RU2166925C1 - Device for saturating blood with hemopoietic cells - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has active resistance electrode, power supply source, accumulation capacitor, electronic control unit, charging unit of the accumulation capacitor, impulse coordination unit, indication unit and passive electrode. The accumulation capacitor provides electric power supply of the impulse coordination unit by means of low-power power supply source. It enables one to form high stability active electrode heating impulses. The electronic control unit has analog-to-digital converter and microprocessor unit controlling operation of the charging unit useable for controlling heat impulse power magnitude. The active electrode is manufactured from a piece of steel wire not longer than 3 mm. EFFECT: enhanced effectiveness of therapy. 11 cl, 3 dwg

Description

 The invention relates to medical equipment, namely to devices used in physiotherapy (reflexology) to search for the location of reflex points and thermal effects on them (thermopuncture).

 Known devices for reflexology, in which the search for biologically active (reflex) points (BAP) by measuring the electrical characteristics of the skin at the point of contact and the impact on these points, for example, by thermal pulses.

 In this case, the measured electrical characteristics of the skin can be, for example, the point potential (RF, c. N 96110963, A 61 H 39/00) or electrical conductivity (RF, patent N 2106855, A 61 H 39/00). In these cases, the measurement circuit should contain two electrodes for contact with the patient - active and passive, and the passive electrode is used only to close the measurement circuit and therefore can be made in any suitable form, for example, in the form of a metal tube that the patient takes in his hand , or in the form of a flat electrode fixed on his body.

 Search for BAT and its thermal effect is carried out using a point active electrode - a small-sized element that is in thermal contact with a thermocouple, which can be heated by passing electric current through it or in another way, for example, by absorbing the energy of optical radiation (USSR, and S.S. N 1588417, A 61 H 39/00). When heated by electric current, the Joule heat generated on the resistor (for example, RF, patent N 2072829, A 61 H 39/00) or Peltier or Thompson contact effects in thermocouples or thermopiles (USSR, A.S. 1393423, A 61 H 39 / 00). In this case, the highest heating-cooling rate in a heat pulse can be achieved with a resistive active electrode, in which Joule heat is released. In it, a thermocouple made in the form of a wire or film heater is simultaneously an electrode used to search for BAT. Thus, electrical energy is converted into heat directly in the element in contact with the BAT. This allows you to extremely reduce the mass of heated elements and thereby reduce their thermal inertia.

The therapeutic effect of the use of such devices is determined by the amount of heat transferred, i.e. the maximum achievable heating temperature of the point active element and the frequency of receipt of thermal pulses on the BAT. However, the large thermal inertia of the active electrode limits both the achievable amplitude of the thermal pulses and the frequency of their repetition, because, firstly, with a heat exposure time of more than 0.3 s, pain develops already at temperatures of 80-100 ^o C, and secondly , the frequency of repetition of thermal pulses on the BAT is limited by both the duration of the actual exposure pulses and the duration of the interval between them, necessary for cooling the active element and relaxation of pain.

A device for reflexology is known, namely the Ventura PTP-1 device, which contains a resistive active electrode, a passive electrode, an AC power supply, a skin resistance measurement circuit at the touch point of the active electrode, an active electrode heating pulse generator, a frequency generator repetition of heating pulses, controls for operation parameters of the device and indicator. The active electrode that implements the invention according to the patent of the Russian Federation N 1825312 is made in the form of a piece of nichrome wire with a diameter of 0.14 mm and a length of 2 mm, which is fixed in massive current-carrying electrodes and placed in a remote unit connected to the device with a flexible two-wire cable that supplies heating current , the value of which is set by a chain with series resistive regulation. The frequency of arrival of the heating pulses varies stepwise and takes values of 0.5, 1, 2 Hz, and the duration of the heating pulse varies in the range of 100 - 300 ms. The temperature of exposure to the patient is regulated by changing the heating current and in the absence of contact of the active element with BAP, the temperature of the latter can reach 500 - 600 ^o C.

 A characteristic feature of the known device is the long duration of the heating pulses, which is several times higher than the cooling time constant of the nichrome wire used in the active electrode. As a result, a significant part of the energy expended is allocated to the electrodes, which reduces the maximum achievable temperature of the active element, leads to undesirable overheating of the electrodes and the heating of the entire remote unit, and a decrease in power while increasing energy consumption. From the point of view of physiotherapeutic effects, design flaws are expressed in the insufficiently effective amplitude of the heat pulse and the insufficiently high pulse repetition rate. In addition, power from the AC network limits the autonomy and mobility of the device.

 A device for reflexology (a.s. N 1588417, A 61 H 39/00, USSR) is known, comprising an active and passive electrodes, a heat exposure unit with a master oscillator, a modulator, a first power amplifier and a thermal infrared (IR) emitter connected in series, connected to the active electrode, a control unit including the first and second generators, a modulating pulse generator, a synthesizer and logic circuit with a switch, as well as a power supply connected, like the control unit, to another switch, the output of which dklyuchen to control unit which is connected to the second input of the active electrode.

 Of the three types of pulse sequences generated by the generator of the control unit, a synthesizer, the operating mode of which is set manually or automatically using a programmable timer, a working pulse sequence of the required type is formed, which, after processing in the logic circuit, is fed to the active electrode to influence the BAT, which are searched for the magnitude of the ohmic resistance in the external circuit between the active and passive electrodes when moving the active electrode along the skin the patient’s shelter.

 The known device allows you to accurately search for BAT using the special operating mode of the control unit, which provides a light indication of their location, and also simultaneously and alternately act on BAT with electrical pulses of the desired shape and duration of their packs, concentrated thermal IR radiation with different modulation frequencies.

 However, the applied method of heating the active electrode by successively converting electrical energy into optical energy and then into thermal energy causes such disadvantages of the known device as the low energy efficiency of the power supply unit, the significant thermal inertia of the active electrode and the inability to reach a sufficiently high temperature, as well as low accuracy setting and setting the desired exposure temperature. Significant disadvantages of such a device include the relatively large dimensions, mass and heat capacity of the active electrode, which makes it difficult to control and adjust exposure parameters at the point of contact with the BAT. These factors significantly limit the effectiveness of the therapeutic effect.

 A known device for reflexology, including active and passive electrodes, a power supply, a control unit with an indicator and a control unit, is selected as the closest analogue of the claimed invention.

 The objective of the invention is to increase the effectiveness of therapeutic effects by increasing the energy of the pulsed thermal effects and the frequency of impulses, as well as providing long-term autonomy while maintaining a high level of electrical safety.

 The problem is solved in that the known device for reflexology, including active and passive electrodes, a power supply, a control unit with an indicator and a control unit, in accordance with the invention is equipped with a storage capacitor, a storage capacitor charge unit and a pulse coordinator, while the control unit and the control unit combined into an electronic control and control unit, to which an indicator is connected, the power supply unit is connected to the power input of the charge unit, the second, control, the input of which is connected to the first the output of the electronic control and control unit, and the output of the charge unit is connected to the first input of the electronic control and control unit, a storage capacitor and the power input of the pulse coordinator, the control input of which is connected to the second output of the electronic control and control unit, and the output to the active electrode, which is connected to the second input of the electronic control and control unit, and the passive electrode is connected to the third output of the electronic control and control unit, while the active electrode is en resistive.

 In addition, the electronic control and control unit is made in the form of a paired multi-channel analog-to-digital converter (ADC), the inputs of which are the inputs of the unit, and a microprocessor device (MPU), the outputs of which are the outputs of the unit.

 In addition, the resistive active and passive electrodes are connected to the inputs of the ADC and the outputs of the MPU through measuring resistors.

 In addition, the charge unit is made in the form of an accumulation-discharge device for magnetic field energy.

 In addition, the pulse coordinator is made in the form of a phase inverter stage with transformer coupling, in which the output winding is connected directly to the resistive active electrode.

 In addition, a digital or alphanumeric indicator is selected as an indicator, which is connected by a bus to the outputs of the MPU.

 In addition, the power supply contains batteries or galvanic cells.

 In addition, the device is equipped with a switch installed in the circuit of the storage capacitor charge unit with the possibility of simultaneously connecting its input to the power supply or an external DC source, and the output, respectively, to the power input of the pulse coordinator or power supply.

 In addition, the device is equipped with a manual control panel, which has at least two contact elements and is connected to the MPU.

 In addition, the active electrode, the storage capacitor, the pulse coordinator and the manual control panel are structurally combined and placed in one housing.

 In addition, the resistive active electrode is made in the form of a piece of wire with a length of not more than 3 mm fixed in holders with high thermal and electrical conductivity.

 The technical result of the invention consists in the most complete use of the low thermal inertia of the resistive active electrode, which allows to improve the therapeutic characteristics of the device (to increase the thermal energy transmitted to the BAT in one thermal pulse, and to increase the frequency of impulses), as well as to increase the energy efficiency of the power supply and accuracy of setting exposure parameters.

 The invention is illustrated in FIG. 1, which presents: a) the main block diagram of the inventive device, and b) a block diagram of the device, supplemented by a switch for connecting to an external power source and a hand control panel; FIG. 2, which shows a flow diagram of a storage capacitor charge unit, and also FIG. 3, which shows the execution scheme of the pulse matching device.

 The device contains a resistive active electrode 1, a power supply 2, a storage capacitor 3, an electronic monitoring and control unit 4, a charge capacitor 5 charging unit, a pulse coordinator 6, an indicator 7, a passive electrode 8. The electronic monitoring and control unit 4 includes conjugated multi-channel ADCs 9 and MPU 10, and the inputs of the ADC 9 are the inputs of block 4, and the outputs of the MPU 10 are its outputs.

 In the device (Fig. 1a), the power supply unit 1 is connected to the power input of the charge unit of the storage capacitor 5, the second (control) input of which is connected to the first output of the electronic control and control unit 4 (MPU 10 output). The output of the charge unit 5 is connected to the first input of the electronic control and control unit 4 (ADC input 9), a storage capacitor 3 and the power input of the pulse coordinator 6, the control input of which is connected to the second output of the electronic control and control unit 4 (second output of the MPU 10), and the output of the pulse coordinator 6 is connected to the active electrode 1, which is connected to the second input of the electronic control and control unit 4 (second input of the ADC 9). The use of conjugated ADCs 9 and MPU 10 provides high accuracy control and management of the operation of the device as a whole. The passive electrode 8 is connected to the third input of the monitoring and control unit 4 (the third input of the ADC), so that, closing itself through the patient, together with the built-in measuring resistors forms a measuring circuit, for example with those shown in FIG. 1b, resistors 11a, 11b and 12 show a bridge circuit.

 The indicator 7, which is preferably made in the form of a digital or alphanumeric indicator, is connected to the MPU 10 bus, which allows you to carry out the required control over the course of exposure to the patient by displaying the resistance of the skin at the touch point of the active electrode 1 when searching for BAP, as well as current device operation parameters during a therapy session.

 The storage capacitor 3 provides a large pulsed power supply to the pulse coordinator 6, to which the active electrode 1 is connected, and reduces the power requirements for the low-voltage power supply unit 2, from which it is charged to a given voltage using the charge unit 5 in the interval between active heating pulses electrode 1, as well as stabilize the device when changing the EMF or internal resistance of the power supply 2. The capacitance of the capacitor 3 and its charging voltage, to This is the input voltage of the pulse coordinator 6, they are chosen large enough so that the voltage change across the capacitor 3 during the heat pulse is insignificant, or limited to safe values, eliminating the possibility of overheating and melting of the active electrode in the event of an emergency malfunction of the device when opening pulse coordinator 6 for a long time.

 The power supply 2 contains as sources of direct current batteries or galvanic cells. To recharge them from an external DC source, the device is equipped with a switch with contact groups 13a, 13b installed in the circuit of the charge unit of the storage capacitor 5 (Fig. 1b). The switch is installed in such a way that in the case of operation of the device from the power supply unit 2, it supplies current through the charge unit of the storage capacitor 5 to the storage capacitor 3 and the pulse coordinator 6 in accordance with the main block diagram (Fig. 1a). If it is necessary to recharge the batteries of the power supply unit 2 from an external direct current source, the contact group of the switch 13a connects the power input of the charge unit 5 to an external source, and the output of the charge unit 5 by the contact group of the switch 13b is connected to the power supply 2 through the charging resistance 14, breaking the active electrode power circuit 1 through a pulse coordinator 6. To control the voltage of an external source, the corresponding terminal is connected to the additional input of the ADC 9. In this mode, when applying voltage from an external source MPU 10 generates a signal that switches the charge unit 5 to work in the mode of stabilization of the battery charge current.

The power consumed by power supply 2 is small. To ensure a pulse repetition rate of 10 Hz at a pulse energy of E _n.max = 0.2 J, the required power of power supply 2 is 2 watts. This power can very well be obtained from modern miniature batteries or galvanic cells.

 The charge unit of the storage capacitor 5 can be made, in particular, in the form of a device for a drive-dumping energy of a magnetic field (Fig. 2). It contains a choke 15, one end of which is connected to a power supply 2 or an external power supply (+ V), and the other to a transistor switch 16 and through a rectifier diode 17 with a load, contact group 13b of the switch and a storage capacitor 3, or a battery charge circuit . Such a design of the charge unit 5 makes it possible to charge the storage capacitor 3 to the required voltage and to stabilize the energy supplied to the storage capacitor 3 in one pulse, or to stabilize the charge current of the battery. When the device is operating, the MPU 10 supplies unlocking pulses to the transistor switch 16, and the duration of these pulses is determined by the input voltage of the unit, and the required number of pulses and their frequency are calculated based on the known values of the required power and total energy transferred to the load. MPU 10, if there is voltage at the terminal of the external source, sets the charging unit 5 to stabilize the battery charging current, and in the absence of an external source, sets the charge mode of the storage capacitor 3. If necessary, control the current of the sub-charge of the batteries by the voltage drop across the charging resistance 14.

 The pulse coordinator 6 can be made, in particular, according to the scheme of a phase-inverter cascade with transformer coupling (Fig. 3), for which the source of the input voltage supplied to the primary winding of the transformer 18 is a storage capacitor charged to the required voltage 3. The current circuit of the primary winding of the transformer 18 are switched by transistor switches 19a and 19b, and the output winding of the cascade is connected directly to the resistive active electrode 1. The ratio of the number of turns of the primary and secondary windings ransformatora 18 defined by the input voltage, the resistance value R of the resistive electrode and an active pulse power required being heated W.

The resistive active electrode 1 can be made in the form of a piece of metal (steel) wire with a length of not more than 3 mm, and it must be fixed in holders with high thermal and electrical conductivity. Therefore, the value of W is chosen large enough so that the heating of the active electrode 1 to the required temperature occurs in time (t _and ), much less than the time constant of its cooling due to heat removal to the electrodes and other structural elements in contact with it.

 For ease of use, the device can be equipped with a manual control unit 20, in addition to block 4. Such a remote control for connecting to the MPU 10 inputs makes it possible to select the device operating mode — search for BAT, therapy, setting the required amplitude, frequency of repetition of thermal pulses and their number in one session. The hand control 20 may comprise two or more contact elements (not shown in FIG. 1).

 At the same time, it is convenient to constructively combine the active electrode 1, the pulse coordinator 6, the storage capacitor 3 and the manual control panel 20 in one housing 21, which forms the remote head of the device, which allows for greater comfort of the procedure.

 The device operates as follows.

 In the BAT search mode, the passive electrode 8 is in contact with the patient, for example, is clamped in the hand. At the electrodes 1 and 8 from the MPU 10, the output potentials are high or low. At the same time, the ADC 9, by commands from the MPU 10, measures the potentials on the electrodes 1 and 8. Based on the measured potentials and the known values of the measuring resistances, the MPU 10 calculates and reflects on the indicator 7 the value of the external resistance between the electrodes, i.e. skin resistance. In this case, the location of the BAP is found by the minimum value of the displayed resistance. When the device is executed without an ADC and MPU, the electronic control and control unit 4 may contain, for example, a well-known ohmmeter circuit with resistance indication with a dial gauge.

When the device is switched to therapy mode, the charge unit 5 starts operation and the storage capacitor 3 is charged to a predetermined voltage U _s . After that, the electronic monitoring and control unit 4 generates an opening impulse of duration t _and , which is the enable signal for the operation of the coordinator 6, or when constructing the coordinator 6 according to the circuit of FIG. 3 - directly corresponding to the sequence of control pulses of transistor switches 19a and 19b. The power transmitted in this case to the active electrode 1 is determined by the selected parameters of the device circuit and voltage U _s . It is approximately constant and changes during the action of the heating pulse according to a simple exponential law, which can be taken into account when setting the time t _and necessary for heating the active electrode to the required temperature.

The maximum temperature and time intervals between pulses are set by the operator. Constancy of the energy consumed in each pulse heating of the active electrode 1, provided persistence value _and t and recovery of the desired voltage U _c of the capacitor 3 in the intervals between pulses. The necessary accuracy in the execution of U _c can be provided by feedbacks in the internal control circuits of unit 5 or due to feedback through the ADC 9 and MPU 10 if the charge unit 5 is made according to the scheme of FIG. 2 and the control and management unit 4 contains an ADC and an MPU. In the latter case, when the device is turned on, the MPU 10 generates a given initial series of pulses that control the operation of the transistor switch 17 of the charge unit 5, at the end of which the ADC 9 measures the achieved voltage at the storage capacitor 3, and calculates the required number of additional charge pulses from the measured value of the MPU 10. The cycle of recharging - monitoring - calculating the number of necessary additional pulses is repeated until the specified potential U _{s is} reached, after which a sign of device readiness is formed. MPU 10 generates the next heating pulse t _and after a specified time interval between pulses is set by the operator in the presence of a sign of readiness.

The proposed device can also be implemented algorithm for adjusting the energy of the thermal pulse according to the value of the actual electrical energy expended on it. Since the charge unit 5 is disconnected during the action of the heating pulse, the value of this energy can be determined by changing the voltage on the storage capacitor 3. At the end of the heat pulse, the ADC 9 measures the voltage U _c2 remaining on the storage capacitor 3, and the known values of U _c , U _c2 and known capacitor 3 and the energy conversion efficiency, the LPA recorded in the memory 10 for programming, MPU 10 calculates the amount of energy expended in heating and if necessary adjusts the duration of the next cpm lsa t _and.

The proposed device provides greater heating capacity of the resistive filament active electrode, thereby minimizing the heating of the pulse duration _and t and minimizing heat losses for unproductive overheating electrodes, in which the filament is attached. Heat loss on heating of the electrodes are determined by the ratio of t _and the cooling time constant and τ electrode _OHL determined heat capacity, density and thermal conductivity of the material strand, as well as its length.

For steel wire filaments with a length of not more than 3 mm and a diameter of 0.2 mm fixed in massive heat-removing electrodes, the value of τ _cool is about 0.065 s, and the electrical resistance is about 0.1 Ohm. To heat it to a temperature T _n = 150 - 750 ^o C requires an energy E _{n of the} order of 0.04 - 0.2 J.

You can show / A.N. Tikhonov, A.A. Samara. Equations of mathematical physics. M., Nauka, 1966, 724 pp. /, That in the general case, when the filament is electrically heated, the temperature at the center of the filament will vary according to the law with uniform heat dissipation and heat dissipation in volume
T (0, t) = T _max [1-exp (-t / τ _cool )], (1)
where T _max is the temperature at which the heat sink to the electrodes is equal to the electric heating power. Hereinafter, the temperature is measured from room temperature, taken as zero.

At the beginning of heating, the temperature varies linearly with time and at the full duration of the heating pulse t _and ≅ τ _cool = 5 ms, dependence (1) will be almost linear, the energy loss to the heat sink to the electrodes will not exceed 5%, and the nonlinearity of the temperature dependence on the pulse duration will not exceed 10%.

 For such a quick warm-up, the average electric pulse power should be W = 40 W, the average current I = 20 A, the voltage drop across the filaments U = 2 V. With a transformation coefficient of m = 0.1 in the pulse coordinator 6, constructed according to the circuit of FIG. 3, the input of the coordinator 6 must be supplied with a voltage of V = 20 V, while the input current consumption (discharge current of the storage capacitor 3) will be 2 A.

The minimum allowable time interval between two consecutive thermal pulses is determined by the time the heater cools to a temperature below the pain threshold, i.e. below 80 ^o C, which corresponds to an excess temperature of 50 ^o C. Since the electrodes on which the ends of the wire heater are fixed practically do not heat up during the action of the electric pulse, their temperature can be considered constant and equal to room temperature. In this case, the law of decreasing the temperature of the filament in time after the end of the heating pulse can be considered purely exponential:
T (t) = T _o exp (-t / τ _cool ), (2)
where T ₀ is the maximum temperature of the thread.

During the time t = 3τ _OHL, t. E. Less than 200 ms (in contact with BAP τ _OHL will be reduced due to the heat sink through the side surface of the thread), the excess temperature decrease 20 times. Therefore, the device allows to increase the frequency of the supply of heating pulses to at least 5 Hz. At lower maximum temperatures and with effective heat removal to the BAP, the pulse arrival frequency can be further increased.

To ensure a pulse repetition rate of 10 Hz at a pulse energy of E _nmax = 0.2 J, the required net power of the power supply will be 2 W, and taking into account the real efficiency of the converter, not more than 3 W.

The safety of the proposed device is determined by the absence of dangerous voltage sources, as well as the exclusion of possible injuries due to the melting of the filament of the active electrode 1 in contact with the patient. Such a danger can arise only when using a large glow power in the event of such a malfunction in the control system of the coordinator 6, which will lead it to turn on for an unlimited time. In the proposed device, it can be eliminated by appropriate selection of the capacitance of the storage capacitor 3 and the energy stored on it. Continuously filament pulse capacitor 3 is discharged with a time constant τ _p .Mozhno show that at a ratio τ = 3τ _{p OHL} pulse duration of the maximum temperature unlimited, subject to shrinking during heating time, power and increasing heat transfer on the electrodes, will be achieved for the time t _max = 1,1τ _p . In this case it is ≈ 1,64 times higher than the temperature attained by the time 0,3τ _p = 0,1τ _OHL. Thus, if the maximum temperature achieved at time t = 0,1τ _OHL should be ≈ 750 ^o C, even in the event of said failure in the control system the maximum filament temperature is 1230 ^o C, which is below the melting temperature of stainless steel (more 1400 ^o C).

The indicated ratio of the cooling times of the thread τ _okhl , the discharge of the capacitor τ _p and the maximum duration of the thermal pulse t _and corresponds to the fact that during time t _{and the} storage capacitor 3 is discharged by no more than 30%, which is acceptable for the amplitude of the low-frequency variable component of most modern high-capacity capacitors .

Estimates show that the total efficiency of the claimed device in the manufacture on a modern elemental base will be more than 75%, which is due to the high efficiency of pulsed energy conversion circuits. In this case, the total energy for a series of 200 pulses of maximum energy E _n = 0.2 J will be less than 55 J. The electrodes of a resistive heater with their mass of 10 g will warm up by about 1 ^o C. It follows that the device as a whole provides high performance , and in the case of using small-sized rechargeable batteries in the power supply unit - long-term autonomy. So, four series-connected elements with a capacity of up to 0.9 Ah • will provide a supply voltage of 4.8 V and a total energy of more than 15.5 kJ. Low power consumption is typical for microprocessor-based devices of the ADC 9 and MPU 10. Typical values of the consumption currents of such microprocessors are less than 10 mA at a supply voltage of about 10 V. With a total current of consumption in the elements of the electronic control and control unit of 20 mA and the intensity of 20 series of pulses per hour (in a series of 200 pulses of maximum power), the battery life without recharging the batteries will exceed 10 hours, which is comparable to the duration of the working day.

 The proposed device, made on a modern elemental base, provides fast heating of the resistive active electrode, a wide range and high accuracy of the execution of the set values of the energy of the thermal pulse and the pulse repetition rates at high electrical and injury safety reflexology procedures for the patient, has a high efficiency of using the energy of an autonomous power supply and thereby solves the task of increasing the effectiveness of therapeutic effects and ensuring long-term autonomous STI works, which makes the device very promising for widespread use.

Claims (11)

 1. Device for reflexology, including active and passive electrodes, a power supply, a control unit with an indicator and a control unit, characterized in that it is equipped with a storage capacitor, a storage capacitor charge unit and a pulse coordinator, while the control unit and the control unit are combined into a unit electronic control and management, to which the indicator is connected, the power supply is connected to the power input of the charge unit, the second, control, the input of which is connected to the first output of the electronic control unit control and control, and the output of the charge unit is connected to the first input of the electronic control and control unit, a storage capacitor and the power input of the pulse coordinator, the control input of which is connected to the second output of the electronic control and control unit, and the output to the active electrode, which is connected to the second the input of the electronic control and control unit, and the passive electrode is connected to the third output of the electronic control and control unit, the active electrode being made resistive.  2. The device according to claim 1, characterized in that the electronic control and control unit is made in the form of a paired multi-channel analog-to-digital converter, the inputs of which are the inputs of the unit, and a microprocessor device, the outputs of which are the outputs of the unit.  3. The device according to claim 1 or 2, characterized in that the resistive active and passive electrodes are connected to the inputs of the analog-to-digital Converter and the outputs of the microprocessor device through the measuring resistors.  4. The device according to claim 1, characterized in that the charge unit is made in the form of a storage device for dumping magnetic field energy.  5. The device according to claim 1, characterized in that the pulse coordinator is made in the form of a phase inverter stage with transformer coupling, in which the output winding is connected directly to the resistive active electrode.  6. The device according to claim 1, characterized in that a digital or alphanumeric indicator is selected as an indicator, which is connected by a bus to the outputs of a microprocessor device.  7. The device according to claim 1, characterized in that the power supply unit contains batteries or galvanic cells.  8. The device according to claim 1, characterized in that it is equipped with a switch installed in the circuit of the storage capacitor charge unit with the possibility of simultaneously connecting its input to the power supply or an external DC source, and the output, respectively, to the power input of the pulse coordinator or power supply .  9. The device according to claim 1, characterized in that it is equipped with a manual control panel, which has at least two contact elements and is connected to a microprocessor device.  10. The device according to claim 1, characterized in that the resistive active electrode, the storage capacitor, the pulse coordinator and the hand control are structurally combined in one housing.  11. The device according to claim 1, characterized in that the resistive active electrode is made in the form of a piece of wire with a length of not more than 3 mm fixed in holders with high thermal and electrical conductivity.

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