DE9201021U1 - Device for treating water in a magnetic field - Google Patents

Description

Device for treating water in a magnetic field.

The innovation relates to a device according to the generic term of claim 1.

A device of this type is known (DE-OS 40 19 630).

The known device is used to remove scale or to prevent the formation of scale in systems through which water flows, namely by treating the water in a magnetic field which is generated by a magnetic coil. The latter is controlled by a control device using a pulsating direct current, i.e. a rectified, non-smoothed alternating current. Furthermore, it is intended to change the direction of the pulsating direct current periodically in order to increase the effectiveness of the device.

The aim of the innovation is to improve the device of the type mentioned at the beginning.

To achieve this object, the device is designed according to the characterizing part of claim 1.

In the new device, a working signal or control clock for the control electronics is derived from the mains voltage. This control clock then enables very precise control or switching of the output stage from one operating state to the next operating state. In particular, this control clock can be used to optimally select the end of the current flow through the solenoid coil, i.e. the end of the first and second operating states, depending on, i.e. synchronously with, the temporal progression of the mains voltage, so that at this end the solenoid coil has a minimum of magnetic energy, so that the creation of an induction voltage on the solenoid coil that places excessive strain on the output stage or its components is avoided.

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Further developments of the innovation are the subject of the dependent claims.

The innovation is explained in more detail below using the figures of an example. They show:

Fig. 1 shows a schematic block or functional diagram of a device for decalcifying water;

Fig. 2 shows a simplified representation of an electronic control circuit for use in the device according to Fig. 1.;

Fig. 3 is a time diagram of the current through a magnetic coil.

In Figure 1, 1 is a pipeline carrying service water, for example the supply line, to which at least one water device or consumer 2 is connected, in particular one that also has a heating device for heating the water. Such consumers 2 are, for example, washing and cleaning machines or systems for the household or for industrial applications, e.g. clothes washing machines, dishwashers, vessel cleaning machines, bottle washing machines, etc.

The water supplied to the consumer 2 flows through a device 3 for treatment, in which the water is softened by ion exchange using salt (sodium chloride).

In the direction of flow of the water, the device 3 is preceded by a device 4 in which the water is treated in a magnetic field whose intensity changes periodically between a minimum value, for example the value zero, and a predetermined maximum value, for example with a frequency that is equal to the mains frequency or twice the mains frequency. In a

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At a predetermined rate, which corresponds to a frequency that is significantly smaller than the frequency of the periodic change in the intensity of the magnetic field, this magnetic field is reversed in its direction, for example in such a way that, as shown in Fig. 3, the magnetic field has a first, predetermined polarity in a longer time period ti. In a laterally adjoining period t2, which is smaller than the time period ti, the magnetic field is completely switched off. In a subsequent time period t3, which is smaller than the time period ti, but larger than the time period t2, the magnetic field has the second, opposite polarity. The time period t3 is followed by a time period t4 in which the magnetic field is again absent. This is followed by a new total period T, having the times or periods ti - t4.

Based on the total period T, the following values result for the individual times:

ti = 0.66 T

t2 = 0.1T

t3 = 0.13T

t4 = 0.11T

The total period duration is, for example, in the order of magnitude between 60 and 100 seconds.

In a preferred embodiment, the times ti -t4 have the following values:

ti = 49.92 seconds

t2 = 7.68 seconds

t3 = 10.24 seconds

t4 = 8.32 seconds

In the embodiment shown, the device 4 consists of a shell-like housing 5, which has an interior space 6 closed to the outside, which is divided by a plate 7 into two sub-spaces, one of which

a connection 8 for supplying the water and the other has a connection 9 for draining the water. The latter is connected to the inlet of the device 3.

To generate the magnetic field through which the water flows, a magnetic coil 10 is provided which surrounds the plate 7, through which a current flows, the intensity of which changes periodically according to the magnetic field to be generated and is also time-controlled in the manner shown in Figure 3. The magnetic coil 10 generates the magnetic field, the field lines of which run in the interior 6 transversely to the gap formed between the inner surfaces of the housing and the plate 7, through which the water flows, and are otherwise closed by the ferromagnetic material of the housing 5.

Although the treatment of the water in the magnetic field does not remove the lime particles contained in the water, which always contain a proportion of iron and/or a proportion of another magnetizable metal, from the water by the device 4, but merely magnetizes the magnetizable parts, this pre-treatment of the water in the device 4 during the immediately following softening can surprisingly result in a very significant saving in the amount of salt required for softening, namely a saving of up to 50%. This can significantly reduce the operating costs of a system. Furthermore, this makes a significant contribution to reducing the burden on the environment. This is evidently due to the fact that the pre-treatment of the water in the magnetic field and the magnetization of the lime particles or their proportions of magnetizable substances that occurs in the process result in optimal processing for ion exchange.

An electronic control device 11, which is shown in more detail in Figure 2, is used to control the magnetic coil 10.

This control device or control unit essentially consists of two parts, namely the control electronics 12 and the output stage 13 that controls the magnetic coil 10.

In the output stage 13, the magnetic coil 10 is connected with one connection to a line 14, between which and the circuit ground the mains voltage of 220 volts and 50 Hz is present. With its second connection, the magnetic coil 10 is connected to a changeover switch for changing the direction of the current flow through the magnetic coil 10. In the embodiment shown, this changeover switch is shown as a changeover contact 15 of a relay 16. Of the two changeover contacts that interact with the changeover contact 15, one is connected to the anode of a diode 17 and the other to the cathode of a diode 18. Both diodes are connected with their other connection to the circuit ground via an electronic switch 19, which in the embodiment shown is designed as a thyristor. The diode 17 is in series with another diode 20 and the diode 18 is in series with another diode 21, each between the switch 19 and the line 14, whereby these diodes 20 and 21, which serve as freewheeling diodes for the magnetic coil 10, are each provided with opposite polarity to the associated diode 17 or 18 in the series circuit, i.e. the diodes 17 and 20 are connected to their anodes and the diodes 18 and 21 to their cathodes.

The changeover contacts of relay 16, which interact with changeover contact 15, are connected to the connection point between diodes 17 and 20 or 21. To limit the voltage or to protect against voltage peaks from the mains voltage or to limit the induction voltage of the magnetic coil 10, a varistor 22 (voltage-dependent resistor) is provided parallel to the changeover contacts of relay 16 and parallel to the magnetic coil 10. A damping resistor 35 is also connected parallel to the magnetic coil 10.

The relay 16 is controlled via a transistor 23. A control circuit 24 is provided for switching or igniting the switch 19, which essentially has a transistor and two clamping diodes for protection against interference voltages from the mains.

According to the timing diagram in Fig. 3, the relay 16 and the switch 19 are controlled in such a way that, for example, when the relay 16 is in the position shown, the switch 19 closes at the beginning of the time ti, so that a rectified pulsating current (corresponding, for example, to the positive half-waves of the AC mains voltage) can flow through the magnetic coil 10 via the diode 17. After the time ti has elapsed, the switch 19 is blocked, which begins the time t2. Shortly before the end of this time period t2, the relay 16 is actuated and the changeover contact

15 is moved into the working position. By switching on the switch 19 again, a current flows through the coil via the diode 18 in the opposite direction, during the time period t3. At the end of the time period t3, the switch 19 is blocked again so that the current flow is interrupted during the time t4. In the time period t4 and before the end of this time period t4, the relay is switched over.

16 back to the starting position shown.

By interrupting the flow of current in the time periods t2 and t4 and by the delayed switching of the relay 16 in these time periods, it is ensured that the relay 16 or the contacts of this relay are switched not only when the magnetic coil is disconnected from the mains voltage, but also only when the induction voltage of the magnetic coil 10 has definitely dissipated, i.e. the relay 16 always switches in the de-energized state, thus ensuring that the relay contacts are subject to a minimum of wear.

In the embodiment shown, the switching of the switch 19 continues to take place synchronously with the temporal course of the mains voltage, namely at a time at which

the magnetic energy of the magnetic coil 10 is at a minimum, so that the induction voltage occurring at the magnetic coil 10 after the switch 19 is blocked is kept low.

The control electronics 12 essentially consist of a control electronics 25, which is formed by an IC and provides the signals for controlling the relay 16 or the associated transistor 23 and the switch 19 or the associated control electronics 25 at different outputs. Furthermore, the control electronics 25 also provides output signals for controlling light-emitting diodes 26, which indicate the operating state.

The control electronics 25 are controlled by several outputs of a divider 27, which is also an IC and to which a pulse signal with mains frequency derived from the mains voltage is fed at a signal input. This pulse signal is used to control the divider 27 synchronously with the mains, which divides the mains frequency down to the required control times. The output signals of the divider are then decoded by the control electronics 25 to generate the control signals.

To generate the control square-wave pulse, one input of the divider 27 is connected to the output of a Schmitt trigger 28, which in turn is connected to the mains voltage via a series resistor 29. A capacitor 30 is provided in parallel to the input of the Schmitt trigger 28, which together with the resistor 29 serves as a low-pass filter to filter out any short-term voltage peaks that may be present on the mains voltage.

At the end of each period T, the divider 27 is reset to zero by a signal present at another output of the control electronics 25 via a feedback branch 31, which, in addition to a Schmitt trigger 32, also has an RC element formed by a resistor 33 and a capacitor 34. The resistor 33 connects the

Input of the Schmitt trigger 32 with the output of the control electronics 25. Via the capacitor 34, the input of the Schmitt trigger 32 is still connected to the direct current supply voltage of the control electronics 12. The RC element formed by the resistor 33 and the capacitor 34 ensures, among other things, that when the electrical control device 11 is switched on, the counter or divider 27 is inevitably set to zero. Furthermore, this RC element also provides a
Minimum remaining time is reached, which is approximately 1 msec.

The invention has been described above using an exemplary embodiment. It is understood that changes and modifications are possible without departing from the inventive concept underlying the invention.

List of reference numbers used

1 4 Pipeline 2 consumer 3, Furnishings 5 Housing 6 9 inner space 7 plate 8th, Connection 10 Magnetic coil 11 Control device 12 Control electronics 13 Power amplifier 14 Line 15 18 Changeover contact 16 relay 17, 21 diode 19 Switch 20, Freewheeling diode 22 Varistor 23 transistor 24 Control circuit 25 Control electronics 26 led 27 Divider 28 Schmittrigger 29 Resistance 30 capacitor 31 return 32 Schmittrigger 33 Resistance 34 capacitor 35 Damping resistance

Claims (10)

Protection claims 1. Device for treating water in a magnetic field, with a housing (5) through which water can flow, with at least one magnetic coil (10) for generating the magnetic field in at least one area through which water can flow in the interior (6) of the housing (5), and with a control device (11) for controlling the magnetic coil (10), the control device (11) having an output stage (13) connected to the magnetic coil (10) with a switching device (16, 19) and control electronics (12) which control the switching device in such a way that in a first operating state of the switching device (16, 19) there is a current flow through the magnetic coil (10) in one direction, in a second operating state of the switching device there is a current flow through the magnetic coil (10) in the opposite direction, and in a third operating state, which is in each case between a first and a second or a second and a first, the current flow through the magnetic coil (10) is interrupted, characterized in that the control electronics (12) has a circuit (27, 28, 29, 30) connected to the mains voltage for deriving a control clock from the mains voltage. 2. Device according to claim 1, characterized in that the circuit has a Schmitt trigger (28) which is provided in its input with an RC element (29, 30) acting as a low-pass filter. 3. Device according to claim 1 or 2, characterized in that the circuit has a counter or divider (27) which is connected to at least one output for transmitting a control signal derived from the mains voltage with a control electronics (25) of the control electronics (12). 4. Device according to claim 3, characterized in that the counter or divider (27) has a reset input, and that an auxiliary circuit (31) connected to this reset input is provided, which forcibly sets the divider or counter to zero when the control device (11) is switched on or when the supply voltage of the control device (11) is switched on. 5. Device according to one of claims 1-4, characterized in that a damping resistor (35) and/or a varistor (22) is provided at the output of the output stage (13) parallel to the magnetic coil (10). 6. Device according to one of claims 1 - 5, characterized in that the switching device is formed by the series connection of an on and off switch (19) and a changeover switch (15, 16), via which the magnetic coil (10) can be connected to a first rectifier arrangement (17) for a current flow in one direction and to a second rectifier arrangement (18) for the current flow in the opposite direction. 7. Device according to claim 6, characterized in that the rectifier arrangements are each formed by a diode (17, 18). 8. Device according to one of the preceding claims, characterized in that the changeover switch (15, 16) has a central connection (15) connected to a connection of the magnetic coil (10) and two switchable connections each connected to a rectifier arrangement (17, 18), that an attenuation element formed by a resistor and/or varistor (22) and/or a series connection of two freewheeling diodes (20, 21) is provided parallel to these switchable connections, and that the circuit point connecting the two freewheeling diodes (20, 21) is connected to the other connection of the magnetic coil (10). 9. Device according to one of the preceding claims, characterized in that the changeover switch is a relay (16). 10. Device according to one of the preceding claims, characterized in that the on and off switch is a thyristor (19).