NL1001559C1 - Generator for low frequency magnetic field for therapeutic applications - Google Patents

Abstract

A coil (1) which produces the magnetic field encircles the user's arm or leg. A d.c. supply (3) is fed via an electronic switching bridge (5, 6, 7, 8) with flywheel diodes to the coil (1). The current fed to the coil is detected using a series resistance (15). The control circuit (13) switches the electronic switches (5, 6, 7, 8) to produce the required frequency, set using a potentiometer (14). The amplitude is controlled by another potentiometer (16) which reduces or increases the length of time for which the pulses are fed to the coil.

Description

Device for generating a magnetic field

The present invention relates to a device for generating a magnetic field for therapeutic purposes, comprising a coil, a DC voltage supply and a control circuit for generating an alternating current with a predetermined amplitude and frequency through the coil.

The use of alternating magnetic fields for therapeutic purposes is known per se, for example from patent application EP-A-0 459 402. In this known device, an alternating voltage is generated with the aid of a sine generator with an adjustable frequency, which is then generated with the aid of of an amplifier circuit with adjustable gain is amplified such that a current flows in a coil connected to the amplifier circuit and generates the alternating magnetic field.

The affected body part is then placed in the coil and is believed to experience a beneficial therapeutic effect from the varying magnetic field. The therapeutic effect can be optimized by choosing an appropriate frequency and an appropriate amplitude of the current.

25

A drawback of the known device is that it is complex and expensive. The device according to the invention provides an advantageous alternative for this, wherein the current is also generated by the coil with a high efficiency, and is characterized in that the control circuit comprises a control circuit and a bridge circuit with at least two switching elements and two flywheel diodes.

In a first favorable embodiment, the device 35 is characterized in that the control circuit comprises a bridge circuit with four 1001 559> 2 switching elements, at the output of which the coil is connected.

In a second favorable embodiment, the device 5 is characterized in that the control circuit comprises a half-bridge circuit with two switching elements, at the output of which the coil is connected. However, the DC voltage supply must have a center tap, so that a positive output voltage and a negative output voltage are available.

For optimal therapeutic effect, the frequency of the alternating current through the coil is selected in an interval of one to twenty Hertz. For both embodiments, the control circuit is therefore arranged to switch the switching elements with a frequency of one to twenty Hertz.

For both embodiments it also holds that a supply voltage is connected to the coil via one or two switching elements, after which the current in the coil will increase. Depending on the ohmic resistance of the coil, it is possible to select the supply voltage in such a way that the desired current starts to flow. The drawback is that in this way the current is determined very inaccurately and that the current intensity cannot be freely selected. A further favorable embodiment of the invention obviates these drawbacks and is characterized in that the control circuit is adapted to switch off switched-on switching elements if an absolute value of the instantaneous current through the coil is greater than a predetermined value Imax and for these switching elements are switched on again if the absolute value of the instantaneous current through the coil is less than a predetermined value Imin, it being noted that also at 1 0 0 1 559.

3 switched-off switching elements, a current can continue to flow through the coil via the flywheel diodes.

It is known that a variable magnetic field with a frequency much higher than one to twenty Hertz can also have a therapeutic effect. It is generally believed that these high frequencies mainly generate heat in deeper layers of the affected tissue. A very favorable embodiment of the inventive device is characterized in that a capacitor, connected in parallel to the coil, is provided for switching high-frequency alternating current through the coil as switching elements of the bridge circuit. Hereby it is assumed that the voltage source 15 has such an internal resistance that it does not damp the pendulum circuit formed by the coil and the capacitor too much. If this is the case, an additional series resistance can be included. A favorable therapeutic effect is obtained by choosing the capacitor such that the frequency of the high-frequency alternating current is in the interval of one thousand to twenty thousand Hz.

It goes without saying that the DC voltage source can also be placed outside the device, for instance in the form of a mains supply device to be connected to a mains voltage, to which the coil can then be connected together with the control circuit. The invention therefore also relates to a device for generating a magnetic field for therapeutic purposes, provided with a coil and a control circuit according to any one of the preceding claims, provided with connection points for connection to a DC voltage supply.

The invention will now be further elucidated with reference to the following figures, wherein: 1 0 0 1 5 5S.

4

Fig. 1 shows a device according to the invention, provided with four switching elements;

Fig. 2 shows a device according to the invention just two switching elements;

Fig. 3 shows a possible embodiment of the control circuit.

Fig. 1 shows a device according to the invention, 10 in which a coil 1 is connected to a control circuit 2, which in turn is connected to a DC voltage source 3. Coil 1 has dimensions such that it can be placed comfortably around an arm or leg , for example with a diameter of 20 cm. and a length of 10-15 cm. The inductance of coil 1 is, for example, 100 mH. Control circuit 2 comprises a bridge circuit 4 with four solid state switching elements 5,6,7,8, here symbolically drawn as switches, each comprising a flywheel diode 9,10,11,12 and furthermore a control circuit 13 for switching on and off the switching elements.

Switching elements 5,6,7,8 can be, for example, transistors, FETs or GTO thyristors.

In order to generate an alternating current in coil 1, the control circuit 13 alternately conducts switching elements 5 and 8 simultaneously, and subsequently switches 6 and 7, with a frequency corresponding to the frequency desired for the alternating current set by means of an adjustment potentiometer 14. This will produce an at least substantially block-shaped alternating voltage on coil 1, which in turn generates an alternating current in coil 1. In its simplest form, the amplitude of the alternating current is determined by the output voltage of DC voltage source 3 and the ohmic resistance of coil 1.

35 It is better to choose the output voltage much larger and 1 0 0 1 5 5 9 ..

5 control circuit 13 to be equipped with a current sensor 15 and an adjustment potentiometer 16, such that if the current threatens to become greater than an Imax selected with adjustment potentiometer 16, the 5 switching elements which are currently switched on are switched off, after which the current is switched off via the flywheel diodes, is going to decrease. If the current has become smaller than a selected Imin, which is set to, for example, 0.9 Imax, these switching elements are switched on again. In this way, the switching amplitude of the current through the coil is kept equal within narrow limits. Current sensor 15 is here designed as a resistor, but can also be designed, for example, as a Hall sensor well known in the art, which Hall sensor is then preferably positioned close to coil 1 for directly measuring the generated magnetic field. The use of a Hall sensor can further increase the efficiency of control circuit 2.

The alternating current through coil 1 is not purely sinusoidal, but contains much higher harmonics. These are believed to provide additional therapeutic action in the form of heat development deeper into the body part placed in the coil. Said high-frequency alternating currents can still be promoted by arranging a capacitor 17 parallel to coil 1. Whenever bridge circuit 4 switches, the resonant circuit formed by coil 1 and capacitor 17 will be excited and will produce a damped high-frequency vibration. Capacitor 17 in combination with coil 1 is preferably chosen such that resonance occurs for currents in the interval between one thousand and twenty thousand Hertz and for this purpose has a capacity of, for example, 2500 pF.

Fig. 2 shows a device according to the invention, in which coil 1 is connected to a control circuit 2, which is at 1001559.

6 is in turn connected to a DC voltage source 3 provided with a center tap, such that both a positive and a negative supply voltage are available. Control circuit 2 comprises a half bridge circuit 4 with 5 two solid state switching elements 5,6, each provided with a flywheel diode 9,10 and furthermore a control circuit 13 for switching on and off the switching elements. The further operation of the device is completely identical to that described with reference to FIG. 1 described device. It can be noted, however, that the efficiency of the in FIG. 2, because the absence of two switching elements is slightly more favorable, since switching elements always introduce losses. This is important, for example, if control circuit 2 and coil 1 are integrated for connection to an externally placed power source 3, whereby especially the heat development in the integrated component could be unpleasant for the patient.

Fig. 3 shows a possible embodiment of control circuit 13, in which the voltage across current sensor 15 is compared with Imax, adjusted with the aid of comparators 18, 19, adjusted with the aid of the adjustment potentiometer 16 and with Imin, using the adjustment potentiometer 20 derived from Imax. Comparators 18,19 will reset flip-flop 21 through input R if the current through current sensor 15 is greater than Imax and reset through input S if the current is less than Imin. Output Q of flip-flop 21 is then combined in AND gates 22, 23 with the complementary outputs X, NX of a digital clock circuit 24 well known in the art, the frequency of which is adjustable with adjustment potentiometer 14. The outputs 25, 26 of AND gates 22,23 are then connected to switching elements 5,8 and 7,6 in FIG. 1 or to switching elements 5 and 6 in FIG. 2 for operating the relevant switching elements. Hereby 100155 *.

7, the complementary outputs of clock circuit 24 determine which switching element or set of switching elements may conduct at any time, while output Q of flip-flop 21 determines whether the current through current sensor 15, and thus also coil 1, 5 increases or decreases within the limits Imax and Imin.

Because control circuit 13 is entirely built up of switching elements, it can easily be integrated on a single integrated circuit together with the switching elements 5,6,7,8 and the flywheel diodes 9,10,11,12.

1 001 559.i

Claims (10)

Device for generating a magnetic field 5 for therapeutic purposes, comprising a coil, a DC voltage supply and a control circuit for generating an alternating current of a predetermined amplitude and frequency through the coil, characterized in that the control circuit is a control circuit and a bridge circuit comprising at least two switching elements and two flywheel diodes. 2. Device as claimed in claim 1, characterized in that the control circuit comprises a bridge circuit with four switching elements 15 and four flywheel diodes, at the output of which the coil is connected. 3. Device as claimed in claim 2, characterized in that the control circuit comprises a half-bridge circuit with two switching elements and two flywheel diodes, at the output of which the coil is connected. 4. Device according to claim 2 or 3, characterized in that the control circuit is adapted to switch the switching elements at a frequency of one to twenty Hertz. 5. Device as claimed in claim 4, characterized in that the control circuit is adapted to switch off 30 switched-on switching elements if an absolute value of the instantaneous current through the coil is greater than a predetermined value Iroax and for switching on these switching elements again. if the absolute value of the instantaneous current through the coil is less than a predetermined value Imin. 100155 ?. 6. Device according to claim 5, characterized in that a capacitor, connected in parallel to the coil, for generating a high-frequency alternating current through the coil, is always switched as switching elements of the bridge circuit. Device according to claim 6, characterized in that the capacitor is chosen to generate a high-frequency alternating current with a frequency of one thousand ten to twenty thousand Hertz. Device according to claim 2 or 3, characterized in that the switching elements are designed as transistors, FETs or GTO thyristors. 15 Device according to claim 8, characterized in that the control circuit is designed as an integrated circuit. A device for generating a magnetic field for therapeutic purposes, comprising a coil and a control circuit according to any one of the preceding claims, provided with connection points for connection to a DC voltage supply. 1 00 1 55¾.