RU157529U1 - DEVICE FOR LIGHT THERAPY - Google Patents

Abstract

A light therapy device comprising a power source and an impact element including a cylinder-shaped housing and a light emitter mounted inside the housing; according to the proposal, the light emitter is made in the form of a single segment of an LED strip FW - 5050 RGB - 60 RW, which is in the form of a spiral fixed on the inner surface of the housing, the length of the segment L = Μ × 50 mm, (where M = 50 .... 100) and contains Ρ = 3 M LED housing type SMD, each of which contains crystals of three colors - red radiation with a wavelength 640 nm, green radiation with for another wave 530 nm and blue radiation with a wavelength of 450 nm, the power supply circuit of the segment through the controller connected to the output terminals of the power source.

Description

A useful model of a device for light therapy relates to medicine, namely to devices for physiotherapeutic effects on human limbs.

In medical practice, color light therapy (color therapy) is widely used. The healing properties of color are due to the influence of electromagnetic waves in the light range. The photon energy of the visible spectrum corresponds to the energies of the physiological transformation of molecules, which, when exposed, creates the conditions for the excitation of certain specific changes in biological structures. Visible radiation is widely used in medicine to stimulate metabolic processes. The electromagnetic radiation of the light range stimulates tissue metabolism and improves microcirculation. Color energy has a positive effect on the functioning of cells in the human body.

Color therapy is a method of healing the body, in which elementary particles of light, photons affect the processes occurring in the body: transmit information from the environment, as well as inside the body between cells, tissues and organs, increasing energy, improve the state of the immune system, regulate the functions of many organs , of which some are light-dependent, set and maintain the rhythm of diurnal fluctuations in the work of systems and organs, activate the synthesis in the skin of vitamin D, necessary for the deposition of cal tion in bone tissue [1].

Color therapy stimulates photobioactivation in a biological object at the molecular, cellular, tissue, organ and systemic levels.

Currently, in medical practice for light therapy, the ADFT-4 “Rainbow” apparatus is used, which uses the dynamic action of the light flux as a traveling wave. The presence of several matrices with a set of different color stimuli and the ability to switch the color gamut during therapy significantly expands the therapeutic capabilities of the apparatus [2].

The closest in technical essence is a photomatrix device of the type ATS - 01/660 of the POLYUS company, which is used to irradiate spatially extended areas of the body, as well as biological media [1, 2, 3].

These devices are a combination of a large number of emitters, giving a stream of light visible or adjacent to the near UV and IR ranges. As emitters, superbright LEDs are used that emit quasimonchromatic radiation with different wavelengths. [3, 4, 5]. The device ATS - 01/660 contains a power source and an impact element including a cylinder-shaped housing and a light emitter mounted inside the housing. The light emitter contains a set of matrices on which superbright LEDs are installed. When installing the matrices in the housing, its axis is parallel to the axis of the housing [5].

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

The technical result is the expansion of operational capabilities.

The technical result is achieved by the fact that in a device for light therapy containing a power source and an exposure element including a housing having the shape of a cylinder and a light emitter mounted inside the housing, according to the proposal, the light emitter is made in the form of one piece of LED strip FW - 5050 RGB - 60 RW, which is mounted in a spiral form on the inner surface of the case, the length of the segment is L = M × 50 mm, (where M = 50 ... 100) and contains P = 3M LED housings of the SMD type, each of which contains crystals of three colors - red radiationwith a wavelength of 640 nm, green radiation with a wavelength of 530 nm and blue radiation with a wavelength of 450 nm, the power supply circuit of the segment through the controller is connected to the output terminals of the power source.

The difference from the prototype is that the proposed device for color therapy contains a light emitter made in the form of a single segment of the LED strip FW - 5050 RGB - 60 RW, which is mounted in a spiral form on the inner surface of the housing, the length of the segment L = M × 50 mm, ( where M = 50 ... 100) and contains P = 3 × M LED housings of the SMD type, each of which contains crystals of three colors - red radiation with a wavelength of 640 nm, green radiation with a wavelength of 530 nm and blue radiation with a wavelength of 450 nm , the power circuit of the cut through the controller connect cheny to the output terminals supply.

In FIG. 1 is a functional diagram of an apparatus for light therapy, FIG. 2 housing with a light emitter.

The device (see Fig. 1). Contains a power source 1, to the output of which by means of a timer 2 an input of an action element 3 is connected, including a light emitter 4. The emitter 4 is a radiator of electromagnetic waves of the optical range, the input of which is connected to the timer output via a controller 5 2.

Three LED systems are connected to the controller outputs 6, 7, 8, and 9. System of red radiation 10 with a wavelength of 640 nm, containing P LEDs with a wavelength of 640 nm, which is connected by the first output to the output of the controller 6. System of green radiation 11, containing P LEDs with a wavelength of 530 nm, which is first connected to the output 7 of the controller . The blue radiation system 12, containing P LEDs with a wavelength of 450 nm, which is connected to the output 8 of the controller by the first output. The second conclusions of all systems are combined and a wire 13 connected to the output 9 of the controller. To control the multi-color LED backlight, the controller 5 is equipped with an infrared sensor for receiving control signals 14. A remote control panel 15 is also included. Using the remote control 15, several modes of smooth and dynamic color change can be selected.

In FIG. 2 shows a snapshot of the impact element, made in the form of a working prototype. The impact element includes a housing 16 having the shape of a cylinder, which is made of fiberglass. A controller 5 is mounted on the side surface of the housing. A light emitter is mounted inside the housing, made in the form of one segment 17 of the LED strip FW 5050 RGB - 60RW. A piece in the form of a spiral is fixed with glue. The length of the segment L = M × 50 mm, (where M = 50 ... 100). On the tape, P = 3 × M LED assemblies of the SMD type are installed. Each LED assembly contains a housing in which a red LED with a wavelength of 640 nm, a green LED with a wavelength of 530 nm, and a blue LED with a wavelength of 450 nm are installed. All LEDs have separate leads. A piece of tape contains M modules (where M = 40 ... 80). Each module has a length of 50 mm and contains 3 LED assemblies and three resistors.

Each module has LEDs of the same color and one resistor connected in series and form a power circuit of the same color. The power circuits of all modules are connected in parallel. LEDs of the same color of all modules form a system of the corresponding color. The “-" pin on each system is connected to a separate wire. The “+” pin on each system is connected to a common wire. With the number of modules M = 50, the number of LED assemblies P = M × 3 = 50 × 3 = 150. Controller 5 is fixed on the side surface.

The device uses a controller company ELF type ELF - IRKON - 24 V - 3CH - LV

The power source 1 and the timer 2 are made in the form of a separate unit (not shown in Fig. 2). The impact element is connected to the unit by a separate cable.

The working sample is designed to act on the knee joint and has the following parameters: diameter 170 mm, frame width 110 mm, length of a segment of LED strip 2500 mm. To influence the limb, the case has a diameter of 200 mm, a frame width of 300 mm, a length of a segment of LED strip 5000 mm.

The device operates as follows.

Preliminarily, using the remote control 15, a smooth and dynamic color change mode is selected. The body of the exposure element is placed on the limbs of the patient.

When the power is turned on, the light emitter operates in a predetermined mode of smooth and dynamic color change, affecting the corresponding region of the limb or joint. The duration of the procedure is determined by the appropriate medical technique.

The main application of the device is the impact on the limbs, knee joint.

The technical result is a reduction in treatment time.

Information sources

1. Zverev V.A.//In Sat. Visual color stimulation in reflexology, neurology, therapy and ophthalmology, ed. B.C. Goidenko, - RMA. - M. - 1998. - p. 86

2. Dynamic Phototherapy Unit ADFT-4 - Rainbow, www.trima.ru/medicine/rainbow.htm.

3. V.P. Zharov et al. Photomatrix devices for the treatment of spatially extended pathologies. Biomedical Electronics, 1999, No. 5, p. 46-48.

4. V.P. Zharov et al. The use of matrix phototherapeutic apparatuses for the treatment of systemic diseases in conditions of weakened immune responses. Biomedical Electronics, 2001, No. 9, p. 66-72.

5. Catalog of medical equipment of the Research Institute “Polyus”. www.polyus.msk.ru

Claims (1)

A light therapy device comprising a power source and an impact element including a cylinder-shaped housing and a light emitter mounted inside the housing, according to the proposal, the light emitter is made in the form of a single segment of an LED strip FW - 5050 RGB - 60 RW, which is in the form of a spiral fixed on the inner surface of the housing, the length of the segment L = Μ × 50 mm, (where M = 50 .... 100) and contains Ρ = 3 M LED housing type SMD, each of which contains crystals of three colors - red radiation with a wavelength 640 nm, green radiation with for another wave 530 nm and blue radiation with a wavelength of 450 nm, the power supply circuit of the segment through the controller connected to the output terminals of the power source.

Images