RU131627U1 - PHYSIOTHERAPY DEVICE - Google Patents

Abstract

Physiotherapy apparatus containing a power source and an impact element, including a housing in which the oscillator circuit is located, an LED emitter and an inductive emitter made in the form of two inductors, the winding of the first inductor is placed on a flat dielectric frame, the winding of the second inductor is placed on the side the surface of the housing, the windings of both inductors are connected in series and according to and connected to the circuit of the oscillator, characterized in that the LED one emitter contains 4 LEDs installed in the center on the frame of the first inductor, the first infrared light emitting diode with a wavelength of 880 nm, the second red light with a wavelength of 640 nm, the third green light with a wavelength of 560 nm, the fourth blue radiation diode with 450 nm wavelength, all LEDs are connected in series and connected to a power source.

Description

The utility model relates to medicine, namely to physiotherapeutic devices.

The proposed apparatus for physiotherapy can find application in ophthalmology in the treatment of a number of diseases. Studying the causes of the progressive course of glaucoma optic neuropathy

after normalization of intraocular pressure, as well as the development of effective methods for its prevention and treatment are of great practical importance. Traditionally, in the early postoperative period, electromagnetotherapy is used in patients with open-angle glaucoma. As a result of treatment, hemodynamics are improved, edema is reduced, and regeneration of damaged tissues is accelerated [1].

Recently, work has been actively carried out on the use of visual color stimulation in the treatment of ophthalmic diseases with liquid [2]. Optical electromagnetic radiation stimulates tissue metabolism and improves microcirculation. The combination of the method of magnetotherapy and chromotherapy with individual selection and correction of stimulation parameters, in addition to the known biological effects, contributes to the integration of the activity of the structures of the visual system.

To influence the patient, AMO-ATOS and ADP- devices are used; Rainbow.

Known devices are used only in hospitals.

The disadvantage of the AMO-ATOS apparatus is the low frequency of the electromagnetic field of 10 Hz.

It is known that at a frequency of 10 Hz, the alternating current induced in biological tissues propagates mainly through the vessels and interstitial gaps, while enveloping cells, since cell membranes at a frequency of 10 Hz have 10,000 times greater resistance compared to intercellular fluid [3, four,].

Therefore, when applying a low-frequency electromagnetic field with a therapeutic effect on biological tissues, it is necessary to significantly increase the radiation power.

Large currents flowing through the intercellular fluid have a negative effect on the body and the rehabilitation process.

At present, an LED ophthalmic apparatus / glasses by Professor O.P. Pankov / [5] is used to treat a number of eye diseases. The device contains built-in LED emitters of red, green and blue light, which operate in a pulsating mode. This device is an analogue of the proposed device.

The device is a portable device consisting of a frame in which LED emitters and a battery power supply are built-in. The operation of the emitters is controlled by built-in microprocessor controllers located directly in the LED emitters.

The wavelengths of radiation, nm ... 450, 530, 650.

The radiation mode is pulse-periodic.

However, there is no electromagnetic field emitter in Pankov’s glasses.

The closest in technical essence to the proposed proposal is a physiotherapy device according to the patent of the Russian Federation No. 2358772, which allows you to simultaneously affect the patient with a dynamic electromagnetic field in the range of 200-500 kHz and light radiation [6].

The device comprises an inductance coil and a base on which infrared, red and white LEDs are mounted. The device is designed to affect a large area of a biological object, for example, the back, lower back of a patient. The presence of a base with LEDs partially shields the winding of a flat inductance coil of an inductive emitter. Decreases the quality factor, and as a result, reduces the level of electromagnetic field strength. To obtain the required level, you have to increase the voltage of the generator, and as a result, increase the power consumption of the device.

To affect the human eye, there is no need to have so many LEDs. It is enough to have one LED emitting electromagnetic waves of different wavelengths. In this case, it is advisable to install them directly on the frame of the inductor in the center. This significantly increases the quality factor of the winding of the inductor, and as a result, the level of electromagnetic field increases. As a result, the proposed device design has lower power consumption compared to the prototype.

As medical practice has shown, to obtain a therapeutic effect, it is necessary to have LEDs of four types emitting infrared, red, green and blue light.

Radiation occurs simultaneously. In the device, all the LEDs are connected in series and are powered by a ripple voltage.

An electromagnetic field emitter and LEDs simultaneously emit electromagnetic waves with different wavelengths.

The objective of the utility model is to expand the arsenal of technical means for physiotherapy.

The technical result is a reduction in energy consumption.

The technical result is achieved by the fact that the apparatus for physiotherapy, containing a power source and an exposure element, including a housing in which the oscillator circuit, an LED emitter, and an inductive emitter are made in the form of two inductors, the winding of the first inductor is placed on a flat dielectric frame, the winding of the second inductor is placed on the side surface of the housing, the windings of both inductors are connected in series and, according to and are connected to the circuit a of the generator, according to the proposal, the LED emitter contains 4 LEDs mounted in the center on the frame of the first inductor, the first infrared LED with a wavelength of 880 nm, the second red light with a wavelength of 640 nm, the third green light with a wavelength of 530 nm , the fourth diode of blue radiation with a wavelength of 450 nm, all the LEDs are connected in series and connected to a power source.

The essence of the proposal lies in the fact that the exposure element simultaneously contains a high-frequency oscillation source with an inductive emitter, and an LED emitter, which contains 4 LEDs mounted in the center on the frame of the first inductor, the first infrared radiation LED with a wavelength of 880 nm, the second red light with a wavelength of 640 nm, a third of green light with a wavelength of 530 nm, a fourth blue radiation diode with a wavelength of 450 nm, all the LEDs are connected in series and connected to and source of food.

Figure 1 shows the functional diagram of the apparatus for physiotherapy; figure 2 shows the inductor, figure 3 shows the impact element assembly.

The device contains a power source 1, the output of which there is a ripple voltage with a ripple frequency of 100 Hz.

The power source contains a step-down transformer, to the secondary winding of which a rectifier is connected, made according to the bridge circuit on semiconductor diodes.

A timer 2, an attenuator 3, and an oscillator 4 are connected in series to the output of the power source I. The oscillator circuit of the oscillator 4 contains a capacitor 5 and inductors 6 and 7 connected in series. The windings of the inductors 6 and 7 are simultaneously an inductive emitter of the action element.

A control path 8 is connected to the oscillator circuit, comprising an amplitude detector 9 connected in series, a DC amplifier 10 and a light indicator 11. The oscillator circuit and the control path are made in the form of a single hybrid circuit.

An audio indication element 12 is connected to the timer circuit. The carrier frequency of the oscillator is determined by the magnitude of the inductance of the windings of the coils 6 and 7 and the capacitance of the capacitor 5 and is in the frequency range 300-400 kHz. A circuit is connected to the output terminals of the attenuator containing 13 LEDs connected in series with infrared radiation with a wavelength of 880 nm, 14 with green light with a wavelength of 560 nm, 15 with red light with a wavelength of 640 nm, and 16 blue light with a wavelength of 430 nm. .

Figure 2 shows the inductor 7 containing the dielectric frame 17, made in the form of radially arranged petals with gaps. The number of petals is odd. On the frame 17 there is a winding of the inductor 7 made in the form of a spiral, while the wire of each coil of the spiral alternately bends around all the petals, and from one coil to another, the wire goes around one or the other side of each petal. LEDs 13, 14, 15 and 16 are installed in the center of the frame.

Figure 3 shows the apparatus for physiotherapy assembly.

The apparatus contains a dielectric housing 18, in which the frame 17 is fixed, with the winding of the inductor 7 and the LEDs 13-16 placed on it.

The housing 18 is made in the form of a bowl. The bottom case 18 is connected to the strap 19, on which the hybrid circuit is fixed 20. The housing 18 is closed by a cover 21. The hybrid circuit is connected to the power source by the cable 22. The casing 23 is mounted on the top of the strap 23. The power supply is made as a separate functional element and includes transformer, rectifier, timer, attenuator and sound indicator.

The device operates as follows. Initially, the duration of the procedure and the level of output voltage are set, which is associated with the radiation power.

The power source is connected to a 220 V network. The device is ready for action. The ripple voltage is supplied to the generator circuit and to the LEDs. An oscillator together with an inductive emitter generates a pulsating high-frequency electromagnetic field in space with a pulsation frequency of 100 Hz. At the same time, pulsating electromagnetic oscillations of the optical range are emitted into space. During the procedure, a labile technique is used, which creates additional amplitude modulation of high-frequency oscillations with infra-low frequencies. The speed of movement of the impact element is not more than 1 cm / sec. After the procedure expires, the timer disconnects power from the generator circuit and from the LEDs. The sound indication turns on.

If the exposure element is brought closer to the patient’s eye, the high-frequency electromagnetic field will affect the eye area. At the same time, an optical emitter located on the frame cover emits infrared electromagnetic waves with a wavelength of 880 nm, red light with a wavelength of 640 nm, green light with a wavelength of 560 nm and blue light with a wavelength of 450 nm, which act on the biological object - the eye .

As medical practice has shown, to obtain a therapeutic effect, it is necessary to have LEDs of four types emitting infrared, red, green blue light.

Radiation occurs simultaneously. In the device, all LEDs are connected in series and are powered by a ripple voltage

The electromagnetic field emitter and LEDs simultaneously emit electromagnetic waves with different wavelengths

It is known that infrared and red light improves microcirculation in the eyeball, increases visual acuity, and sensitivity of retinal receptors. Green light reduces intraocular pressure, most effectively restores the biorhythm of the visual analyzer, promotes blood flow and circulation of intraocular fluid.

Blue color has a calming effect, reduces intraocular pressure, normalizes sleep.

Bioenergy forces induced by electromagnetic vibrations cause a whole cascade of transformations in the body. They act on the central nervous system, endocrine glands and many other vital formations, contribute to the intensification of metabolism, division and cell growth.

Information sources:

1. Bivas Shushanto Kumar, N. A. Listopadova. Possibilities of magnetotherapy in the stabilization of visual functions in patients with glaucoma. // Bulletin of Ophthalmology. 1996, No. 1, C.6-8.

2. Bakutin V.V., Kamenskikh T.G. On combined methods of physiotherapeutic treatment of partial atrophy of the optic nerves. Actual problems of modern ophthalmology. // Materials of the Volga scientific-practical conference. Saratov, 1996, p. 212.

3. URWaydi. Frequency and energy windows when exposed to weak electromagnetic fields on living tissue. - TIIER; t.68, No. 1, January 1980, p.140-147.

4. GG Ivanov and others. Opportunities for assessing total water. RUDN University Bulletin, series Medicine, 1998, No. 1, pp. 213-323.

5. Points Professor Pankov. Vision restoration using the unique technology of Professor Oleg Pankov. - M .: ACT :; Astrel; Vladimir: VKT, 2011

6. RF patent No. 2358772, class 7 A61N 5/06, 2/02 publ. January 20, 2009, B. No. 17.

Claims (1)

Physiotherapy apparatus containing a power source and an impact element, including a housing in which the oscillator circuit is located, an LED emitter and an inductive emitter made in the form of two inductors, the winding of the first inductor is placed on a flat dielectric frame, the winding of the second inductor is placed on the side the surface of the housing, the windings of both inductors are connected in series and according to and connected to the circuit of the oscillator, characterized in that the LED one emitter contains 4 LEDs installed in the center on the frame of the first inductor, the first infrared light emitting diode with a wavelength of 880 nm, the second red light with a wavelength of 640 nm, the third green light with a wavelength of 560 nm, the fourth blue radiation diode with 450 nm wavelength, all LEDs are connected in series and connected to a power source.

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