CN116712681B - Magnetic control type far infrared physiotherapy lamp - Google Patents

Abstract

The invention discloses a magnetic control type far infrared physiotherapy lamp, which comprises a fixing component and a far infrared excitation component arranged on the fixing component; the far infrared excitation assembly comprises a liquid storage tank for storing quantum dot liquid, the quantum dot liquid is in a transparent state, a light emitting structure is arranged at the bottom of the liquid storage tank, an elastic isolation film made of a light-transmitting material is arranged in the liquid storage tank, and a plurality of ferromagnetic quantum light emitting pieces are suspended and dispersed in the quantum dot liquid; the top of the liquid storage tank is provided with a quantum excitation light source, and the top of the quantum excitation light source is provided with an electromagnetic unit; the invention realizes continuous stepless regulation of the far infrared excitation intensity, has more flexible structure use, improves the use experience of users and has better physiotherapy effect.

Description

Magnetic control type far infrared physiotherapy lamp

Technical Field

The invention relates to the technical field of physiotherapy, in particular to a magnetic control type far infrared physiotherapy lamp.

Background

At present, far infrared physiotherapy lamp products generally directly adopt an electroluminescence principle, and far infrared light is generated by an infrared LED lamp to irradiate and physiotherapy the skin; because the infrared light wave crest distribution range generated by the existing infrared LED lamp is wider, the infrared light wavelength distribution range with physiotherapy effect on human body is only 4-14 microns, most of energy is converted into other useless electromagnetic waves such as visible light or infrared light with other wavelengths, and physiotherapy efficiency is difficult to improve.

The quantum dot material is adopted as a photoluminescence material, and infrared light with the wavelength of 4-14 microns and extremely narrow wavelength distribution range can be emitted under the excitation of light; however, the current quantum dot light emitting physiotherapy lamp cannot adjust the excitation intensity, and has poor use flexibility.

Disclosure of Invention

The invention aims to overcome the defects and provide the magnetic control type far infrared physiotherapy lamp with a more flexible structure.

In order to achieve the above object, the present invention is specifically as follows:

a magnetic control type far infrared physiotherapy lamp comprises a fixing component and a far infrared excitation component arranged on the fixing component;

the far infrared excitation assembly comprises a liquid storage tank for storing quantum dot liquid, the quantum dot liquid is in a transparent state, a light emitting structure is arranged at the bottom of the liquid storage tank, an elastic isolation film made of a light-transmitting material is arranged in the liquid storage tank, and a plurality of ferromagnetic quantum light emitting pieces are suspended and dispersed in the quantum dot liquid;

the top of the liquid storage tank is provided with a quantum excitation light source, and the top of the quantum excitation light source is provided with an electromagnetic unit.

The quantum light-emitting element comprises a light-transmitting sheet, one surface of the light-transmitting sheet is coated with a quantum dot material layer for stimulated emission of far infrared light, the other surface of the light-transmitting sheet opposite to the light-transmitting sheet is provided with a shielding grating, the shielding grating is of a porous structure, and a ferromagnetic body matched with the shielding grating in shape is arranged on the shielding grating.

In the invention, the light emergent structure is a Fresnel lens structure.

The quantum excitation light source comprises a light-emitting diode (LED) lamp panel and a scattering cover, wherein the scattering cover is covered on the liquid storage tank, and the LED lamp panel is fixed on the scattering cover.

In the invention, a plurality of communicated chambers are partitioned in the liquid storage tank, and each chamber is internally provided with an elastic isolating film.

The electromagnetic units are in one-to-one correspondence with the positions of the bins.

The invention further provides a far infrared excitation assembly, which further comprises an elastic liquid storage bag storing quantum dot liquid, wherein the elastic liquid storage bag is communicated with the liquid storage groove.

In the invention, the number of the elastic liquid storage bags is two, and the two elastic liquid storage bags are distributed at two ends of the liquid storage groove.

The fixing assembly comprises an adsorption bracket with a light-transmitting window and four vacuum adsorption units which are distributed on the adsorption bracket in a rectangular shape, wherein each vacuum adsorption unit comprises a vacuum chuck, an adsorption air bag and an air valve, one end of the adsorption air bag is connected to the vacuum chuck, and the air valve is arranged at the other end of the adsorption air bag.

The vacuum chuck is provided with a connecting shaft, and the connecting shaft is threaded on the adsorption bracket.

The beneficial effects of the invention are as follows: according to the invention, the quantum dot liquid of the ferromagnetic quantum light emitting part is suspended and dispersed in the liquid storage tank, and the elastic isolation film in a transparent state is arranged in the liquid storage tank, so that the pressure change of the quantum light emitting part to the elastic isolation film can be controlled by controlling the magnetic field force generated by the electromagnetic unit, the curvature radius of the elastic isolation film is changed, the projection area of the quantum light emitting part on the light emitting structure is further changed, the far infrared light intensity generated by excitation of the quantum light emitting part is controlled, the continuous stepless regulation of the far infrared excitation intensity is realized, the structure is more flexible to use, the use experience of a user is improved, and the physiotherapy effect is better.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic diagram of the structure of the far infrared excitation assembly of the present invention;

FIG. 4 is an exploded schematic view of the far infrared excitation assembly of the present invention;

FIG. 5 is a schematic cross-sectional view of a far infrared excitation assembly of the present invention;

FIG. 6 is another cross-sectional schematic view of the far infrared excitation assembly of the present invention;

FIG. 7 is a schematic diagram of a quantum light emitting device of the present invention;

FIG. 8 is a schematic cross-sectional view of a vacuum adsorption unit of the present invention;

reference numerals illustrate: 1. a fixing assembly; 11. an adsorption bracket; 12. a vacuum adsorption unit; 121. a vacuum chuck; 122. an adsorption balloon; 123. an air valve; 124. a connecting shaft; 2. a far infrared excitation assembly; 21. a liquid storage tank; 211. a light-emitting structure; 212. a bin; 22. an elastic isolation film; 23. a quantum light emitting member; 231. a light transmitting sheet; 232. a quantum dot material layer; 233. a shielding grating; 234. a ferromagnetic body; 24. a quantum excitation light source; 241. an LED lamp panel; 242. a diffusion cover; 25. an electromagnetic unit; 26. an elastic reservoir.

Detailed Description

The invention will now be described in further detail with reference to the drawings and the specific embodiments, without limiting the scope of the invention.

As shown in fig. 1 to 8, the magnetic control type far infrared physiotherapy lamp in this embodiment includes a fixing component 1 and a far infrared excitation component 2 disposed on the fixing component 1;

the far infrared excitation assembly 2 comprises a liquid storage tank 21 storing quantum dot liquid, wherein the quantum dot liquid is in a transparent state, a light emitting structure 211 is arranged at the bottom of the liquid storage tank 21, an elastic isolation film 22 made of a light-transmitting material is arranged in the liquid storage tank 21, and the elastic isolation film 22 is in an arc-shaped state of sinking towards the inside of the liquid storage tank 21 in a natural state; a plurality of quantum light emitting elements 23 with ferromagnetism are suspended and dispersed in the quantum dot liquid;

the top of the liquid storage tank 21 is provided with a quantum excitation light source 24 for enabling the quantum light emitting piece 23 to generate far infrared light, and the top of the quantum excitation light source 24 is provided with an electromagnetic unit 25.

In actual use, the far infrared excitation assembly 2 is placed on a part to be treated through the fixing assembly 1, then the quantum excitation light source 24 generates visible light to irradiate the elastic isolation film 22, the frequency of the visible light is higher than that of the far infrared light, meanwhile, the electromagnetic unit 25 generates a uniform magnetic field towards the inside of the liquid storage tank 21, and as a plurality of quantum light emitting pieces 23 with ferromagnetism are suspended in the quantum dot liquid, the quantum light emitting pieces 23 move upwards under the action of the magnetic field force and gather on the surface of the elastic isolation film 22 in an arc state, the generated visible light excites the quantum light emitting pieces 23 to generate far infrared light, the far infrared light is emitted from the light emitting structure 211, and the part to be treated is subjected to far infrared physiotherapy;

because the elastic isolation film 22 is in an arc state, an included angle exists between the surfaces of the light emitting structures 211 of the quantum light emitting elements 23, so that the effective projection area of the quantum light emitting elements 23 on the light emitting structures 211 is determined, when the magnetic field force generated by the electromagnetic units 25 is in a minimum state, the elastic isolation film 22 is recessed to the inside of the liquid storage tank 21 to the maximum extent, the curvature of the surfaces of the elastic isolation film 22 is the maximum, the projection area of the quantum light emitting elements 23 on the surfaces of the light emitting structures 211 is the minimum, the far infrared light intensity generated by the quantum light emitting elements 23 is the weakest, and as the magnetic field force generated by the electromagnetic units 25 is increased, the pressure of the quantum light emitting elements 23 on the elastic isolation film 22 causes the elastic isolation film 22 to shrink outwards, so that the curvature radius of the elastic isolation film 22 is increased, the projection area of the quantum light emitting elements 23 on the surfaces of the light emitting structures 211 is increased, more visible light is irradiated to the quantum light emitting elements 23, the far infrared light intensity generated by excitation of the quantum light emitting elements 23 is enhanced, and the adjustment of the excitation intensity is controlled.

According to the embodiment, the quantum dot liquid of the ferromagnetic quantum light emitting part 23 is suspended and dispersed in the liquid storage tank 21, and the elastic isolation film 22 in a transparent state is arranged in the liquid storage tank 21, so that the pressure change of the quantum light emitting part 23 to the elastic isolation film 22 can be controlled by controlling the magnetic force generated by the electromagnetic unit 25, the curvature radius of the elastic isolation film 22 is changed, the projection area of the quantum light emitting part 23 on the light emitting structure 211 is changed, the far infrared light intensity generated by excitation of the quantum light emitting part 23 is controlled, the continuous stepless adjustment of the far infrared excitation intensity is realized, the structure is more flexible to use, the use experience of a user is improved, and the physiotherapy effect is better.

Based on the above embodiment, further, as shown in fig. 7, the quantum light emitting element 23 includes a light transmitting sheet 231, one surface of the light transmitting sheet 231 is coated with a quantum dot material layer 232 for stimulated emission of far infrared light, a shielding grating 233 is disposed on the opposite surface of the light transmitting sheet 231, the shielding grating 233 is in a porous structure, and a ferromagnetic 234 matching the shape of the shielding grating 233 is disposed on the shielding grating 233. In this embodiment, by arranging the shielding grating 233, the visible light generated by the quantum excitation light source 24 can irradiate the quantum dot material layer 232 only through the light of the shielding grating 233, so as to excite the quantum dot material layer 232 to generate far infrared light, and the ferromagnetic 234 of the quantum light emitting element 23 is tightly adhered to the surface of the elastic isolation film 22 under the action of the magnetic field force, so that an included angle exists between the shielding grating 233 and the propagation direction of the visible light, and the included angle directly determines the excited effective area of the quantum dot material layer 232, so as to determine the visible light capable of transmitting the shielding grating 233, thereby realizing the control of the far infrared light intensity generated by the excitation of the quantum dot material layer 232 by the visible light.

Based on the above embodiment, further, as shown in fig. 2 and fig. 5, the light emitting structure 211 is a fresnel lens structure; the device is arranged in such a way that the generated far infrared light is scattered in parallel, and the far infrared physiotherapy is fully carried out on the part to be treated.

Based on the above embodiment, further, as shown in fig. 1 to 6, the quantum excitation light source 24 includes an LED lamp panel 241 and a diffusion cover 242, the diffusion cover 242 covers the liquid storage tank 21, and the LED lamp panel 241 is fixed on the diffusion cover 242; with the above arrangement, the LED lamp panel 241 generates visible light with a frequency greater than that of far infrared light, and irradiates the elastic isolation film 22 after being scattered in parallel by the scattering cover 242, so as to excite the quantum dot material layer 232 to generate far infrared light.

Based on the above embodiment, further, as shown in fig. 2 and fig. 4 to fig. 6, the reservoir 21 is divided into a plurality of chambers 212 that are communicated with each other, and each chamber 212 is provided with an elastic isolation film 22. In this embodiment, the number of the electromagnetic units 25 is plural, and the positions of the electromagnetic units 25 and the chambers 212 are in one-to-one correspondence. Specifically, the plurality of chambers 212 are arranged in two rows, and correspondingly, the plurality of electromagnetic units 25 are arranged in two rows; by the arrangement, the far infrared excitation intensity of the quantum light emitting elements 23 in each bin 212 can be controlled independently, and the flexibility of the structure is further enhanced.

Based on the above embodiment, further, as shown in fig. 1, 3 and 4, the far infrared excitation assembly 2 further includes an elastic liquid reservoir 26 storing quantum dot liquid, and the elastic liquid reservoir 26 is in communication with the liquid reservoir 21. Preferably, the number of the elastic liquid storage bags 26 is two, and the two elastic liquid storage bags 26 are distributed at two ends of the liquid storage groove 21. With the above arrangement, the quantum dot liquid in each chamber 212 is buffered by the elastic reservoir 26 to accommodate the change in radius of curvature of the elastic isolation membrane 22.

Based on the above embodiment, further, as shown in fig. 1, 2 and 8, the fixing assembly 1 includes an adsorption bracket 11 with a light-transmitting window and four vacuum adsorption units 12 distributed on the adsorption bracket 11 in a rectangular shape, each vacuum adsorption unit 12 includes a vacuum chuck 121, an adsorption air bag 122 and an air valve 123, one end of the adsorption air bag 122 is connected to the vacuum chuck 121, and the air valve 123 is disposed at the other end of the adsorption air bag 122. When in actual use, the vacuum sucker 121 contacts with skin to form a vacuum space, then the air valve 123 is closed, and the adsorption air bag 122 is continuously extruded, so that the vacuum sucker 121 is adsorbed on the surface of the skin, the fixation of the far infrared excitation component 2 is realized, and the far infrared excitation component 2 is used for stably carrying out far infrared physiotherapy on a part to be treated; the far infrared light generated by the far infrared excitation component 2 irradiates the part to be treated through the light-transmitting window.

Based on the above embodiment, further, as shown in fig. 1, 2 and 8, the vacuum chuck 121 has a connecting shaft 124, and the connecting shaft 124 is threaded on the suction bracket 11. So set up, through rotatory vacuum chuck 121 for vacuum chuck 121 removes relative absorption support 11, thereby adjusts the interval between light-emitting structure 211 and the skin of treating physiotherapy position, in order to avoid light-emitting structure 211 direct and treat the skin contact of physiotherapy position and cause the scald, thereby adopts higher far infrared light intensity to treat physiotherapy position and carry out physiotherapy, improves physiotherapy effect.

The foregoing description is only one preferred embodiment of the invention, and therefore all changes and modifications that come within the meaning and range of equivalency of the structures, features and principles of the invention are intended to be embraced therein.

Claims (10)

1. The magnetic control type far infrared physiotherapy lamp is characterized by comprising a fixing component and a far infrared excitation component arranged on the fixing component;

the far infrared excitation assembly comprises a liquid storage tank for storing quantum dot liquid, the quantum dot liquid is in a transparent state, a light emitting structure is arranged at the bottom of the liquid storage tank, an elastic isolation film made of a light-transmitting material is arranged in the liquid storage tank, and a plurality of ferromagnetic quantum light emitting pieces are suspended and dispersed in the quantum dot liquid;

the top of the liquid storage tank is provided with a quantum excitation light source, and the top of the quantum excitation light source is provided with an electromagnetic unit.

2. The magnetic control type far infrared physiotherapy lamp according to claim 1, wherein the quantum light-emitting element comprises a light-transmitting sheet, one surface of the light-transmitting sheet is coated with a quantum dot material layer for stimulated emission of far infrared light, a shading grating is arranged on the other surface of the light-transmitting sheet opposite to the light-transmitting sheet, the shading grating is of a porous structure, and a ferromagnetic body matched with the shape of the shading grating is arranged on the shading grating.

3. The magnetron type far infrared physiotherapy lamp according to claim 1, wherein the light emitting structure is a fresnel lens structure.

4. The magnetic control type far infrared physiotherapy lamp according to claim 1, wherein the quantum excitation light source comprises an LED lamp panel and a scattering cover, the scattering cover is covered on the liquid storage tank, and the LED lamp panel is fixed on the scattering cover.

5. The magnetic control type far infrared physiotherapy lamp according to claim 1, wherein a plurality of communicated chambers are partitioned in the liquid storage tank, and an elastic isolation film is arranged in each chamber.

6. The magnetic control type far infrared physiotherapy lamp according to claim 5, wherein the electromagnetic units are multiple in number, and the electromagnetic units are in one-to-one correspondence with the positions of the bins.

7. The magnetically controlled far infrared physiotherapy lamp of claim 1, wherein the far infrared excitation assembly further comprises an elastic reservoir storing a quantum dot liquid, the elastic reservoir being in communication with the reservoir.

8. The magnetic control type far infrared physiotherapy lamp according to claim 7, wherein the number of the elastic liquid storage bags is two, and the two elastic liquid storage bags are distributed at two ends of the liquid storage groove.

9. The magnetron type far infrared physiotherapy lamp according to any one of claims 1 to 8, wherein the fixing assembly comprises an adsorption bracket with a light-transmitting window and four vacuum adsorption units which are distributed on the adsorption bracket in a rectangular shape, each vacuum adsorption unit comprises a vacuum chuck, an adsorption air bag and an air valve, one end of the adsorption air bag is connected to the vacuum chuck, and the air valve is arranged at the other end of the adsorption air bag.

10. The magnetic control type far infrared physiotherapy lamp as set forth in claim 9, wherein the vacuum chuck has a connecting shaft, and the connecting shaft is threaded on the adsorption bracket.