CN214550672U - Portable multi-wavelength combined photon pulse physiotherapy instrument - Google Patents

Abstract

The embodiment of the utility model provides a portable multi-wavelength combination formula photon pulse physiotherapy equipment, this physiotherapy equipment is a portable photon therapeutic instrument who adopts tertiary cascade combination light source, and it is small, easy operation, treatment effect are higher than current equipment of the same kind, and it is by portable device shell, integrated circuit system and rechargeable lithium cell charge, main control microprocessor, voltage control circuit for the light source of physiotherapy, filter the optical filter of invalid wavelength to and operation control panel constitutes. The physiotherapy instrument adopts a multi-radiation medical technology based on the super-pulse, three groups of laser lamp beads are used, a plurality of wavelengths are cooperated to generate a cascade effect, and light sources with different wavelengths irradiate different depths capable of penetrating through the skin of a human body, so that the treatment effect on the human body is better.

Description

Portable multi-wavelength combined photon pulse physiotherapy instrument

Technical Field

The embodiment of the utility model provides a relate to photon physiotherapy technical field, concretely relates to portable multi-wavelength combination formula photon pulse physiotherapy equipment.

Background

Phototherapy is a method for preventing and treating diseases by using artificial light sources or natural light sources, and is one of the commonly used methods for physical therapy. Phototherapy is mainly performed by ultraviolet therapy, infrared light, visible light therapy and laser therapy.

For example, people shining in the sun are a common form of natural phototherapy. Because vitamin D is closely related to sunlight, 90% of the human body must be acquired by sunlight. Studies by scientists have shown that vitamin D produced by the skin after exposure to sunlight helps to suppress inflammation, improve vascular and cardiac function, reduce the risk of heart disease, heart failure and stroke, and delay aging.

Phototherapy, which is clinically referred to in medicine, is a method of pathological treatment by artificial light (ultraviolet light, infrared light, visible light, and laser light). The mechanism is that spectral energy with a certain wavelength acts on a human body, so that a series of linked biological effects are generated in the body, and the biological effects are summarized into five types: the thermal effect, pressure effect, electromagnetic field effect, photochemical effect and biological stimulation effect, and the biological effect generated by different wave bands of light are different, so that some therapeutic methods and therapeutic apparatuses for different wave band spectra of different diseases are researched and developed.

The coherent optical radiation source (laser) invented in the sixties of the twentieth century has strongly promoted the development of laser technology in medicine and also promoted the upgrading and development of laser medical equipment. The low-intensity pulse infrared therapeutic laser has special significance, and the high treatment efficiency and safety of the low-intensity pulse infrared therapeutic laser have been proved.

The existing photon treatment device mostly adopts a light source with a single wavelength, the treatment effect is single, and the human body can easily generate tissue adaptability to the light with the single wavelength in the treatment stage, so that the treatment effect is reduced. Even if some devices use a combined laser, most of the laser generators of the devices use a continuous-wave helium-Neon laser (he-Neon laser), and the he-Neon laser has small laser power, low energy density, short service life and great treatment limit.

SUMMERY OF THE UTILITY MODEL

Therefore, the embodiment of the utility model provides a portable multi-wavelength combination formula photon pulse physiotherapy equipment, this physiotherapy equipment is a portable photon therapeutic instrument who adopts tertiary cascade combination light source, and it is small, easy operation, therapeutic effect are higher than current equipment of the same kind, and it mainly comprises portable device shell, integrated circuit system and rechargeable lithium cell that charges, main control microprocessor, voltage control circuit for the light source of physiotherapy, the optical filter of filtering invalid wavelength to and operation control panel. The physiotherapy instrument adopts a multi-radiation medical technology based on the super-pulse, three groups of light sources with different wavelengths are cascaded, the multiple wavelengths are coordinated to generate a cascade effect, and the light sources with different wavelengths irradiate different depths capable of penetrating through the skin of a human body, so that the treatment effect on the human body is better. The specific technical scheme is as follows:

the embodiment of the application provides a portable multi-wavelength combined photon pulse physiotherapy instrument, which comprises a physiotherapy instrument shell and a control circuit; the physiotherapy instrument shell comprises a handheld handle positioned at the lower end and a light source control panel positioned at the upper end and used for controlling the multi-wavelength combined light source on the control circuit through a key; the control circuit is arranged in the light source control panel, and the multi-wavelength combined light source on the control circuit is correspondingly arranged with the light outlet hole of the light source control panel; the light source control panel is connected with the control circuit through the key.

Further, the multi-wavelength combined light source comprises laser light sources with the wavelengths of 660nm, 870nm and 905nm respectively.

Further, an optical filter is arranged between the light outlet hole and the multi-wavelength combined light source.

Furthermore, the control circuit further comprises a voltage control module for controlling the multi-wavelength combined light source by controlling voltage, a rechargeable lithium battery for charging the control circuit, a linear lithium battery charging integrated circuit for charging the rechargeable lithium battery, and a microprocessor for controlling the voltage control module and the linear lithium battery charging integrated circuit, wherein the voltage control module, the microprocessor and the linear lithium battery charging integrated circuit are sequentially connected.

Further, the keys comprise a light source frequency key for controlling the output frequency of the multi-wavelength combined light source, a duration key for controlling the output duration of the multi-wavelength combined light source, and a start or stop key for controlling the start or stop state of the multi-wavelength combined light source.

Furthermore, the light source control panel is circular, the light outlet is circular, and the light beads of the multi-wavelength combined light source are uniformly arranged at the positions corresponding to the light outlet.

Furthermore, the handheld handle is cylindrical or square.

Further, the microprocessor adopts a low-power consumption RISC CPU with the model number of PIC18F25K 22.

Further, the linear lithium battery charging integrated circuit is of the model MCP 73883.

Furthermore, the frequency keys comprise variable frequency frequencies with the frequency of 5-1000MHZ and fixed frequency frequencies with the frequency of 5MHZ, 50MHZ and 1000 MHZ; the time length of the time length key includes 5 minutes, 2 minutes, and 1 minute.

The embodiment of the utility model provides a have following advantage:

the utility model provides a portable multi-wavelength combined photon pulse physiotherapy instrument, which comprises a physiotherapy instrument shell and a control circuit; the physiotherapy instrument shell comprises a handheld handle positioned at the lower end and a light source control panel positioned at the upper end and used for controlling the multi-wavelength combined light source on the control circuit through a key; the control circuit is arranged in the lower inner part of the light source control panel, and the multi-wavelength combined light source on the control circuit is correspondingly arranged with the light outlet hole of the light source control panel; the light source control panel is connected with the control circuit through the key. Three clinically proven wavelengths are used in multiple radiation medicine: 660nm, 870nm and 905nm to cover the entire spectral treatment window, allowing deeper penetration of light energy into the human skin and enhanced absorption. A cascade effect is also produced: the surface tissue absorbs 660 nanometer red light, a road is cleared for 870 nanometer infrared light penetration depth, cell interference is eliminated, and therefore 905 nanometer infrared super pulse laser can be deeper. The physiotherapy instrument is simple to operate, low in price and easy to operate.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structure, ratio, size and the like shown in the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by people familiar with the technology, and are not used for limiting the limit conditions which can be implemented by the present invention, so that the present invention has no technical essential significance, and any structure modification, ratio relationship change or size adjustment should still fall within the scope which can be covered by the technical content disclosed by the present invention without affecting the efficacy and the achievable purpose of the present invention.

Fig. 1 is a schematic structural view of a portable multi-wavelength combined photon pulse physiotherapy instrument provided in embodiment 1 of the present invention;

fig. 2 is a block diagram schematically illustrating a structure of a control circuit of the portable multi-wavelength combined photon pulse physiotherapy instrument provided in embodiment 1 of the present invention;

fig. 3 is a schematic view of a control panel of the portable multi-wavelength combined photon pulse physiotherapy instrument provided in embodiment 1;

in the figure: 1: a physiotherapeutic instrument shell; 2: a handle; 3: a light source control panel; 4: and a light outlet.

Detailed Description

The present invention is described in terms of specific embodiments, and other advantages and benefits of the present invention will become apparent to those skilled in the art from the following disclosure. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, a schematic structural diagram of a portable multi-wavelength combined photon pulse physiotherapy instrument provided in embodiment 1 of the present invention includes a physiotherapy instrument housing (1) and a control circuit; the physiotherapeutic instrument shell (1) comprises a handheld handle (2) positioned at the lower end and a light source control panel (3) positioned at the upper end and used for controlling the multi-wavelength combined light source on the control circuit through a key; the control circuit is arranged in the light source control panel (3), and the multi-wavelength combined light source on the control circuit is correspondingly arranged with the light outlet hole (4) of the light source control panel (3); the light source control panel (3) is connected with the control circuit through the key.

The user holds the handheld handle, and through button control multi-wavelength combination light source from the light-emitting hole output, shine to human skin, the different degree of depth's of skin tissue is shone in the light source of different wavelengths, carries out the irradiation of different levels to the skin of different depths, produces better recovered effect. Preferably, the present application employs light sources of 660nm, 870nm and 905 nm. Clinical evidence shows that: the wavelength is 660nm, 870nm and 905nm can irradiate different depths of human skin, and an energy cascade effect is generated: the surface tissue absorbs 660 nanometer red light, a road is cleared for 870 nanometer infrared to penetrate through the skin deeply, cell interference is eliminated, and therefore 905 nanometer infrared super pulse laser can be deeper. Producing light that covers the entire spectral treatment window and deeper penetration and enhanced absorption. The wavelength of 660nm is visible red light, the wavelength of 870nm is infrared light, the wavelength of 905nm is GaAS super pulse infrared laser, the super pulse laser provides billionths of a second pulse, and the peak power is up to 50000mW, so that the light energy with higher concentration can be obtained. Each pulse of the super-pulse laser generates high peak power (usually 100 to 200 nanoseconds) in a short time, and the pulse energy peak cycle time is far lower than the human body self-thermal pre-relaxation time, so that the human body can obtain periodic high-density light energy, and meanwhile, self tissues can not be damaged due to thermal effect. In order to ensure that the correct light energy of the three wavelengths required by the device is obtained, the present invention employs optical filter optics to filter a small amount of unwanted wavelengths of light produced by the device.

In order to hold the utility model, the handle is designed into a cylinder or a cube.

Reference to fig. 2 is the utility model provides a portable multi-wavelength combination formula photon pulse physiotherapy equipment's control circuit's that embodiment 1 provided structure schematic block diagram, above-mentioned control circuit still including be used for through control voltage realize right multi-wavelength combination light source carries out the voltage control module that controls, be used for right the rechargeable lithium battery that control circuit charges is used for right the rechargeable lithium battery carries out the linear lithium battery integrated circuit that charges, is used for control voltage control module, linear lithium battery integrated circuit's microprocessor that charges, voltage control module microprocessor linear lithium battery integrated circuit that charges connects gradually. The utility model discloses the power supply of 3.7V 1800mAh high performance rechargeable lithium cell as the device. The utility model discloses a MICROHIP company's MCP73883 independent linear lithium ion management controller that charges, its inside charging current that has integrateed detects, reverse blocking protection and automatic end function that charges to adjustable and control battery temperature provide high-grade safety protection.

The novel PIC18F25K22 chip is used as a control processor of the device, is a RISC CPU with high performance and low power consumption, and is very suitable for being used in small-sized portable equipment. The processor is controlled by an internal program to realize the following functions:

1) the luminous frequency of the light source is adjusted, the light energy with different frequencies can generate output energy with different densities, different penetration depths are achieved, and the output of the light energy can be adjusted according to different patients. Through frequency adjustment, the self-adaptability of human tissues to the stimulation of the same frequency is effectively avoided.

2) The light emitting time of the light source is adjusted, and the illumination time can be automatically set for different patients.

Referring to fig. 3, a schematic view of a control panel of the portable multi-wavelength combined photon pulse physiotherapy instrument provided in embodiment 1 is provided, the light source control panel is connected to the control circuit through the key, and the key includes a light source frequency key for controlling an output frequency of the multi-wavelength combined light source, a duration key for controlling an output duration of the multi-wavelength combined light source, and a start or stop key for controlling a start/stop state of the multi-wavelength combined light source. The utility model discloses light source control panel's shape is circular, the shape in light-emitting hole is circular, the light pearl of multi-wavelength combination light source evenly sets up the position that the light-emitting hole corresponds. The frequency keys comprise variable frequency frequencies with the frequency of 5-1000MHZ and fixed frequency frequencies with the frequency of 5MHZ, 50MHZ and 1000 MHZ; the time length of the time length key includes 5 minutes, 2 minutes, and 1 minute.

The utility model provides a portable multi-wavelength combined photon pulse physiotherapy instrument, which comprises a physiotherapy instrument shell and a control circuit; the physiotherapy instrument shell comprises a handheld handle positioned at the lower end and a light source control panel positioned at the upper end and used for controlling the multi-wavelength combined light source on the control circuit through a key; the control circuit is arranged in the light source control panel, and the multi-wavelength combined light source on the control circuit is correspondingly arranged with the light outlet hole of the light source control panel; the light source control panel is connected with the control circuit through the key. Three clinically proven wavelengths are used in multiple radiation medicine: 660nm, 870nm and 905nm to cover the entire spectral treatment window, allowing deeper penetration of light and enhanced absorption. A cascade effect is also produced: the surface tissue absorbs 660 nanometers, a road is swept for 870 nanometer infrared penetration depth, cell interference is eliminated, and therefore 905 nanometer infrared super pulse laser can be deeper. The physiotherapy instrument is simple to operate, low in price and easy to operate.

Although the invention has been described in detail with respect to the general description and the specific embodiments, it will be apparent to those skilled in the art that modifications and improvements can be made based on the invention. Therefore, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (10)

1. A portable multi-wavelength combined photon pulse physiotherapy instrument is characterized by comprising a physiotherapy instrument shell (1) and a control circuit; the physiotherapeutic instrument shell (1) comprises a handheld handle (2) positioned at the lower end and a light source control panel (3) positioned at the upper end and used for controlling the multi-wavelength combined light source on the control circuit through a key; the control circuit is arranged in the light source control panel (3), and the multi-wavelength combined light source on the control circuit is correspondingly arranged with the light outlet hole (4) of the light source control panel (3); the light source control panel (3) is connected with the control circuit through the key.

2. The portable multi-wavelength combined photon pulse physiotherapy instrument according to claim 1, wherein the multi-wavelength combined light source comprises a super-pulse laser light source with the wavelengths of 660nm visible red light, 870nm infrared light and 905 nm.

3. The portable multi-wavelength combined photon pulse physiotherapy instrument according to claim 1, characterized in that a filter is arranged between the light outlet hole (4) and the multi-wavelength combined light source.

4. The portable multi-wavelength combined photon pulse physiotherapy instrument according to claim 1, wherein the control circuit further comprises a voltage control module for controlling the multi-wavelength combined light source by controlling voltage, a rechargeable lithium battery for charging the control circuit, a linear lithium battery charging integrated circuit for charging the rechargeable lithium battery, and a microprocessor for controlling the voltage control module and the linear lithium battery charging integrated circuit, and the voltage control module, the microprocessor and the linear lithium battery charging integrated circuit are connected in sequence.

5. The portable multi-wavelength combined photon pulse physiotherapy instrument according to claim 1, wherein the keys comprise a light source frequency key for controlling the output frequency of the multi-wavelength combined light source, a duration key for controlling the output duration of the multi-wavelength combined light source, and a start or stop key for controlling the on-off state of the multi-wavelength combined light source.

6. The portable multi-wavelength combined photon pulse physiotherapy instrument according to claim 1, wherein the light source control panel (3) is circular, the light outlet (4) is circular, and the lamp beads of the multi-wavelength combined light source are uniformly arranged at the positions corresponding to the light outlet.

7. The portable multi-wavelength combined photon pulse physiotherapy instrument according to claim 1, characterized in that the hand-held handle (2) is cylindrical or cuboid.

8. The portable multi-wavelength combined photonic pulse physiotherapy instrument as claimed in claim 4, wherein the microprocessor adopts a low power consumption RISC CPU model PIC18F25K 22.

9. The portable multi-wavelength combined photonic pulse physiotherapy instrument as claimed in claim 4, wherein the linear lithium battery charging integrated circuit is of the model MCP 73883.

10. The portable multi-wavelength combined photon pulse physiotherapy instrument according to claim 5, wherein the frequency keys comprise a variable frequency of 5-1000MHZ, a fixed frequency of 5MHZ, 50MHZ, 1000 MHZ; the time length of the time length key includes 5 minutes, 2 minutes, and 1 minute.

Images