EP0211015A1

EP0211015A1 - Method and device for eliminating scale and corrosion or for preventing the formation of scale and corrosion

Info

Publication number: EP0211015A1
Application number: EP19860900711
Authority: EP
Inventors: Gerhard Eibl; Gerätebau Ges.m.b.H. & Co. KG Maitron
Original assignee: EIBL Gerhard; Maitron Geraetebau GmbH
Current assignee: EIBL Gerhard; Maitron Geraetebau GmbH
Priority date: 1985-01-22
Filing date: 1986-01-21
Publication date: 1987-02-25
Also published as: WO1986004321A1; ATA15685A; AU5355286A

Abstract

Pour éliminer ou empêcher la formation du tartre et la corrosion on fait agir pendant une courte période un champ électrique à haute tension et un champ magnétique à haute intensité. Le dispositif présente une enceinte de traitement (1), disposée entre deux plaques de condensateur (4, 5), parcourue par le liquide. En plus, le dispositif présente une bobine d'un circuit oscillant (6, 7), dont le champ magnétique traverse l'enceinte (1) et un interrupteur (16) qui connecte pendant de courts instants la bobine au circuit.To eliminate or prevent scale formation and corrosion, a high voltage electric field and a high intensity magnetic field are made to act for a short period. The device has a treatment enclosure (1), arranged between two capacitor plates (4, 5), traversed by the liquid. In addition, the device has a coil of an oscillating circuit (6, 7), the magnetic field of which passes through the enclosure (1) and a switch (16) which connects the coil to the circuit for short moments.

Description

Method and device for removing scale and corrosion or for preventing scale and corrosion

The invention relates to a method for removing scale and corrosion or for preventing scale and corrosion from forming in a liquid, e.g. Water, flowed pipe system by physical treatment of the liquid flowing through the pipe system and on a device for performing the method.

Devices of the aforementioned type are known in which the water is conducted in a turbulent flow through a magnetic field. To form the magnetic field, permanent magnets or coils are provided, which are fed with mains-frequency or low-frequency current or also with direct current. The effect of this known device is insufficient in practice, and as a result the manufacturing costs of the known devices are frequently of considerable size, and there is a further disadvantage, which is present in the known devices, that they require regular maintenance when the devices are used no special filters are connected upstream, but such an upstream connection of filters causes additional purchase and maintenance costs.

It is an object of the present invention to provide a method and a device for carrying it out which have a better effect than the known methods or devices of the type mentioned at the outset and which can also be implemented in a simple manner with little effort. To this end, the invention provides a method for removing scale and corrosion or for preventing scale and corrosion from forming in a pipe system through which a liquid, for example water, flows, by physical treatment of the liquid flowing through the pipe system, which is characterized in that the liquid both the action of an electrical high-voltage field as well as the action of a strong magnetic field, which is effective for short periods of time, which are separated from longer breaks. The invention also provides an apparatus for carrying out the method according to the invention. This device is characterized in that the device has a treatment chamber arranged between two capacitor plates for the flow of the liquid, a resonant circuit coil arranged in the region of the treatment chamber, the magnetic field of which passes through the treatment chamber, a DC high-voltage source which contains the capacitors and the resonant circuit coil The resonant circuit feeds, and has a switch element that briefly switches on the current flow through the resonant circuit coil. The above-mentioned objectives can be met well by the measures provided according to the invention. This technique achieves a very good effect in removing scale and corrosion as well as preventing scale formation, which effect can be achieved at higher thermal loads on the heated surfaces than in the previously known methods in which Water to prevent the formation of scale is subjected to a physical treatment, and it this effect can be achieved with little equipment and with very little energy.

In the method according to the invention, it is advantageous if the liquid is subjected to the action of an electrical high-voltage field, which is a high-frequency electrical field.

A preferred embodiment of the method according to the invention, which has the advantages of having a good effect and being easy to implement, is characterized in that the liquid is subjected to the action of an electrical high-voltage field which consists of a slowly changing or constant component and a high-frequency component. With regard to the magnetic field, these advantages can be achieved in a simple manner by subjecting the liquid to the action of a magnetic field which is generated by an electrical current flowing briefly through an electrical resonant circuit.

An embodiment of the device according to the invention is advantageous for achieving a high magnetic field strength with low construction costs, which is characterized in that the high-voltage source has a storage capacitor at its output. It is particularly advantageous if the oscillating circuit coil is connected in series between the high voltage source and the capacitor plates arranged in the treatment room.

In the device designed according to the invention, simple circuitry can be achieved if it is provided that the switching element closes a circuit which leads from one to the other of the capacitor plates arranged on the treatment room. The switch element is preferably a spark gap. Other, in particular electronic, switch elements can also be used; A spark gap is particularly simple and reliable and can also be designed to be adjustable in its striking distance in a simple manner, and the sequence frequency of the magnetic field effects provided in the method according to the invention can be set in this way.

To achieve a very high frequency of the magnetic field, an embodiment of the device according to the invention is advantageous, which is characterized in that in the circuit leading from one to the other capacitor plate there is a coil belonging to the resonant circuit, the magnetic field of which acts on the liquid to be treated.

With regard to the constructive design of the treatment room of the device and the arrangement of the condenser plates serving for the treatment of the liquid flowing through the treatment room, an embodiment is advantageous which is characterized in that the treatment room is formed by a vessel made of insulating material with inflow and outflow openings , in the insulating walls of which the capacitor plates are arranged. This embodiment can be easily manufactured and ensures good protection of the capacitor plates both in electrical as well as in mechanical and chemical terms. The effect of the device can be further improved if it is provided that the vessel forming the treatment room is designed as a flat box and in this there is a web forming the treatment room into a U-shaped flow path, the openings for the inlet and for the drain lie adjacent to each other on one side of the web and the capacitor plates extend over the entire treatment room.

A structure that can be easily dismantled for maintenance of the device, as well as a stable construction and good electrical shielding of the electrical components of the device from the outside, is provided in one embodiment of the device according to the invention, which is characterized in that the vessel forming the treatment space is formed from two can halves, which are inserted between two metal clamping plates and are pressed together by these clamping plates.

The invention will now be further explained on the basis of preferred embodiments, which are shown schematically in the drawing.

The drawing shows:

1 shows a first embodiment of a device according to the invention in a view,

2 shows the device according to FIG. 1 in a section along the line A-B in FIG. 1,

3 shows this device in a section along the line C-D-E in FIG. 1,

Fig. 4 is a circuit diagram of the high voltage source provided in the device, and

5 shows an overall circuit diagram of the device;

Fig. 6 shows another embodiment of a device according to the invention in a view.

7 shows this device in section along the line A-B in Fig. 6th

Fig. 8 is a section along the line C-D in Fig. 6, and

Fig. 9 is an overall circuit diagram of this device. The device shown in FIGS. 1 to 5 has a treatment room 1 through which the liquid to be treated flows. Inlet and outlet openings 2, 3 are provided for the inlet and outlet of the liquid to be treated. The direction of flow is arbitrary.

The treatment room 1 is located between two capacitor plates 4, 5. Furthermore, two resonant circuit coils 6, 7 are arranged in the area of the treatment room 1, the magnetic field of which passes through the treatment room. The liquid in the treatment room 1 is thus subjected both to the action of the electrical field formed by the capacitor plates 4, 5 and to the action of the magnetic field formed by the resonant circuit coils 6, 7.

In the device according to FIGS. 1 to 5, the encoder plates 4, 5, as shown in FIG. 5, are connected to one via the resonant circuit coils 6, 7

DC high voltage source 8 connected, which in turn via its terminals 9 with electrical energy, e.g. from an electrical power supply network. The high-voltage source 8 is a capacitor-rectifier cascade circuit in the case shown; other designs of high voltage sources are also possible, e.g. so-called switching power supplies with high voltage output. The effective total capacitance formed by the capacitors 12 of the cascade circuit forming the high voltage source 8 is shown in FIG. 5 by a single capacitor 14 which is located at the output 10 of the high voltage source 8.

An electrical conductor 15 leads from one capacitor plate 4 via a switch element designed as a spark gap 16 to the other capacitor plate 5; When the spark gap 16 responds, ie the switch element formed by this spark gap closes, a circuit leading from the capacitor plate 4 to the capacitor plate 5 is formed via the conductor 15. The stroke distance of the spark gap 16 is adjustable with a screw 17, which is provided with an electrically insulating handle 18. In this way, the response voltage of the switch element formed by the spark gap 16 can be changed.

If the high-voltage source 8 is supplied with electrical energy via the terminals 9, a high direct voltage builds up at the output 10 of the high-voltage source, the output capacitance of which is represented by the capacitor 14. This high voltage is at the same time on the capacitor plates 4 and 5. As soon as the value of this high voltage reaches the ignition voltage of the spark gap 16, it becomes conductive, and there is an abrupt discharge of the energy stored in the high voltage source via the resonant circuit coils 6, 7, thereby using these coils a strong magnetic field, which acts on the liquid in the treatment room 1, is generated for a short period of time. It can be assumed that the discharge produces a rapidly decaying oscillation. This oscillation is superimposed on a further oscillation with a significantly higher frequency, which arises in the part of the oscillating circuit formed by the capacitance 20 of the capacitor plates 4, 5 and the conductor 15 with a conductive spark gap 16.

After the abovementioned vibrations have subsided, the spark gap 16 loses its conductivity and there is again a build-up of a high voltage at the output 10 of the high-voltage source 8. This voltage build-up requires a considerably longer period of time than the discharge of the energy stored in the high-voltage source 8, and accordingly the liquid in the treatment room 1 is subjected to the action of a magnetic field generated by the coils 6, 7 for short periods of time, and these short periods of time are longer Breaks separated. The electrical high-voltage field, to which the liquid in the treatment room 1 is also subjected, consists, according to the relatively slow voltage build-up at the output 10 of the high-voltage source 8, of a slowly changing component and of a high-frequency component which results from the oscillation processes discussed above.

The vessel forming the treatment room 1 is formed in the example shown in FIGS. 1 to 5 from two nozzle halves 22, 23 made of insulating material, in the walls of which, in addition to the capacitor plates 4, 5, the resonant circuit coils 6, 7 are also embedded. The nozzle halves 22, 23 are inserted between two metal clamping plates 24, 25 and are pressed against one another by this, the annular gap between the can halves being closed by a sealing ring 26. The clamping plates 24, 25 are in turn held together by screws 27. On the inside of the nozzle halves there is a web 28 forming the treatment room 1 into a U-shaped flow, and the inlet and outlet openings 2, 3 of the treatment room are adjacent to each other on one side of this web 28. The capacitor plates 4, 5 are sufficient over the entire treatment room 1.

The embodiment shown in FIGS. 6 to 9 is a device according to the invention 1 to 5 similar to the embodiment discussed above.

6 to 9, the treatment room 1 is formed by a one-piece vessel 29 made of insulating material, in which the inlet and outlet openings 2, 3 are provided, and the condensate plates 4, 5 are embedded in the insulating walls thereof are. The coil 30 provided to form the magnetic field passing through the treatment room 1 is arranged in the region of the web 28, which forms a U-shaped flow path from the treatment room 1, and is placed in such a way that the field direction of the magnetic field of this coil in the treatment room is approximately perpendicular to the field direction of the electrical high-voltage field, which is generated by the Kαndensatorplatten 4, 5, runs.

The capacitor plates 4, 5 are connected via connecting lines 31 to the output 10 of the DC high-voltage source 8; the capacitance effective at the output 10 of the high-voltage source 8 is represented by a capacitor 14. The coil 30 forms a circuit leading from the capacitor plate 4 to the capacitor plate 5, into which a switch element designed as a spark gap 16 is inserted. The breakdown voltage of the radio amplifier 16 can be adjusted by means of a screw 17. The coil 30 forms, together with the capacitor plates 4, 5 or the effective capacitance 20 thereof and the capacitance 14 of the high-voltage source 8, a high-frequency resonant circuit.

When the high-voltage source 8 is supplied via the terminals 9, a high DC voltage builds up at the output of the high-voltage source 8, which is also present on the capacitor plates 4, 5. If the value of this high voltage reaches the breakdown voltage of the spark gap 16, there is an abrupt discharge via the coil 30 and at the same time an oscillation, as a result of which the electrical high-voltage field, which is active between the capacitor plates 4, 5, and due to the slow voltage build-up at the output of the high-voltage source, now has a slowly changing component high-frequency component is given by the vibration originating from the discharge. At the same time, the current flowing through the coil 30 generates a strong magnetic field for a short period of time, which acts on the liquid to be treated in the treatment room 1.

The device according to the invention can be operated with very little energy. For example, in execution farms, as shown in the drawing, and in which the vessel forming the treatment room has a diameter of approx. 80 mm, energy consumption of approx. 5 W is sufficient.

Claims

PATENT CLAIMS:

1. Method of removing scale and corrosion or preventing scale and corrosion from forming in a liquid, e.g. Water through which the pipe system flows through physical treatment of the liquid flowing through the pipe system, characterized in that the liquid is subjected both to the action of an electrical high-voltage field and to the action of a strong magnetic field which is effective for short periods of time which are separated from longer breaks.

2. The method according to claim 1, characterized in that the liquid is subjected to the action of an electrical high-voltage field, which is a high-frequency electrical field.

3. The method according to claim 1, characterized in that the liquid is subjected to the action of an electrical high voltage field, which consists of a slowly changing or constant component and a high-frequency component.

4. The method according to any one of claims 1 to 3, characterized in that the liquid is subjected to the action of a magnetic field which is generated by a briefly flowing electrical current through an electrical resonant circuit.

5. The method according to any one of claims 1 to 4, characterized in that the field direction of the magnetic field is approximately perpendicular to the field direction of the electrical high-voltage field.

6. Device for carrying out the method according to one of claims 1 to 5, characterized in that the device one for the flow of the liquid trained, between two capacitor plates (4, 5) lying treatment room (1), arranged in the area of the treatment room resonant circuit coil (6, 7; 30), whose magnetic field passes through the treatment room (1), a direct voltage high voltage source (8), the feeds the resonant circuit containing the capacitors and the resonant circuit coil, and has a switch element (16) which briefly switches on the current flow through the resonant circuit coil.

7. The device according to claim 6, characterized in that the high voltage source (8) at its output (10) has a storage capacitor (14).

8. The device according to claim 7, characterized in that the high voltage source (8) is a capacitor-rectifier cascade circuit.

9. Device according to one of claims 6 to 8, characterized in that the switch element (16) closes a circuit which leads from one to the other of the capacitor plates arranged on the treatment room (4, 5).

10. The device according to claim 9, characterized in that the switch element is a spark gap (16).

11. The device according to claim 10, characterized in that the range of the spark gap is adjustable.

12. Device according to one of claims 7 to 11, characterized in that the resonant circuit coil (6, 7) is connected in series between the high-voltage source (8) and the capacitor plates (4, 5) arranged on the treatment room (1).

13. The apparatus according to claim 12, characterized in that the voice coil consists of two Partial coils (6, 7) is formed, which are each arranged on one side of the treatment room (1) and inserted into one of the two lines leading from the high voltage source (8) to the capacitor plates (4, 5).

14. Device according to one of claims 6 to 11, characterized in that in the vαn one of the circuit leading to the other circuit board is a resonant circuit belonging to the coil (30) whose magnetic field acts on the liquid to be treated.

15. Device according to one of claims 6 to 14, characterized in that the treatment room (1) is formed by a vessel made of insulating material (22, 23; 29) with inlet and outlet openings (2, 3), in the insulating walls the capacitor plates (4, 5) are arranged.

16. The apparatus according to claim 15, characterized in that the conductors or coils (6, 7; 15, 30) provided for forming the magnetic field are embedded in the walls of the vessel (22, 23; 29).

17. The apparatus according to claim 15, characterized in that the treatment chamber (1) forming the vessel is designed as a flat box and in this a treatment chamber (1) to a U-shaped flow path web (28) is provided, the openings (2, 3) for the inflow and outflow are adjacent to each other on one side of the web (28) and the capacitor plates (4, 5) extend over the entire treatment room (1).

18. The apparatus according to claim 17, characterized in that the treatment chamber (1) forming vessel from two can halves (22, 23) is formed, which