electrodes ( 7 , 7 ').