RU6708U1 - APPARATUS FOR SCALAR MAGNETO-LASER THERAPY - Google Patents

Abstract

1. The apparatus for magnetic laser therapy, containing a ring source of constant magnetic field, a photodetector, an indicator, a sequentially connected generator, modulator and a semiconductor laser emitter, characterized in that a control unit, a coding device such as a semiconductor laser, an optical system, a timer, a matching unit, active probe, passive electrode, resistance-frequency converter connected in series, sound frequency generator and source of acoustic vibrations, while The main source of constant magnetic field and the optical system are aligned with the semiconductor laser emitter, the control input of the generator is connected to the first output of the control unit, the second, third and fourth outputs of which are connected respectively to the second input of the modulator, the timer input and the first input of the resistance-frequency converter , to the second and third inputs of which the active probe and passive electrode are connected, respectively, and to the output is the first input of the sound frequency generator, the second input of which connected to the first output of the timer, the second output of which is connected to the third input of the modulator, the fourth input of which is connected to the electrical output of the semiconductor laser emitter, and the fifth input is connected to a coding device such as a semiconductor laser, to which the first input of the matching unit is also connected, the second input of which is connected with the output of the photodetector, and the output with the indicator. 2. The apparatus according to claim 1, characterized in that the modulator comprises a control element and a current sensor connected in series to the first and

Description

Apparatus for magnetic laser therapy "Scalar

The utility model relates to medical and veterinary technology, namely, devices for physiotherapeutic exposure to laser radiation and a magnetic field in the treatment of purulent-inflammatory diseases of soft tissues, wounds, traumatic injuries of bones, diseases of inflammatory etiology, etc. in humans and animals. The device can be used in the following areas: clean and purulent surgery, outpatient surgery, plastic surgery and cosmetology, traumatology, sports and ballet injuries, gynecology and obstetrics, disaster medicine, angiology and vascular surgery, proctology, urology, pediatrics, laser acupuncture, dermatology and etc.

A device for magnetic laser therapy, containing a master pulse generator associated with a pulse distributor; controlled stable current generator associated with a laser source; a magnetic field source consisting of magnetic inductors; source of food Yeshe; keys connecting the power source and pulse distributor with magnetic inductors; a radiating head in which sources of a magnetic field and laser radiation are combined. The master oscillator is connected to a controlled stable current generator by means of a modulator that determines the shape of the laser pulses. This device is intended for the treatment of pulmonary, cardiovascular diseases, diseases of the motor apparatus, minor burns and open wounds (ed. St. USSR No. 1808339, class A 61N 5/06, 1993).

MPK6A6Sh5 / 06

A disadvantage of the known device is the lack of an objective control system for the power of laser radiation.

Closest to the claimed utility model is an apparatus for magnetic laser therapy, containing a ring source of constant magnetic field, a semiconductor laser emitter, interconnected switch and synchronizer, LEDs and a photodetector installed in the nozzle, an indicator connected to the photodetector, a current adjustment unit connected to the LEDs and a switch, connected in series with a pulse master oscillator and a pulse shaper modulator connected to a semiconductor laser th emitter, the master oscillator is connected to the second output of the synchronizer. Structurally, the apparatus consists of two components that are connected in an integral manner - an irradiating terminal in which LEDs are mounted, a semiconductor laser emitter, a photodetector, an annular source of constant magnetic field, and a control panel in which the remaining elements of the apparatus circuit are located. Between themselves, these parts are connected by an electric cable.

The continuous emission of LEDs together with the pulsed radiation of a semiconductor laser operating in the near-infrared range of the optical spectrum (0.84-0.89 μm) leads to spatially uniform mixing of the light flux in the aperture of the terminal, which makes it possible to uniformly affect both surface and and over more than a year later lying tissues of the irradiated biological object. This ensures a certain accuracy of the individual dosage of light energy during therapeutic irradiation of wounds, traumatic bone injuries, inflammatory etiology diseases, etc. (RF patent No. 2072879, class A 61N 5/06, 1997).

The reason that impedes the achievement of the technical result indicated below by using the known apparatus is as follows. The photodetector installed in the terminal measures the radiation power of several LEDs and a laser reflected from the surface of a biological object without taking into account the total amount of incident power. In case of failure of one of the emitters, the photodetector will perceive this as an increase in the absorbing ability of the irradiated surface, because no control is provided to determine which emitter is out of order. The total radiation power of the LEDs is 35-40 mW, the average power of the L11I-102 semiconductor laser is 3-4 mW, i.e. about 10% of the mobility emitted by the apparatus. Therefore, a laser failure may not be noticed. All this, along with the lack of smooth adjustment of exposure and the frequency of repetition of radiation pulses, can lead to errors in establishing an individual radiation dose and, ultimately, to a decrease in the accuracy of laser therapy. In addition, the terminal design provides only surface zonal irradiation, it excludes the possibility of using supply nozzles or optical fibers, which limits the functionality of the apparatus.

The task to which the claimed utility model is directed is the development and creation of a multifunctional low-energy therapeutic device that provides irradiation of both zones and biologically active points and internal cavities of biological objects with laser radiation with various adjustable and controlled wavelengths and mowing, which allows to increase the efficiency laser therapy in various fields of medicine and

veterinary medicine in the conditions of inpatient, outpatient and sanatorium treatment.

The technical result achieved by implementing the utility model consists in increasing the accuracy of the dosage of light energy of a laser emitter in the treatment of various diseases of the surface of the skin and internal organs of a person or animal.

The specified technical result is achieved by the fact that a control unit, a coding device such as a semiconductor laser, an optical system, a timer are introduced into a known apparatus for magnetic laser therapy, containing a ring source of constant magnetic field, a photodetector, indicator, a series-connected generator, modulator and a semiconductor laser detector; , matching unit, active probe, passive electrode, series-connected resistance-frequency converter, sound frequency generator and source a source of acoustic vibrations, while the ring source of constant magnetic field and the optical system are mounted coaxially with a semiconductor laser emitter, the control input of the generator is connected to the first output of the control unit, the second, third and fourth outputs of which are connected respectively to the second input of the modulator, the timer input and the first input the resistance-frequency converter, to the second and third inputs of which are connected an active probe and a passive electrode, respectively, and the first input is connected to the output sound frequency, the second input of which is connected to the first output of the timer, the second output of which is connected to the third input of the modulator, the fourth input of which is connected to the electrical output of the laser semiconductor from the 1 transmitter, and the fifth input is connected to a coding device such as a semiconductor laser, to which also connected is the first input of the matching unit, the second input of which is connected to the output of the photodetector, and the output is from in.

the announcer.

The modulator is made in the form of a laser beam power control device and contains a control element and a current sensor connected in series, to the first and second outputs of which a high-speed switch is connected, electrically connected to the common bus, while the inputs of the control element are the first, second, third and fourth inputs of the modulator , the second input of the current sensor is the fifth input of the modulator, and the first output of the current sensor is the output of the modulator.

The floor) conductor laser emitter is made on the basis of replaceable semiconductor lasers of the infrared or red optical wavelength ranges, in this case, lasers with an integrated photodiode are used, the output of which is the electrical output of the semiconductor laser emitter.

A semiconductor laser emitter and a coding device such as a semiconductor laser are mounted in a remote irradiator made in the form of a cylindrical body with a device for fastening an annular source of a constant magnetic field, supply nozzles or an optical system.

The inlet nozzles are made of translucent material in the form of cylindrical rods, which are bent at an angle selected in the range from O to 120 to the longitudinal axis of the rod, or in the form of a rod of a conical shape, or in the form of a fiber.

whose optical axes are aligned with the optical axis of the semiconductor laser emitter.

The matching unit contains a comparator, pulse counter, counter pulse generator, reset pulse generator, decoder, digital-to-analog converter, the comparator output being connected to the first input of the pulse counter, the outputs of the counter pulse generator and reset pulse generator respectively connected to the second and third inputs thereof, the first output of the pulse counter is connected to the decoder, and the second output is connected to a digital-to-analog converter, the output of which is connected to the first input of the comparator, while the second the second and third inputs of the comparator, the decoder output are respectively the first, second inputs and the output of the matching unit.

An RC generator of sinusoidal oscillations was used as a resistance-frequency converter.

The analysis of the prior art by the applicant showed that there are no solutions in the identified sources of patent and scientific and technical solutions, characterized by features identical to all the features of the claimed utility model. This gives reason to believe that it meets the condition of patentability “novelty.

The utility model is illustrated by drawings.

Pa fig. 1 shows a structural diagram of an apparatus for magnetic laser therapy "Scalar. Pa figure 2 presents a structural diagram of a modulator pulp laser beam. Pa fig.Z presents a block diagram of the coordination unit. Pa figure 4 shows some of the forms of execution of the inlet nozzles. Pa fig.Z schematically shows the device of the optical system.

The apparatus for magnetic laser therapy "Scalar (Fig. 1) contains a functionally coupled laser radiation generating unit (elements 1-9), a control unit (10), a timer (11), a laser radiation power measuring unit (elements 12-14), block search biologically active points (BAP) on the skin of a person or animal (elements 15-19), power supply (elements 20-21).

The laser radiation generating unit contains a series-connected generator 1, modulator 2, a semiconductor laser 3 with an integrated photodiode 4. The latter form a semi-conductor laser emitter (PLI) 5, to control the operation of which part of the light energy of the laser 3 is radiated in the opposite direction to photodiode 4. Its output is the electric output of the PLI 5 and is connected to the fourth input of the modulator 2, the second and third inputs of which are connected respectively to the second output of the control unit 10 and the second output of the timer 11. Gene ator 1 is designed as a RC-oscillator voltage pryamoztolnoy forms such as "meander assembled on integrated circuits and comprises a frequency multiplication circuit 10.

PLI 5 is mounted in a remote irradiator 6 connected with the remaining units of the apparatus through a cable. It is made in the form of a cylindrical body 7, the open end of which is equipped with a fastening device 8 for an annular source of a constant magnetic field or optical system, as well as supply nozzles (not shown in the diagram). In case 7, an encoding device of type 9 of a conductive laser 3 is also mounted. In PLI 5, replaceable no.iiynpo lead lasers 3 are used, operating in the infrared or red optical spectral ranges. So, in the infrared range (0.81-0.89 μm), low-power (40-50 mW) lasers of the ILPP-108, IP-1-50 type or powerful (250 mW) lasers of the ILPI-112B type can be used,

ILPN-114; in the red range - low-power (30-40 mW) lasers of the RS1-637-30 type (0.63-0.66 μm), IP-678-30 (0.67-0.68 μm), IP-780 (0 78 μm).

The encoding device 9 is made in the form of jumper-switched contacts that are connected to the elements (w) by wiring or shorting them to a common bus) of the electrical circuits of the modulator 2, which provide stabilization of the radiation power of this laser and its protection, and a laser radiation power measurement unit (12-14 ), determining its sensitivity. Thus, each type of semiconductor laser 3 corresponds to a certain position of the jumpers of the encoding device 9.

The control unit (BU) 10 is built according to well-known rules using standard microcircuits that provide the operations of memorization, regulation, switching and indicating, as well as LEDs, control knobs and touch switches. The first output of the control unit 10 is connected to the generator 1 (smoothly adjusting the frequency, multiplying the frequency by 10, setting the operating mode of the device: continuous, pulse); the second output - with a modulator 2 (turning on or off the PLI 5, adjusting the laser radiation power); the third output - with timer 11 (switching on, setting the duration of the PLI 5 operation, counting the exposure time), the fourth output - with a resistance-frequency converter (switching on the BAT search unit).

The timer 11 is made in the form of a highly stable RC pulse generator with a frequency divider of 1024.

The laser radiation power measuring unit comprises a photodetector 13 connected in series, a matching unit 12, and an indicator 14. In this case, a matching unit is connected to the mouth / by its second input; With the encoding property 9 of a semiconductor laser type 3. As a photodetector 13, a wide-area photodiode, for example, type FD-7K or FD-24, is used. The indicator 14 is made in the form of a line of sixteen LEDs, the luminescence of each of which corresponds to a certain level of radiation sensitivity PLI 5. The BAT search unit contains a resistance-frequency 15 converter, an audio frequency generator 16, and an acoustic oscillation source 17. The first input of the converter “Resistance-frequency is connected with the fourth output of the control unit 10, and the active probe 18 and the passive electrode 19 are connected to the second and third inputs, respectively; the second input of the sound frequency generator 16 is connected to the first output of the timer 11. An RC-generator of sinusoidal oscillations with the ohmic resistance of a biological object in the frequency-defining circuit is used as a resistance-frequency converter 15. The contact between the generator and the biological object is created using an active probe 18, which is made in the interior of a conductive rod covered with insulating material with a small cross section of the open end, which provides local contact with human or animal skin, and a passive electrode 19, which is made in the form of an open conductive rod, convenient for holding in the hand by a person, or spring-loaded plates mounted on the body of the animal. As a source of acoustic vibrations 17, a speaker or (preferably) a piezoelectric emitter can be used. The power supply unit contains series-connected first 20 and second 21 voltage converters. The first provides a voltage reduction of 220V 50Hz to 9V, its rectification and stabilization, and the second - the formation of supply voltages for all units of the device (in the functional diagram of Fig. 1, simplified connections of elements with a power supply are indicated by shortened arrows, and these connections are not mentioned in the description text as one of the inputs of the elements). The first voltage converter 20 may be replaced by a direct current source, for example, a battery, which ensures autonomy of the apparatus.

The modulator 2 (Fig. 2) contains serially connected control element 22 and a current sensor 23, to the first and second outputs of which a high-speed switch 24 is connected, electrically connected to a common bus. As a control element 11, a powerful transistor switched on in the current stabilizer mode can be used. Its inputs are the inputs of modulator 2 and are connected: the first with the output of the generator 1, the second with the second output of the control unit 10, the third with the second output of the timer 11, the fourth with the electrical output G1LI 5 (the output of the built-in photodiode 4, figure 1). The current sensor 23 is made in the form of a resistive circuit, the elements of which are connected to an encoding device 9 of the type of a semiconductor laser (fifth input of modulator 2). The first output of the current sensor 23 is the output of the modulator 2. As a high-speed switch 24, a high-frequency transistor can be used, the power circuit (collector-emitter) of which is shorted to the output of the current sensor 23 and a common bus.

The matching unit 12 (FIG. 3) contains a comparator 25, a pulse counter 26, a counter of pulse counts 27, a reset pulse generator 28, a de-shafter 29, a digital-to-analog converter 30, while the output of the comparator 25 is connected to the first input of the pulse counter 26, to the second and to the third inputs of which the outputs of the counter pulse generator 27 and the reset pulse generator 28 are connected, the first output of the pulse counter 26 is connected to the de-diffractor 29, and the second output is connected to a digital-to-analog converter 30, the output of which is connected to the first Odom comparator 25. The second input is connected to its output of the photodetector 13, and the third input is connected to the coding device 9 type semiconductor laser. The output of the deprafter 29 is the output of the matching unit 12 and is connected to the indicator 14.

The inlet nozzles (Fig. 4) are designed to supply laser radiation to local areas both on the surface of the skin of a person or animal, and in various internal cavities (for example, mouth, nose, etc.). They are made of high-quality translucent material, for example quartz or organic glass, in the form of rods or optical fibers (Fig.4d). Their free ends have a spherical shape (for focusing the beam). A flattened shape is possible when the diameter of the flat end exceeds the diameter of the rod or fiber. The rod inlet nozzles have a cylindrical or conical (Fig. 4b) shape and can be performed with bending of the end part at various angles, for example, from O to 120 (Fig. 4a, 4c, 4d).

The optical system (Fig. 5) is designed to enable remote irradiation of the skin surface of predominantly animals, in particular, wild animals contained in cells. It contains an optical collimator 31 and a laser target designator 32, the optical axis of which is aligned with each other. The optical collimator 31 is installed in a cylindrical housing 33 with the possibility of smooth reciprocating movement inside it, for example, using a threaded connection. The housing 33 is articulated with the housing 7 of the external irradiator 6 of the apparatus using the mounting device 8 (Fig. 1) - instead of a ring source of constant magnetic field. As the mounting device 8, a threaded connection can be used, including with a collet clamp for the supply nozzles. To reduce energy losses, the focal length of the input lens 34 of the optical collimator 31 is selected from the condition of ensuring the minimum distance between this lens and the semiconductor laser 3.

As a laser target designator 32, a semiconductor laser of the red spectral range (X, 0.67 μm) of the IP-6-3 / 5M type with a microclimator can be used. The laser pointer 32 is mounted on the housing 33 using the adjustment screws. Because the laser pointer 32 works for a short time only when the optical axis of the remote irradiator 6 is pointed at the desired area of the animal’s skin surface along the red spot, it is equipped with an autonomous power source with a power button. For ease of use and to prevent jitter of the laser beam during the external irradiator 6 with the optical system, it is mounted in a hinge head mounted on a portable stand (not shown in the drawing).

The described apparatus for magnetic laser therapy “Scalar works as follows. After switching on the electrical generator, the generator 1 starts, at the output of which a meander sequence is formed. The pulse frequency with a constant duty cycle equal to 2. By the command from the control unit 10, two laser radiation modes are implemented: continuous or modulated (pulsed). To implement the continuous mode, the generator 1 is disconnected from the modulator 2 and the pump current of the laser 3 is set by the bias current of the control element 22. In this case, the laser 3 emits unmodulated light, the exposure is set using the timer 11 and can be continuously adjusted in the range of 30 sec. up to 6 minutes Using the control unit 10, the laser radiation power can be smoothly set in the range from the minimum to the maximum rated power of the laser 3. When the modulated (pulsed) mode is implemented, the meander sequence of pulses from the output of the generator 1 is supplied to the control element 11 of the modulator 2, which is influenced by These pulses are generated by pump current pulses, which through a resistive current sensor 23 enter the semiconductor laser 3 with a frequency equal to the pulse repetition rate in the meander sequence telnosti. Thus, periodic pulsed modulation of the laser beam power is carried out. In this case, using the control unit 10, the frequency of modulation of the radiation power can smoothly change in a wide range: from 0.4 Hz to 4 Hz and from 4 kHz to 40 kHz (in the frequency multiplication mode by 10). Due to the constant pulse duty cycle in the meander sequence of 2, the average laser power remains constant with a change in the modulation frequency. This greatly simplifies the calculation of the required radiation dose. The frequency of modulation is established from the conditions for obtaining the greatest therapeutic effect by appropriate methods. Laser radiation is supplied to the biological object using an external irradiator 6 with an annular source of a constant magnetic field or without it directly, or through a supply nozzle, or remotely through an optical system. D.G1YA supply of laser radiation in the internal cavity using nozzles with curved ends or fibers.

In addition to the function of generating the pump current of a semiconductor laser 3, the modulator 2 provides stabilization of the laser radiation power when external and internal operating conditions change, such as temperature changes, aging of materials, surges in supply voltages, etc. So, for example, with increasing temperature of the environment and the body of the semiconductor laser 3, its output power decreases. This will reduce the light flux incident on the built-in photodiode 4. The value of its output signal supplied to the fourth input of the control element 22 will decrease, which will lead to its opening and increase the pump current of the semiconductor laser 3, the output power of which is restored. In the event of a current surge with a 30% excess and a duration of more than 40 ns, which is especially dangerous for crawler lasers, the resistive current sensor 23 generates a signal that opens a high-speed switch (high-frequency transistor) 24. The latter passes part of the pump current through the common wheat and thereby smooths out the current surge, preventing the failure or damage of the laser 3. The values of the control thresholds in the described cases are set individually for the particular semiconductor used laser pomosh1.yu coding apparatus 9 of the laser type.

To measure the laser radiation power, it is necessary to bring the external irradiator 6 or the end of the supply nozzle to the photodetector 13. Its output signal, which is proportional to the laser radiation power, is fed to the second input of the comparator 25 of the matching unit 12. This unit works as follows. The pulse counter 26, based on the counting pulses and the reset pulses, received from the generators 27 and 28, generates a binary decimal code, which is converted in the decoder 29 to a binary position code, which is received in a 16-bit LED indicator 14. From the second output of the counter pulses, the signals are fed into a digital-to-analog converter 30, in which the binary decimal code is converted into an analog step-changing signal, which is fed to the first input of the comparator 25. Here, this signal is compared with the output with photocell detector. When their values coincide, a signal is generated at the output of the comparator 25, under which the pulse counter 26 stops, and a code is recorded at its output associated with the decoder 29, the value of which is directly proportional to the power of the laser radiation incident on the photodetector 13. This value is indicated by the glow of the corresponding LED on the indicator 14. The sensitivity of the power measurement unit when changing the semiconductor laser 3 is corrected with the help of a laser type coding device 9 connected to the third input of the comparator 25.

The principle of operation of the biologically active points (BAP) search unit is based on the use of the phenomenon of higher electrical conductivity (lowering ohmic resistance) of human or animal skin in the BAP. The block works as follows. When the converter “frequency impedance 15” is turned on by a command from the control unit 10, the passive electrode 19 is clamped in the human hand (it is tightly clamped on the skin of the animal). The active probe 18 is slightly pressed and moved over the surface of the skin. The probe current is chosen to be the smallest by all methods and does not exceed 4 μA. Thus, the frequency section of the RC sinusoidal oscillator used as the resistance-frequency converter 15 includes the resistance of the skin area between the active probe 18 and the passive electrode 19. A voltage is allocated to the output of the generator 15, the frequency of which is proportional to the resistance of the local skin area, and is supplied to the first input of the sound frequency generator 16. The voltage of the sound frequency from the output of the generator 16 is supplied to the source of acoustic oscillations 17, which emits a sound of a certain tone flax. If the active probe 18 hits the BAP, in which the ohmic resistance of the skin is less than normal, the frequency of the generators 15 and

16 The tone of the sound is increased and correspondingly increased. The presence of the BAT search unit in the apparatus, in addition to ensuring the accuracy of magnetic laser therapy, allows laser reflexotherapy.

Sound frequency generator 16 and a source of acoustic vibrations

17 are also used to provide an audible alarm about the end of the laser exposure exposure, the time of which is set using the timer 11. For this, the corresponding signals from the first output of the timer 11 are fed to the second input of the sound frequency generator 16, and from the second output of the timer 11 to the third input of the control element 22 modulator 2 (command to turn off the semiconductor laser emitter 5).

The above information confirms that the tool embodying the claimed utility model in its implementation is intended for use in industry, namely in medical and veterinary technology. For a utility model in the form described in the utility model formula, the possibility of its implementation using the means and methods described in the application or known prior to the priority date is confirmed. Moreover, the tool embodying the claimed utility model is capable of achieving the technical result indicated in the application. Therefore, the utility model meets the patentability condition “industrial applicability.

Claims (11)

1. The apparatus for magnetic laser therapy, containing a ring source of constant magnetic field, a photodetector, an indicator, a sequentially connected generator, modulator and a semiconductor laser emitter, characterized in that a control unit, a coding device such as a semiconductor laser, an optical system, a timer, a matching unit, active probe, passive electrode, resistance-frequency converter connected in series, sound frequency generator and source of acoustic vibrations, while The main source of constant magnetic field and the optical system are aligned with the semiconductor laser emitter, the control input of the generator is connected to the first output of the control unit, the second, third and fourth outputs of which are connected respectively to the second input of the modulator, the timer input and the first input of the resistance-frequency converter , to the second and third inputs of which the active probe and passive electrode are connected, respectively, and to the output is the first input of the sound frequency generator, the second input of which connected to the first output of the timer, the second output of which is connected to the third input of the modulator, the fourth input of which is connected to the electrical output of the semiconductor laser emitter, and the fifth input is connected to a coding device such as a semiconductor laser, to which the first input of the matching unit is also connected, the second input of which is connected with the output of the photodetector, and the output with an indicator.  2. The apparatus according to claim 1, characterized in that the modulator contains a serially connected control element and a current sensor, to the first and second outputs of which is connected a high-speed switch, electrically connected to a common bus, while the inputs of the control element are the first, second, third and the fourth inputs of the modulator, the second input of the current sensor is the fifth input of the modulator, and the first output of the current sensor is the output of the modulator.  3. The apparatus according to claim 1, characterized in that the semiconductor laser emitter is made in the form of replaceable semiconductor lasers, respectively, infrared or red optical wavelengths, using lasers with a built-in photodiode, the output of which is the electrical output of a semiconductor laser emitter.  4. The apparatus according to claim 1, characterized in that the semiconductor laser emitter and a coding device such as a semiconductor laser are mounted in a remote irradiator made in the form of a cylindrical body with a device for fastening an annular source of constant magnetic field, supply nozzles or optical system.  5. The apparatus according to claim 4, characterized in that the supply nozzles are made of translucent material. 6. The apparatus according to claim 4, characterized in that the supply nozzles are made in the form of cylindrical rods, the end parts of which are bent at an angle selected in the range 0 - 120 ^o to the longitudinal axis of the rod.  7. The apparatus according to claim 4, characterized in that the inlet nozzle is made in the form of a conical rod.  8. The apparatus according to claim 4, characterized in that the supply nozzle is made in the form of a fiber.  9. The apparatus according to claim 1, characterized in that the optical system is made in the form of interconnected optical collimator and a semiconductor laser target designator, the optical axis of which is aligned with the optical axis of the semiconductor laser emitter.  10. The apparatus according to claim 1, characterized in that the matching unit comprises a comparator, pulse counter, counter pulse generator, reset pulse generator, decoder, digital-to-analog converter, the comparator output being connected to the first input of the pulse counter, to the second and third inputs of which accordingly, the outputs of the counter pulse generator and the reset pulse generator, the first output of the pulse counter and the reset pulse generator, the first output of the pulse counter is connected to the decoder, and the second output is connected to digital-to-analog converter, the output of which is connected to the first input of the comparator, while the second and third inputs of the comparator, the output of the decoder are the first, second inputs and output of the matching unit, respectively.  11. The apparatus according to claim 1, characterized in that the RC-generator of sinusoidal oscillations is used as a resistance-frequency converter.