DE1175372B - Electric stimulation current device - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Class: H05g

German class: 21g- 24/01

Number: 1175 372

File number: Y 573 VIII c / 21 g

Filing date: March 20, 1962

Opening day: August 6, 1964

The invention relates to an electrical stimulation current device for muscle stimulation with a low frequency Alternating stimulus voltage, the waveform of which is that which occurs when a nerve is electrically stimulated Corresponds to nerve waveform.

It is already known for therapeutic devices to use low-frequency square waves or simple ones To use impulse waves. Square waves allow a strong passage of current through the body to be treated, but are not suitable for activating the muscles. Waves in Simple impulses can be used to activate muscles, but they can cause them they have muscle pain in the body.

It is also already known for electrical stimulation of the heart by the high-frequency voltages To modulate the patient's pulse rate at a low frequency.

According to the invention, the above-mentioned disadvantages are eliminated in that an electrical Stimulation current device for muscle stimulation of the type mentioned is designed so that by a Tube or transistor oscillator a low-frequency alternating voltage corresponding to the nerve wave is generated which its shape corresponding to the nerve wave by appropriate setting of the value of a capacitor and / or resistor in the oscillating oscillator, and that this AC voltage a high-frequency AC voltage is superimposed.

Treatment with such a stimulation current device now has the advantage that activation of the Muscles can be reached with a relatively weak current, so that neither is the risk of a Burn still exists also caused by treating pain.

It has been experimentally confirmed that for a massage of a stiff shoulder by stimulating the Muscles a tension in the form of a nerve wave is more effective, because the current is less causes the same muscle movement as the square wave.

In the case of the electrical healing device according to the invention, an output control circuit is preferably provided, so that the effect of battery depletion is minimized and voltage changes can be kept small.

Embodiments of the invention are explained with reference to the drawing in which

B i 1 d 1 shows the shape of a nerve wave;

B i 1 d 2 is a circuit diagram of an oscillating circuit using vacuum tubes;

Electric stimulation current device

Applicant:

Sutetaro Yamashiki, Fukiaiku, Kobe (Japan)

Representative:

Dipl.-Chem. Dr. L. Wessely, patent attorney,

Munich 19, Montenstr. 9

Named as inventor:

Kazuzo Masaki, Toyonaka City, Osaka (Japan) - -

Figures 3 to 5 show the waveforms of the voltages appearing in the circuit of Figure 2; B i 1 d 6 is a transistorized circuit;

B i 1 d e r 7 to 10 show the waveforms of the voltages occurring in the circuit of Fig. 6;

Figure 11 is a control circuit with an oscillating circuit;

B i 1 d 12 explains a schematic output circuit;

B i 1 d 13 shows the output circuit of the preferred embodiment of the invention;

B i 1 d 14 shows a front view of a healing device which contains the device according to FIG. 11;

B i 1 d 15 is a side view of the device of Figure 14.

Figure 1 shows the waveform of a nerve wave as it is emitted by the nerve tissue of a warm-blooded animal when an electrical impulse is sent through this tissue. For this purpose, a nerve fiber of a warm-blooded animal was taken out, and at the point in time α , an electrical pulse with a voltage of 0.5 to 30 volts was applied to the tissue. After about V1000 seconds, a voltage developed at time b, and the voltage profile corresponded to curve cde f. The waveform of healthy nerve tissue generally corresponds to the curve shown in Figure 1, although slight deviations may occur due to vitamin deficiency and other causes .

There can be no doubt that healing effects can be obtained by looking at the human Body applies a voltage whose artificially generated waveform corresponds to the shape of the nerve wave.

The circuit of a blocking oscillator shown in B i 1 d 2 contains a transformer T, vacuum

409 639/288

tubes V ₁ and F ₂ and an oscillator OS. By appropriately setting the capacitor C and the resistor R , a waveform can be generated which is similar to the waveform of the nerve voltage. The frequency of this wave is determined by the capacitor C ₁ and the resistor R ₁ . In this circuit, the voltage appearing at the transformer T has a waveform which corresponds to the curve G in B i 1 d 3. This curve G represents a waveform corresponding to nerve tension, and when a voltage having this waveform is directly applied to the human body, the patient feels a sharp pain. If, however, as shown in B i 1 d 2, the voltage in the form of the nerve wave from the vacuum tube F ₁ and a voltage output by the oscillator OS , i.e. a voltage with a frequency of 20 to 100 kHz (see Fig. 4 ), with the formation of an output wave with the waveform P (see Fig. 5), are mixed and this superposition wave is applied to the human body, then the patient can hardly feel any pain. However, since the refractory period, ie the time in which the human nerve does not respond, lasts less than 10000 seconds, no pain is felt on the skin up to a frequency of a few 10 kHz, but a current flows through the body, its The waveform of the envelope corresponds to the curve shown in Figure 5, so that a muscle movement is caused.

With the circuit shown in B i 1 d 6, such a waveform is generated simply by using a transistor oscillator. The B i 1 d 6 shows a transistorized blocking resonance circuit. If there is no negative resistance on the secondary side P, Q of the transformer T , an oscillation is generated that has the waveform shown in Figure 7. If only the capacitor C _{2 is} connected to the terminals P, Q , an oscillation with a waveform as shown in B i 1 d 8 occurs. If only the resistor R ₂ is connected, a wave with the shape shown in Figure 9 is formed. The wave with the shape shown in Figure 9 has a frequency of a few kilohertz. If the capacitor C ₂ and the load across the resistor R ₂ are connected together, a waveform as shown in B i 1 d 10 is obtained. The wave of the B i 1 of the 10 has a similar shape to the output wave of the picture 5, which is obtained using vacuum tubes. The equivalent resistance of the human body is given by a combination of a capacitor C and a resistor R , as indicated at B ₀ in B i 1 d 6, and if in this circuit the output terminals P, Q are connected to the human body, then one automatically obtains a wave with a shape as shown in B i 1 d 10. If the sizes of R and also C R in the transistorized circuit are dimensioned accordingly and the transformation ratio of the transformer C is selected appropriately, then one obtains a waveform as shown in B i 1 d 10, which approximates a superposition of a high-frequency voltage and corresponds to a voltage whose waveform is similar to that of nerve tension.

Corresponding dimensioning of the CR value is to be understood here as the choice of a value such that the interval between the oscillations is 1 to V10 seconds and the period of the oscillation is V * »to V1000 seconds, a high-frequency wave then being superimposed on this oscillation. In Figure 2 the interval between the oscillations is determined by C ₁ and R ₁ and in Figure 6 by C and R. The waveform of the oscillation is determined by T, C and R in the circuit according to B i 1 d 2 and by R ₂ and C ₂ in the circuit according to Figure 6.

A low frequency healing device that has very little voltage fluctuations when the electrodes are used attached to or detached from the human body is cheaper because it is lower Causes stimuli. For such a device, a voltage source must be available in which there are no large fluctuations depending on the load. To do this, it is It is desirable that the internal impedance of the output circuit in such a device be as low as is possible. This is easier to achieve with a device with vacuum tubes, with a transistor device however, which corresponds, for example, to the circuit of the picture 11, it would be because of the capacitance of the Transistor and battery depletion difficult because of monitoring the depletion of the Battery a high internal impedance of the output circuit is required.

A preferred embodiment of the invention relates to a circuit in which the smallest possible voltage changes occur with a high internal impedance, so that this disadvantage is eliminated. Figure 12 shows a circuit in which a conventional variable resistor is used to regulate the output voltage, the regulation being carried out by adjusting the sliding contact C of the variable resistor VR . If VR is 10 ohms and the sliding contact C is in a middle position, then the output voltage is about half of the input voltage E. If under these conditions a negative resistance Z = I kOhm, i.e. the human body, at terminals B and C. is connected, then the voltage is 0.14 E. Since the voltage without load was 0.5 E, this means that the voltage was reduced to about a third by switching on the negative resistor Z, ie to 0.14 E. This can be explained as follows:

At first the resistances between A and C and between B and C were each 5 kOhm. After switching on Z = I kOhm, the resulting resistance of BC and Z is 830 Ohm, and the voltage is equal to ⁸³⁰ AwOo · E, i.e. 0.14 E.

It is assumed that in the circuit according to Figure 13 a resistor R is connected between A and C, this resistor R being made approximately equal to the negative resistance Z, ie set to 1 kOhm. In order to examine the voltage change under this assumption, the sliding contact C of the variable resistor VR is first set without connecting the negative resistor Z so that 0.5 E is obtained. Then about 9 kOhms meet VR and 1 kOhm meet R between A and C, and the resulting resistance is about 1 kOhm, and the resistance between B and C is also about 1 kOhm. Under these conditions you have 1 kOhm with VR and

1 kOhm at Z between B and C, so that the resulting resistance is 500 Ohm and, accordingly, the output voltage is 0.3 E.

While 0.14 E is obtained with the circuit according to Fig. 12, 0.3 E is obtained with the circuit according to B i 1 d 13, ie the fluctuation factor is reduced to less than half. If only the voltage fluctuations are to be reduced, then it is sufficient to select the value of the variable resistor VR to be small. In the circuit of Figure 11, however, in which the output is taken directly from the transistorized resonant circuit, it would be unfavorable if the variable resistance VR were too small. In addition, since the output power is limited, a voltage drop is obtained across the variable resistor VR, and that part of the power which can flow into the human body is reduced. It is therefore desirable that the variable resistance VR is chosen to be as large as possible here.

If the variable resistance is made as large as possible, then a resistance R between A and C is switched on, and the sliding contact E is set close to A , and the power consumption in VR becomes lower since the resistance VR is large against Z.

In this way, a very useful electrical healing device is obtained, in which the battery Ba is hardly depleted with a high internal impedance and small voltage fluctuations occur if a resistor R is placed on the high potential side of the sliding contact C of the variable resistor VR in the transistorized amplifying resonant circuit switches on as shown in Figures 11 and 13.

In the device shown in Figures 14 and 15, the rotatable disk 1 represents the variable resistor VR and also serves as a switch. The roller-shaped treatment electrode 2 corresponds to the sliding contact C in figures 11 and 13. The ground electrode 3 corresponds to B in figures 11 and 13. During the treatment, the human body is connected to the grounded ground electrode 3 on the one hand and to the roller-shaped treatment electrode 2 on the other.

Claims (2)

Patent claims: 1. Electrical stimulation current device for muscle stimulation with a low-frequency alternating stimulus voltage, whose waveform corresponds to the nerve waveform that occurs when a nerve is electrically stimulated, characterized in that by a tube or transistor oscillator a low-frequency alternating voltage corresponding to the nerve wave is generated, which corresponds to its corresponding to the nerve wave Shape by setting the value of a capacitor and / or resistor accordingly received in the oscillator, and that this alternating voltage is a high-frequency alternating voltage is superimposed. 2. Stimulation current device according to claim 1 with a transistor oscillator that generates a low-frequency alternating stimulus voltage, the shape of which corresponds to a high-frequency superimposed nerve wave, characterized in that a high-value resistor (Fi?) With an adjustable tap in the form of a parallel to the secondary winding of the oscillator in the output circuit Sliding contact (C), which forms an adjustable voltage divider, and that the patient resistance is connected between one end of the resistor and the sliding contact, while a resistor (R) of the order of magnitude of the patient's resistance is connected between the other end of the resistor and the sliding contact ( Fig. 11 and 13). Considered publications:
German Patent No. 693 778;
U.S. Patent No. 3,015,333;
British Patent No. 837 713. 1 sheet of drawings 409 639/288 7.64 © Bundesdruckerei Berlin