DE10054477A1 - Manget therapy device and procedure - Google Patents

Abstract

The invention relates to a magnetic field therapy device, comprising a device for the generation of an inductive field and optionally a device for the generation of a capacitive field, which are preferably controlled in a synchronous manner and are embodied such that they permit essentially the whole body of the patient to be subjected to the corresponding field. The invention further relates to the use of said device for therapy and said therapy.

Description

Field of the Invention

The invention relates to a magnetic therapy device for treatment of humans, but also of animals, especially of mammals.

State of the art

The use of magnetic fields in medical therapy has one long tradition. For this, both the fields of permanent magnets as well as those used by electromagnets. The use of Electromagnets make it easy to change the magnetic field by appropriate electrical control. Although there are approaches to Use of ver generated by means of movable permanent magnets changeable magnetic fields, the use of electromagnets is before Trains t. This allows the direction, strength, frequency and the temporal Vary the course of the magnetic field over a wide range. Come here as magnetic field generating devices in general without current its coils. These can be self-supporting around a hollow Core wound. In these cases, they are referred to as air coils. However, they can also have a core, which preferably consists of a fer romagnetic material e.g. B. consists of iron. Such an iron core increases the magnetic flux density (field strength) by up to four orders of magnitude calculations.

Magnetic field therapy devices with electromagnets are among others known from EP 0 144 920, EP 0 459 402, EP 0 857 495, WO 91/16 941, U.S.P. 4,665,898, U.S.P. 4,674,482, U.S.P. 5,441,495, U.S.P. 5,453,074, U.S.P. 5,527,259, U.S.P. 5,518,495 and U.S.P. 5,769,778.

The possible common effect of a homogeneous magnetic field and of a simultaneous homogeneous electric field is in "The Great Book of Magnetic Therapy", Ed. Christian Thuile, 2nd ed., Page 313 (1998) mentioned. However, there is no indication of a techni given implementation.  

To date, magnetic field therapy is predominantly based on experience of individual therapists. There are few principles that can be considered generally accepted. Which also includes, that the use of frequencies as low as possible and / or one the smallest possible amplitude of the signal used is generally advantageous should be. A comparison of the success of the different therapy However, shaping is desirable, especially to the experience that a Therapist made with a specific form of magnetic therapy has to be able to document and possibly generalize.

The object of the present invention was a device to provide magnetic therapy, which is a simple change change in the applied magnetic field, especially with regard to Strength, frequency and waveform enables, as well as documentation and, if necessary, storing these parameters, in particular the Im pulse frequency, pulse amplitude and pulse shape allowed.

Furthermore, the task consisted of tracking, monitoring and Determination of the interaction of the generated magnetic field with the Organism of the patient and also their documentation and counter if necessary, their storage. In the present application means Patient human or animal, preferably human, who or that by means of Therapy is treated. The magnetic field interacts with the organ mus of the patient. The nature and strength of this interaction depends on it probably from the properties of the magnetic field, as well as from those of the Magnetic field from the organism. So the change is obvious interaction also depends on which part of which organism or which organism with which constitutional conditions the Ma gnetfeld is or are exposed. In particular, are here as special significant conditions gender, age and general constitution of the patient.

Another object of the present invention is to provide a measure Magnetic field therapy device available, with which essentially the patient's entire body has a defined magnetic field can be exposed.  

In addition, the task was to provide a device set next to the magnetic field, preferably synchronously controlled, electric field (a capacitive field) is generated.

Description of the invention

The magnetic therapy device comprises

• a) one or more pulse generating device (s)
• b) comprising a magnetic therapy station one or more field generating device (s),
• c) one or more, preferably several, measuring and / or rule device (s) and
• d) optional, preferably mandatory, a computer system.

In the present application, magnetic field therapy place (short MFTP) a device that is part of a patient or a patient can accommodate ten. The MTFP is preferred for the whole patient take up. The MTFP may include a device for opening acceptance or support of a patient or part of a patient As a device for receiving or supporting a patient can serve, for example, a chair or preferably a couch.

The MFTP preferably comprises two or more field generating devices, particularly preferably it comprises

• a) one or more inductive field generating devices and
• b) one or more capacitive field generating devices.

The MTFP preferably comprises one or more amplifiers, preferably one or more low frequency amplifiers. Does the MTFP contain one  single amplifier, it preferably has several channels. Prefers the MFTP contains one amplifier per coil or a multi-channel ver stronger with at least one channel per coil.

In a preferred embodiment, the MFTP comprises two or more inductive field generating devices, each of which preferably has its own low frequency amplifier or a separate channel of a multi-channel have low frequency amplifier.

In a preferred embodiment, magnetic field therapy comprises direction one or more, preferably two or more coils to generate inductive field and one or more vertical to the coil or to the coils arranged capacitor (s) for generating generation of an electrical (capacitive) field. Where the coil or the Coils and the capacitor or the capacitors each so arranged net are that both the magnetic field and the electric field preferred according to the length of the patient the length of a human body. It is from the average size of an adult person this is assumed to be 170 to 180 cm. The total length of the coil or coil arrangement for inductive generation of the field is be preferably 160 cm or more and the length of the arrangement including the Core of the coil 180 cm or more.

The magnetic flux density (T) depends on the number of turns n, the length of the coil l [m]), and the current intensity I [A]. It is calculated according to the following formula (Formula (1)).

T = µ ₀ .µ.n / lI (1)

where µ _{0 is} the magnetic permeability in a vacuum and has the value 4π.10 ^-7 , µ is the relative material-specific susceptibility of the core. For iron, the value of µ is on the order of 10 ³ to 10 ⁴ . The unit of measurement for magnetic flux density is Tesla, or T.

The capacitive field is generated by a plate capacitor. This electric field is preferably also such that essentially the patient's entire body can be exposed to the field. Be the electric field is preferably a homogeneous or largely homogeneous electric field.

The bottom plate of the capacitor is installed below the coil. she is preferably permanently installed. The construction of the lower plate of the Kon capacitor is not critical. The bottom plate of the capacitor is before trains formed as a solid plate or as several solid plates. she can be used for easier maintenance and disassembly of the therapy device from several, preferably from two or more, very particularly preferably consist of two parts. There is the bottom plate of the capacitor it is preferably driven from several parts as a single plate The material of the lower plate of the capacitor is also not critical table. It can be made from almost any electrically conductive material al, e.g. B. consist of copper or zinc sheet. The lower plate of the The capacitor does not have to be planar. It can be curved and / or out be composed of two or more flat plates, each egg form an angle to each other. For example, the bottom plate can be made there are two essentially identical partial plates, which are V-shaped in egg nem obtuse angles are attached to each other under the coil.

The upper plate of the capacitor is preferably variable in size. The upper plate of the capacitor is preferably designed as an electrically conductive, flexible layer. The preferred dimension is 100 x 160 cm ² . The upper plate of the capacitor is preferably placed on the patient like a blanket. The lowest possible stiffness of the upper plate is advantageous. In a preferred embodiment, the upper plate of the capacitor consists of an electrically conductive blanket, tarpaulin or foil. The upper plate preferably consists of an electrically insulating and an electrically conductive material. The electrically conductive material is incorporated into or applied to the insulating material. The electrically conductive material can be in various forms, for example in the form of one or more layers or in the form of individual or interwoven threads. Exemplary embodiments of the upper plate are blankets with woven-in metal threads, for example copper, silver or gold threads, the latter being advantageous due to their high conductivity and the fact that they can be realized with very small diameters. Further exemplary embodiments are metal foils, such as aluminum foil, or metallized plastic foils, such as PET foils coated with aluminum. These metallic or metallized foils are preferably applied to a blanket or tarp or, particularly preferably, incorporated between two blankets or tarpaulins.

The patient on the lying surface and the coil are inside the Capacitor. The capacitance of the capacitor depends on the effective one Area of the plates, the average distance between the plates and the dielectric between the plates, i.e. the patient, from. Since in particular the distance between the plates varies from patient to patient, especially ri also the capacity accordingly. The capacity is more typical 2.5 nF to 3.5 nF.

The signal from the patient is recorded with a probe. This preferably has the shape of a metal plate with skin contact. A probe, as is customary for recording ECGs, is preferably used. The probe is preferably attached to the patient's wrist. The metal plate has a suitable area, typically from a few square centimeters to a few 10 cm ^2, and is shaped in such a way that it lies against the patient. It is fi xed on the patient by a fastening device. It can advantageously be secured against slipping with a plaster, bandage or egg cuff. For example, the cuff can be equipped with one or more straps for tying, with buttons, with hooks and / or eyelets, with one or more elastic bands, with one or more Velcro fasteners or with a combination of several of these elements.

The pulse generating device comprises a device for generating of electrical signals, preferably periodically changing elec trical voltages with amplitudes (strengths) from 0 to 10 volts, ss (Spit ze-peak). A device is preferably used, the signals of which in  Frequency, amplitude, duration and preferably also ver in their curve shape are changeable. A function generator is particularly preferred set, which is advantageously programmable and in particular it allows to generate signals using mathematical functions, since these are storable and thus clearly reproducible. The definition of Si However, signal form is preferably carried out via a CAD analog computer pro then the signal can appear on the screen during its design be followed. Each signal can be saved and then stands available in identical form, frequency, amplitude and duration.

Signals with low frequencies are preferably used. The Fre frequencies are in the range from 0.1 Hz to 600 Hz, preferably from 1 Hz to 400 Hz and particularly preferably from 10 Hz to 200 Hz.

The frequency and amplitude, but also the shape and duration of the Signals can be generated at any time, including during a magnet session field therapy, to the individual conditions of the Pa to be treated be adjusted. The adaptation to the resonance is preferred financial conditions, d. H. the conditions under which an interaction kung the patient's organism with the pulsating field, or pulsating fields occurs. These resonance conditions are in the Re Gel differs from patient to patient. However, you can also use a and the same patient, depending on his current constitution of Vary from day to day. Significant influence on the resonance conditions have z. B. the fluid intake of the patient on the respective day, ingested poisons (such as nicotine or alcohol), electrolyte ver Lusts (such as those associated with vomiting or diarrhea) or their ge On the contrary, electrolyte retention in the body, as in a kidney sufficiency (an insufficient excretion function of the kidneys) can occur.

The electrical signals generated in the function generator are with ei nem shielded cable to the MFTP and there a Niederfre supplied with a sequence amplifier. The necessary signal strength is generated here and the amplified signal to the coil as well as to the synchronous Coil controlled condenser conducted. Synchronous here means both  field-generating components (coil and capacitor) simultaneously their respective generate gene-dependent field strengths.

The combination of an inductive field with a synchronous ka capacitive field changes the magnetic field compared to that at ago conventional magnetic field therapies used magnetic fields. In the front lying therapy device act inductive field and capacitive field together. Only determining the extent of the effect of the respective The field is the pulse shape and to a lesser extent the height of the Amplitude. With a sinusoidal pulse, the inductive field dominates, in the case of a rectangular pulse, the electrical (capacitive) field dominates. The the respective acting parts influence the reactions of the organ mus. The combination of both fields allows in significantly improved Way the desired interaction, namely the occurrence of Reso to reach nanz. In addition, there is a very special advantage Opportunity not only the input signals used, but also the type and form of the organism's reaction to those used Track signals.

Observe when using inductive and capacitive fields at the same time if you pay attention to a beat of the Signal from the patient. This beat can oscillate, so alternate be ascending and descending, with the enveloping curve of the maxima len signals shows an approximately sinusoidal course. Depending on the However, the beat can be a waveform of the input signal used also repeatedly fall from a maximum value of the amplitude or, be especially when using a square wave signal to a maximum value rise, cancel and rise again.

Although there is no general typical excitation signal, it has come up issued that a pulse shape that is both a balanced Relationship between the inductive and the capacitive field leads to most effective. The optimal relationship between the two fields however, depends largely on the indication to be treated.  

Duration of a signal depends on the frequency used, which like which depends on the therapy goal. Low frequencies work in the Re Gel balancing and calming, higher ones have a stimulating effect. Both The therapies made have the three frequencies of 32 Hz, 64 Hz and 128 Hz proved to be particularly preferred. These three frequencies in most cases meet the required resonance conditions that usually just fine-tune from patient to patient must be taken. These fine-tuning is done by Changing the frequency by up to two to three percent, often just enough ne change of up to only one percent.

The use of a continuous signal is preferred in comparison for using pulse packets. With a sweep signal ne ben the frequency modulation also amplitude modulation applied become. The use of a sweep signal at which the frequency Varies between two selectable limits, it has not proven to be advantageous grasslands. With this type of signal variation there were no significant thera significant effects, whereas a worsening of the Resonance effects occurred. The use of an Si has proven advantageous highlighted with an asymmetrical temporal course. before have z. B. the rising and falling edge of a triangular radio tion does not have the same absolute value of the slope. The ratio is preferred nis the rising edge to the falling edge 1: 3 (i.e. 25% and 75%). In the case of a square-wave signal, the signal component is negative Voltage in relation to a period 25% and the signal part with positi ver tension 75%, e.g. B. the negative signal lasts 25 ms, the positive Signal 75 ms.

The duration of a therapy session is preferably at least 20 minutes and preferably at most 40 minutes.

The measuring part of the measuring and / or control unit preferably comprises one one or more, preferably two or three and particularly preferably all three, of the following devices: an oscilloscope, a frequency analyzer and a frequency recorder. The oscilloscope is preferably a double beam oscilloscope and the frequency analyzer prefer a Fast Fourier  Transform (FFT) frequency analyzer. A device is advantageously used the one or more, preferably two or three and particularly preferred includes all three of these devices. It is preferred over one Interface connected to a computer, so that all of them functions can be controlled and measurement results can be read NEN. The measurement results are preferably displayed on a screen provides. The measurement results are preferred on a storage medium, z. B. the hard drive of the computer, recorded. Optionally, the Measurement results printed out using a suitable printer or using Plotter to be drawn.

With a digital double beam oscilloscope, both the input signal, as well as in the organism through the magnetic field and that mutually synchronous capacitor field generated potential changes be measured. These measurement results can optionally be shown on the picture screen of the oscilloscope or preferably via a PC on the screen asked and persecuted. So the functionality of the whole Device checked and essentially already an amplitude match solution of the input and thus also the output signal become.

In a second part, preferably also computer-controllable direction of the measuring device, a (Fast Fourrier Transform) frequency analyzer, the occurrence of resonance conditions can be determined who the. A frequency adjustment can be made here.

It was found that in addition to the shape of the input chosen signals, an amplitude change and / or frequency change of the Si a decisive influence on the occurrence of an interaction, especially the appearance of resonance.

In a third sub-device of the measuring device, a frequency recorder of, the organism's reactions can progress in time observes and judges and adapts to the respective therapy goal the.  

Possible indications in which magnetic therapy is successfully used are known from the literature. The following will be named some preferred indications in which the invention Magnetic therapy device can be used. This list is intended to exemplify the applicability of the device according to the invention point out without restricting them in any way.

Table 1

Preferred indications

Examples

In the following the present invention with reference to figures and Illustrated examples. These show concrete, preferred execution forms men of the invention, limit their possible embodiments depending but in no way on these examples.

example 1

The magnetic therapy station is shown schematically from the side in Fig. 1. The patient lies on the couch (L), the body of which consists essentially of wood. Directly underneath the lying surface of the bed is the coil arrangement in the middle (see also Fig. 3). The upper capacitor plate (KO) is above the patient and the lower capacitor plate (KU) is below the coil assembly. This is also shown in Fig. 3, in which the flexible shape of the upper capacitor plate, as well as the two-part structure of the lower capacitor plate is shown. The signal from the patient is recorded on the patient's forearm using a probe in the form of a metal plate with skin contact, as is customary for recording ECGs. The metal plate has an area of 3 × 8 cm ² and is slightly cylindrically curved. This means that it fits snugly on the patient's forearm. There it is secured against slipping with a cuff.

As shown in Fig. 3, the patient (P), covered by the upper capacitor plate (KO), lies on the couch (L). The coil arrangement (SP) is mounted on the cross bar (B1) as a fastening element. The lower plate of the capacitor consists of two, essentially identical, partial plates (KU1) and (KU2) made of zinc sheet. They both have the dimensions of 27 × 160 cm ² . The two parts of the lower capacitor plate (KU1) and (KU2) are V-shaped, at an obtuse angle to each other under the coil assembly on the cross member (B2) attached.

The shape of the two parts of the lower capacitor plate (KU1) and (KU2) can be seen in the top view in Fig. 4. Their mutually adjacent edges are located under the sink arrangement (SP) and are not shown. In this figure, the support of the Spulenan arrangement (SP) on the cross member (B3) under the head part (K) of the couch is shown. The core (KE) of the coil lies on this cross member. The core is shown in dashed lines in the coil arrangement. The cross bar, on which the other end of the coil arrangement rests ((B1) in Fig. 3), is located under the beam that forms the foot end of the bed. This is also the case for the cross member on which one end of the lower condenser plates rests ((B2) in Fig. 3). The cross bar, on which the other ends of the lower capacitor plates rest, is located under the cross bar (B1). The four electrical leads of the two parts of the lower capacitor plates (two per part) are brought together (K2).

The magnetic field is generated by a coil arrangement (SP) which is shown in Fig. 5. The coil arrangement has a total length of 180 cm. The actual coil body, made of hard plastic, has a length of 160 cm. The outer diameter of the coil is 12 cm. An iron pipe with an outer diameter of 1.5 inches and a wall thickness of va. 2 mm, as is commonly used for the installation of water pipes. A wooden disc (S) forms the lateral end of the windings, one of which is drawn.

Lacquered copper wire was used as the electrical conductor of the coil Diameter of 0.8 mm used. A total of four individual coils superimposed, wound on the bobbin. So there is Coil arrangement consisting of four, essentially concentric individual coils. Each of the four individual coils has approximately 2,000 turns.

The upper plate of the capacitor is preferably designed as an electrically conductive, flexible layer with an area of 100 × 160 cm ² . This can preferably be placed on the patient like a blanket. The lowest possible stiffness of the upper plate is advantageous. In a preferred embodiment, the upper plate of the capacitor consists of an electrically conductive blanket, tarpaulin or foil. The upper plate preferably consists of an electrically insulating and an electrically conductive material. The electrically conductive material is incorporated into or applied to the insulating material. The electrically conductive material can be in various forms, for example in the form of one or more layers or in the form of individual or interwoven threads. Exemplary embodiments of the upper plate are blankets with woven-in metal threads, for example copper, silver or gold threads, the latter being advantageous due to their high conductivity and the fact that they can be realized with very small diameters. Further exemplary embodiments are metal foils, such as aluminum foil, for example, or metallized plastic foils, such as foils coated with aluminum. These metallic or metallized foils are preferably applied to a blanket or tarpaulin or particularly preferably incorporated between two blankets or tarpaulins.

A device with the designation "Arbitrary Si gnalgenerator ", type WG 1240 from Mair & Rohner OEG. It enables individual signal generation. He's about a cut connected to a PC and using appropriate software controls. The generated impulses can be saved if required. The (among other things also mathematically) definable signals of the Im pulse of different configuration in their biological effect become cash.

As a PC, a computer, a laptop from Vobis, Le Book, Penti clocked at 90 MHz processor. Minimum requirement for This preferred constellation is a 486 PC with a co-processor.

An interconti® brand amplifier was used as the low-frequency amplifier used. The maximum output power is 4 × 160 watts 4 × 55 watt nominal power (sine). The frequency range extends from 10 Hz to 40,000 Hz. Each of the four individual coils is connected to its own Ka nal of the amplifier connected.

A "PCS32" digital storage oscilloscope was used as the measuring device from Vellemann. This oscilloscope can have three single radio executions. It includes a digital double-beam oscilloscope, one Fast Fourier transform frequency analyzer and a frequency recorder. You can switch between the three functions as required.

Like the function generator, the oscilloscope has an interface with connected to the PC and can by means of an appropriate Program can be controlled.

The input signal and the reactions of the Or mechanism on this input signal based on the probe signal.

The signal of the function generator (see Fig. 2: 1 , connection 12 ) is with a two-pole line to one channel of the oscilloscope ( 2 , to circuit 21 ) and from there to the inputs ( 41 , 51 , 61 and 71 ) of the four channels of the amplifier ( 4 to 7 ) passed. The amplified signals are routed from the outputs of the four channels of the amplifier to the four coils (S11 and S12 to S41 and S42). The capacitor plates are connected in parallel to the coils (K1 to 6 and K2 to 7 ). The signal from the probe on the patient (P1) is picked up by the second channel of the oscilloscope ( 2 , connection 22 ). The data of the two channels of the Oszil loskops ( 2 , output 23 ) are taken over by the computer via an LPT1 connection ( 3 , input 32 ). The computer program optionally controls the function generator ( 1 , connection 11 ) via the COM1 output ( 31 ) and the oscilloscope ( 2 , input 23 ) via the LPT1 output ( 32 ).

Example 2 Application example 1

A patient is exposed to a magnetic field in the MFTP as shown in Fig. 1. Repetitive de square wave voltage pulses of 0.5 V for 5 ms and -0.5 V for 15 ms were used as the signal of the function generator. Only the coil arrangement was activated. The signal from the measuring probe shows a deflection of approx. 0.4 V at every zero crossing of the control signal. The signal from the probe decays almost exponentially with a time constant of approx. 0.4 ms.

Example 3 Example of use 2

An increase in the amplitude of the signal from example 1 to +/- 10 V leads to almost the same signal from the measuring probe as in the application example 1.

Example 4 Example of use 3

However, the same drive signal as in Example 1 is used, however driven at the same time the capacitor field, so is the amplitude of the Si gnals of the measuring probe almost ten times larger than in the application example 1.  

Example 5 Example of use 4

As in application example 2, a signal with a voltage of 10 V (ss) used. Now the waveform is a triangular function with steeper falling and flatter rising edge. The capacitor field is not controlled. With every zero crossing of the control signal shows the signal from the measuring probe again a deflection in the order of magnitude of 0.4 V with a sign inverse to the slope of the control signal. The The deflection on the flatter side of the triangle is less high than on the steeper slope and its rise is less steep.

Example 6 Application example 5

As in application examples 2 and 4, a signal with a voltage of 10 V (ss) used. However, the waveform is now sinusoidal rounded triangular function like the triangular function of the application example 4 also with steeper falling and flatter rising flan ke. The capacitor field is not activated. At every zero crossing of the control signal, the signal from the measuring probe again shows an off beat in the order of magnitude of 0.4 V with the slope of the control inverse sign. The rash on the flatter flank of the Control signal is again less high than with the steeper edge and its ascent is less steep.

Example 7 Application example 6

The triangular function from Example 4 is used, but with an Am plitude of 0.15 V (ss). The capacitor field is not activated. It is almost no signal from the measuring probe.

Example 8 Application example 7

The triangular function from Examples 4 and 6 is used, this time with an amplitude of 0.5 V (ss). Now the capacitor became parallel field controlled. The signal from the measuring probe showed significantly larger off beats than in application example 5. (with a height of 15 V ss)  

Example 9 therapy example

A patient with the indication impetigo (a disfiguring skin crane kung) was treated with the MTFP. The individual therapy sessions each lasted 30 minutes and took place every three days towards each other. Initially, four applications were overwritten with one inductive field made. Here, however, the symptoms took off me in the course of therapy. In contrast, the Symptoms of the skin disease after switching to a predominantly no capacitive field clearly after the second therapy session and wa after the fifth session almost completely subsided.

Brief description of the pictures Fig. 1

Shows the arrangement of the field generating devices and the signal recording probe relative to the patient. The capacitor is only shown schematically and the couch and the fastening elements for the spool lenanordnung and the lower capacitor plate and the Niederfre frequency amplifier are not shown. P patient,
KU lower capacitor plate,
KO upper capacitor area,
SP coil arrangement,
K core,
L lying surface,
SO measuring probe,
S11 and S12 first coil,
S21 and S22 second coil,
S31 and S32 third coil,
S41 and S42 fourth coil,
K1 upper capacitor plate,
K2 lower capacitor plate and
P1 probe,

Fig. 2

Shows a block diagram of the magnetic field therapy device of the example. The electrical connections of the field generating devices and the measuring probe are numbered as in Fig. 1. 1 function generator,
11 signal input (optional),
12 signal output (two-pole),
2 oscilloscope,
21 input first channel,
22 input second channel,
23 input control signal and output first and second channel,
3 computers,
31 output control signal function generator,
32 output to the oscilloscope: control signal and inputs first and second channel from the oscilloscope,
4 to 7 four channels of the low frequency amplifier,
41 , 51 , 61 and 71 inputs of the channels of the low-frequency amplifier (two-pole).

Fig. 3

Shows the magnetic therapy place from the foot side of the patient. P patient,
L couch,
SP coil arrangement,
B1 fastening element for coil arrangement,
B2 fastening element for the lower capacitor plate and
KO upper capacitor plate (ceiling),
KU1 and KU2 both parts of the lower capacitor plate.

Fig. 4

Shows the arrangement of the coils relative to the couch and to the lower capacitor plate from above. The surface of the bed is removed. The connections of the lower capacitor plate are as shown in Fig. 2. The connections of the coil arrangement are not shown. R frame of the bed,
K head part of the bed,
KE core,
KU1 first part of the lower capacitor plate,
KU2 second part of the lower capacitor plate,
K2 connection of the lower capacitor plate and
B1 fastening element for coil arrangement,

Fig. 5

Shows the coil arrangement. The windings of the coils are partially removed to show the core. Furthermore, only the connections are drawn on one side. KE core,
SP coils,
S disc and
Sn1, n = 1 to 4 connections of the coils.

Claims (10)

1. comprising magnetic field therapy device

• a) one or more pulse generating device (s)
• b) one or more field generating device (s),
• c) one or more measuring and control devices and
• d) optionally a computer system.

2. Magnetic therapy device according to claim 1, characterized draws two or more field generating devices summarizes. 3. Magnetic field therapy device according to at least one of the claims 1 and 2, characterized in that there is one or more inductive Field generating device (s) comprises. 4. Magnetic therapy device according to at least one of the claims 1 to 3, characterized in that there is one or more inductive Field generating device (s) which has the shape of a coil or have. 5. Magnetic therapy device according to at least one of the claims 1 to 4, characterized in that there are several inductive fields Generation device (s) comprises in the form of a coil arrangement. 6. Magnetic therapy device according to at least one of the claims 1 to 5, characterized in that there are several inductive fields generating device (s) in the form of a coil arrangement, where with each of the sub-coils an amplifier or an amplifier channel is arranged.   7. Magnetic field therapy device according to at least one of the claims 1 to 6, characterized in that there is one or more capacitive Field generating device (s) comprises. 8. Magnetic field therapy device according to at least one of the claims 1 to 7, characterized in that there is one or more capacitive Field generating device (s) comprising the shape of a condenser sators has or have. 9. Use of a magnetic therapy device according to at least one nem of claims 1 to 8 for the therapy of a patient. 10. Method for therapy of a patient, characterized in that a magnetic therapy device according to at least one of the claims sayings 1 to 8 is used.