RU2179869C1 - Apparatus for applying magneto-photo laser therapy - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has adapter unit, terminal unit having laser radiator, N infrared photodiodes, photodetector manufactured as transistor and waiting multivibrator, power supply source for feeding infrared photodiodes with pulsating current stabilizers, laser radiator power supply source, microcontroller, unit for switching operation modes, acoustic signal unit, photo-indication unit, terminal chambers. EFFECT: low cost, weight and small dimensions; enhanced reliability in detecting infrared radiation. 2 dwg

Description

 The invention relates to medical equipment, namely to devices for physiotherapeutic exposure to laser and LED infrared radiation simultaneously with a magnetic field on the internal and external tissues of a biological object.

 A known apparatus for magnetic laser therapy, comprising a functionally interconnected irradiating terminal with LEDs and a photodetector installed in the nozzle, a semiconductor laser emitter, a constant magnetic field source and a control panel comprising a commutator and a synchronizer, a current adjustment unit connected to the LEDs and the commutator, is connected in series connected pulse master oscillator connected to the output of the synchronizer, and the pulse shaper module, connected nny to a semiconductor laser transmitter, and indicator coupled to the photodetector [1].

 A disadvantage of the known apparatus is the possibility of overheating of the LEDs and the terminal as a whole, which leads to a decrease in the reliability of the apparatus and to energy losses during its operation.

 A known apparatus for magnetic laser therapy, which is the closest analogue of the claimed invention, containing a terminal consisting of N LEDs, where N> 1, a photodiode, a laser emitter, a source of a constant magnetic field (magnet), a photodetector, a camera and a control panel containing a digital display unit, sound indication unit, LED power supply, laser emitter power supply, microprocessor (microcontroller), adaptation unit, mode switching unit, synchronizer [2].

 The disadvantages of the known apparatus are the reduction of the effect of treatment due to the fact that the indication of the presence of laser radiation is the glow of the indicator LED, which is included in the laser power supply circuit and indicates only the presence of current in the circuit, and in the event of laser emission loss, the current in the circuit will cause the LED to glow, however, radiation will be absent, which can mislead the doctor and, accordingly, reduce the effect of treatment.

 In addition, in the well-known analogue, the power level of the LEDs is set according to the readings of the photodetector of the reflected signal, and since the radiation of the IR LEDs is continuous, the photodetector reacts to any continuous infrared radiation, including the infrared component of sunlight. At the same time, the LEDs are powered by direct current, which leads to energy losses, additional heating of the LEDs and the terminal, and the complexity of the design of the device.

 The technical result achieved by the proposed invention is to use a pulsed current to power the IR LEDs with a laser radiation frequency and at a maximum average radiation power of the LEDs, while the pulsed current has cutouts (intervals between pulses) equal to about five percent of the duration of the laser repetition period radiation. With this functioning of the device, the patient perceives the emission of LEDs as quasi-continuous. Changing and adjusting the average radiation power of the LEDs is carried out by changing the duration of the current pulse supplying the LEDs.

 In addition, the technical result (technical results) is achieved through the use of a photodetector made in the form of a phototransistor connected to a waiting multivibrator, and responding to the resulting signal (in the form of an envelope of the components of the radiation signals of infrared emitters) of both a laser and LEDs.

 The use of a different LED power source compared to the closest analogue (another circuit solution) and the use of a photodetector with a waiting multivibrator using a modern element base can reduce the cost of the device by 1.5-2 times, reduce its weight and dimensions, increase the reliability and reliability of the indication of availability IR radiation of the laser and LEDs while maintaining the basic parameters of the physical factors affecting the patient (pulsed power and frequency of repetition of laser radiation, average NOSTA LED radiation, magnetic field).

These technical results are achieved due to the fact that the apparatus for magnetophotolaser therapy, consisting of a terminal containing N (where N> 1) IR LEDs (infrared LEDs), a photodetector, a laser emitter, an annular source of constant magnetic field, one side of which is the front part of the terminal, and the other facing the inside of the terminal, the camera, the inner surface of which is made mirrored with the ability to reflect infrared radiation, and the camera is placed in the hole of the annular a constant magnetic field source, while one of the base of the camera is the front plane of the terminal, and on the other base of the camera N IR LEDs are rigidly mounted, a laser emitter, in addition, the terminal contains a mode switching unit connected to the switching input (discrete input) of the microcontroller (microprocessor), a sound indication unit connected to the first indicator output of the microcontroller, to the first and second triggering outputs of which the laser power source is connected emitter connected to a laser emitter, and a power supply of N IR LEDs connected to N IR LEDs, while the power supply voltage of the apparatus is supplied from the AC network, in addition, the proposed apparatus additionally contains a light-digital indication unit, a first indicator input in the terminal which, which (depending on the operating mode) is either an input indication of a given radiation power N IR LEDs, or a given repetition frequency of the laser emitter, or a specified timer (exposure time) is connected to the second indicator output of the microcontroller, while the photodetector is made in the form of a series-connected phototransistor and a waiting multivibrator, the output of which is connected to the second indicator input of the light indication unit, which is an input for indicating the presence of infrared radiation at the input of the photodetector, in addition, a red backlight LED is connected to the terminal, connected to the third triggering output of the microcontroller, while the phototransistor and the red backlight LED are firmly set s on the same base of the camera, on which N IR LEDs and a laser emitter are rigidly mounted, in addition, the apparatus is supplied with voltage from the AC mains through an adapter connected by an integral cable to the terminal, and the adapter is configured to have a toggle switch on it turning on / off the supply voltage from the AC mains and the indicator LED, fixing the inclusion of the supply voltage from the AC mains, in addition, the power supply of N IR LEDs is made with the possibility of power supply of each of the N IR LEDs using a separate current stabilizer in a pulsed mode with a pulse repetition rate equal to the frequency of the laser emitter, while the average radiation power of the N IR LEDs is changed by changing the duration of the current pulses so that the cutting time (delay ) T _B between _the pulses with a maximum average power LED should be approximately equal to five percent of the duration T _P of the repetition period of the laser radiation emitter, rum, the digital board with a timer and luminous indicator LED display unit and the switching unit are arranged buttons operation modes on the backside of the terminal body.

где F - частота повторения излучения лазерного излучателя в герцах,
Т_{СД (сек)} - длительность (в секундах) импульса излучения светодиода при максимальной средней мощности излучения,
Т_В - время вырезки (задержки) между импульсами излучения светодиодов, при этом T_В≈0,05 Т_П,
I_ТСД - ток питания светодиодов.The invention is illustrated by drawings, where figure 1 shows a functional diagram of the apparatus, and figure 2 is a diagram of the pulses of the current supply of the LED over time. In this case, the following notation is introduced in the indicated figures:
1 - adapter (power supply),
2 - terminal,
3 - laser emitter
4 - IR LEDs
5 - phototransistor,
6 - LED red backlight,
7 - magnet (source of constant magnetic field),
8 - standby multivibrator,
9 - power supply IR LEDs
10 - power source of the laser emitter,
11 - microcontroller,
12 - block switching modes,
13 - block sound alarm
14 - light indication unit,
15 - terminal camera,
16 - photodetector,
T _{P (sec)} - the repetition period of the radiation of the laser emitter in seconds, while

where F is the frequency of repetition of the radiation of the laser emitter in hertz,
T _{SD (sec)} - the duration (in seconds) of the radiation pulse of the LED at the maximum average radiation power,
T _In - time cut-out (delay) between the pulses of the radiation of the LEDs, while T _In ≈0.05 T _P ,
I _TSD - power supply current of LEDs.

 Taking into account the indicated designations, the apparatus for magnetic photolaser therapy consists of adapter 1 and terminal 2. Moreover, terminal 2 and the adapter (power supply) 1 are connected by an integral cable. Structurally, the terminal (its constituent elements) is located (s) in a special building. Terminal 2 contains a laser emitter 3, N (where N> 1) IR LEDs 4, a photodetector 16 made in the form of a series-connected phototransistor 5 and a waiting multivibrator 8, an LED for red illumination 6 of the irradiation area for visualization, an annular source of constant magnetic field (magnet) 7, one side of which represents the front of the terminal, and the other side faces the inside of the terminal, the camera terminal 15, the inner surface of which is made mirror to reflect infrared radiation, and the camera is sized it is located in the hole of the annular source of constant magnetic field 7, one of the base of the camera is the front plane of the terminal, and IR LEDs 4, laser emitter 3, phototransistor 5 and LED for red illumination 6 are rigidly mounted on the other base of the camera, in addition, the terminal contains a source power supply of the laser emitter 10 connected to the laser emitter 3, the microcontroller 11, the light indication unit 14, made with a digital display and a timer, an audible alarm unit 13 connected to the first indicator the output of the microcontroller, the mode switching unit 12, connected to the switching input (discrete input) of the microcontroller, to the second indicator output of which is connected the first indicator input of the light indication unit 14, which is (depending on the operating modes) or the indication input of the set radiation power N IR light emitting diodes, or a predetermined repetition frequency of laser emitter radiation, or a predetermined timer operation time (exposure time), with the first, second and third triggering outputs of the micro the troller 11 is connected respectively to the input of the power source N IR LEDs 9, the input of the power source of the laser emitter 10 and the red LED 6, and the output of the standby multivibrator 8 is connected to the second indicator input of the light indication unit 6, which is an input to indicate the presence of infrared radiation at the input of the photodetector 16 (phototransistor 5).

 In this case, the camera (15) of the terminal 2 should be made of non-magnetic material, such as brass, which eliminates the distortion of the magnetic field.

 The chamber can be made of a weatherproof dielectric material, for example, plastic, which reduces the cost and facilitates the design of the apparatus as a whole.

 When performing a source of constant magnetic field in the form of an annular magnet, the most optimal is the implementation of the camera in the form of a cylinder.

 The device is powered from the AC mains through the adapter 1, connected by a one-piece cable to the terminal 2. When you turn on the toggle switch of the AC mains located on the adapter, the indicator LED lights up, which is also located on the adapter and fixes the power supply from the AC mains, while the indicator LED of the terminal also lights up, which fixes the inclusion of the terminal, and “0” appears on the digital display of the light indication unit 14, and a short sound signal is emitted, rmiruemy chime unit 13, the signal from the microcontroller 11. Press the "BACKGROUND" operation mode switching unit 12 at the terminal 2 by a signal from the microcontroller 11 sets the desired (set) radiation power IR LEDs 4 (0, 50 or 100 mW). At the same time, the corresponding indicator LED of the light indication unit 14 lights up according to the signal from the second indicator output of the microcontroller 11, which is fed to the first indicator input of the light indication unit 14, which is the input of the indication of the set radiation power N IR LEDs (in the LEVEL mode). Using the “FREQUENCY” button of the operating mode switching unit 12 at terminal 2, the required frequency of the laser emitter 3 repetition is set. The corresponding indicator LED of the light indication unit 14 on the terminal lights up according to the signal from the second indicator output of the microcontroller 11, which is received at the first indicator input of the light indication unit 14 in the "FREQUENCY" mode.

 Using the “TIME” button of the operating mode switching unit 12 on terminal 2, the required exposure is set from 1 to 9 minutes, which is fixed by the timer of the light indication unit 14 by the signal from the second indicator output of the microcontroller 11 in the “TIME” mode. At the same time, the corresponding digit appears on the digital display of the light indication unit 14, the red backlight 6 lights up (on a signal from the third triggering output of the microcontroller 11) and the radiation of the IR LEDs and the laser emitter starts in the set modes.

 After the expiration of the exposure time set by the timer, the radiation ceases, the sound signal from the sound indicator block 13 is emitted (according to the signal from the first indicator output of the microcontroller 11) and the digit “0” appears on the digital display of the light display unit 14, while the red backlight that goes out red backlight LED 6. During the emission of IR LEDs (laser or LEDs), reflected infrared signals are received from the irradiated surface to the phototransistor 5 from the irradiated surface, upon receipt of the resulting signal (form whose matrix represents the envelope of the components of these signals) a waiting multivibrator 8 is triggered, as a result of which a luminous dot appears on the digital display of the light indication unit 14 to the right of the digit (the light dot lights up), indicating the presence of radiation.

 Since the photodetector (phototransistor, the output of which is connected to the waiting multivibrator) reacts only to the resulting signal (the shape of which represents the envelope of the components of the infrared radiation signals), the point glows only when there is a pulsed laser or pulsed LED infrared radiation.

 The average radiation power level of the IR LEDs, the laser pulse repetition rate, and the timer operation time are set discretely by the microcontroller 11 and are set using the buttons of the operation mode switching unit 12, and the selected mode is displayed on the light indicators of the light indication unit 14.

 At the same time, a digital display with a timer and indicator LEDs of the light indication unit 14 of the terminal 2, buttons of the operation mode switching unit 12 are located on the reverse side of the terminal case.

длительностью импульса излучения светодиода Т_СД и временем вырезки (задержки) между импульсами излучения Т_В≈0,05 Т_П. Изменение средней мощности излучения ИК-светодиодов осуществляется изменением длительности импульса тока Т_СД. Указанный режим питания светодиодов, иллюстрируемый на фиг.2, позволяет более эффективно использовать энергетические характеристики светодиодов, повысить коэффициент полезного действия использования светодиодов и обеспечить их защиту путем исключения перегрева.In addition, the power of each IR LED 4 is carried out by a stabilized current using a separate pulse current stabilizer (in pulsed mode), with a repetition frequency of the laser emitter F (Hz), the repetition period of the laser emitter

the duration of the radiation pulse of the LED T _LED and the time cut-out (delay) between the radiation pulses T _B ≈ 0.05 T _P The change in the average radiation power of IR LEDs is carried out by changing the duration of the current pulse T _SD . The specified power mode of the LEDs, illustrated in figure 2, allows more efficient use of the energy characteristics of the LEDs, increase the efficiency of the use of LEDs and ensure their protection by eliminating overheating.

 Thus, the proposed device allows to increase the reliability of the indication of the presence of LED and laser infrared radiation during magnetophotolaser therapy, to eliminate the influence of PIK-exposure to sunlight on the operation of the photodetector; due to the pulse power supply of the stabilized current LEDs, significantly improve the efficiency of using LEDs, eliminate overheating of the LEDs and the terminal, and increase the reliability of the device; the introduction of a red backlight allows you to visualize the presence of infrared radiation, which increases the safety of the device (helps to prevent infrared radiation from entering the patient's eyes); The new circuit and constructive solutions can reduce the cost of the device, as well as significantly reduce its weight and dimensions.

Sources of information
1. RU 2022574 C1, 11/15/94

 2. RU 2143293 C1, 12/27/99

Claims (1)

 An apparatus for magnetophotolaser therapy, comprising a terminal, consisting of N (where N> 1) IR LEDs, a photodetector, a laser emitter, an annular source of constant magnetic field, one side of which represents the front of the terminal and the other faces the terminal, camera, inner surface which is made mirrored with the possibility of reflecting infrared radiation, and the camera is placed in the hole of the annular source of constant magnetic field, one of the bases of the camera is the front plane the terminal, and on the other base of the camera, N IR LEDs are rigidly mounted, a laser emitter, in addition, the terminal contains a mode switching unit connected to the switching input of the microcontroller, an audio alarm unit connected to the first indicator output of the microcontroller, to the first and second triggering outputs which respectively connects the power source of the laser emitter connected to the laser emitter, and the power supply of N IR LEDs connected to N IR LEDs, while the voltage The apparatus is fed from an AC network, characterized in that the terminal further comprises a light indication unit made with a digital display and a timer, while the first indicator input of the light indication unit is connected to the second indicator output of the microcontroller, in addition, the photodetector is made in the form of series-connected a phototransistor and a standby multivibrator, the output of which is connected to the second indicator input of the light indication unit, which is an input for indicating the presence of infrared radiation at the input In addition to the photodetector, a red backlight LED connected to the third trigger output of the microcontroller is also introduced into the terminal, while a phototransistor and a red backlight LED are rigidly mounted on the same base of the camera on which N IR LEDs and a laser emitter are rigidly installed, in addition, voltage supply AC power is supplied through an adapter connected by a one-piece cable to the terminal, while the adapter is configured to have an on / off toggle switch located on it the power supply from the AC mains and the indicator LED, which detects the inclusion of the supply voltage from the AC mains, in addition, the power supply of the N IR LEDs is configured to power each of the N IR LEDs through a separate current stabilizer in a pulsed mode with a pulse repetition rate equal to the frequency of the laser emitter, and the change in the average radiation power N of the IR LEDs is carried out by changing the duration of the pulses of the power supply current of the LEDs with cutting time between and pulses with a maximum average power of LEDs is approximately equal to 0.05 the length of the repetition period of the laser radiation emitter, in addition, digital display with a timer and luminous indicator LED display unit and the switching unit are arranged buttons operation modes on the backside of the terminal body.

Images