CN110538068A - LED light source assembly for thermal moxibustion therapeutic apparatus and preparation method thereof - Google Patents

Abstract

the invention discloses an LED light source assembly for a thermal moxibustion therapeutic apparatus, which comprises an aluminum substrate and LED lamp beads, wherein the LED lamp beads comprise 1 LED red light lamp bead with the emission peak wavelength of 640nm and 6 LED near-infrared lamp beads with the wavelength of 700 nm-1600 nm; the LED red light lamp bead with the emission peak wavelength of 640nm is fixedly arranged in the center of the surface of the aluminum substrate and used for indicating and irradiating human body parts, so that the thermosensitive acupuncture points can be accurately positioned; the 6 LED near-infrared lamp beads with the wavelength between 700nm and 1600nm are uniformly arranged on the surface of the aluminum substrate in an annular shape and are used for generating photothermal action on heat-sensitive acupuncture points of a human body to play a role in heat-sensitive moxibustion treatment. The invention adopts the LED light source as the heat source of the heat-sensitive moxibustion, has no smoke, is not easy to burn, is easy to operate and realizes the environment-friendly heat moxibustion.

Description

LED light source assembly for thermal moxibustion therapeutic apparatus and preparation method thereof

Technical Field

The invention belongs to the technical field of thermal moxibustion treatment, and particularly relates to an LED light source assembly for a thermal moxibustion treatment instrument. In particular to a preparation method of the LED light source assembly for the thermal moxibustion therapy apparatus.

Background

Acupuncture and moxibustion is a subject that studies the meridians, acupoints and moxibustion methods and discusses the law of preventing and treating diseases by acupuncture and moxibustion, guided by the theory of traditional Chinese medicine. The moxibustion therapy is a treatment method which is characterized in that moxa heat generated by moxa stick materials made of folium artemisiae argyi stimulates acupuncture points or specific parts on the body surface and regulates the physiological and biochemical functions of human body disorder by exciting the activity of meridian qi, thereby achieving the purpose of preventing and treating diseases. Thermosensitive moxibustion belongs to one of acupuncture and moxibustion. The heat-sensitive moxibustion is a new therapy which utilizes the action of light heat radiation to suspend moxibustion heat-sensitive acupuncture points, excites heat-sensitive moxibustion senses such as diathermy, heat diffusion, heat transfer, local non-micro-heat far-part heat, surface non-micro-heat deep-part heat, non-heat and the like and channel qi conduction, and applies individualized saturated desensitization moxibustion quantity, thereby improving the moxibustion curative effect.

The moxibustion generates physical factor infrared rays which are very effective and suitable for organisms when burning, and the radiation energy spectrum is between 0.8 and 5.6 mu m, which shows that the radiation energy spectrum when burning moxa has not only heat radiation and far infrared radiation, but also near infrared radiation, the energy spectrum of the moxibustion has near infrared radiation which accounts for the main components, and the peak spectrum is near 1.5 mu m. According to the principle of physics, the far infrared ray can directly act on the shallow part of the human body and radiate heat by conduction; the near infrared ray is far from the infrared ray, has short wavelength and strong energy, can directly permeate deep tissues, has the depth of penetrating a body to be about 10mm, and is transmitted to a wider part through a capillary network to be absorbed by a human body.

However, the traditional moxibustion mainly has the problems and risks that the labor intensity of a moxibustion applicator is high, smoke is heavy, residual smell is easy to remain on clothes and hair, moxibustion parts are easy to burn, and the like.

Therefore, in order to overcome the defects of the traditional moxibustion, the near infrared light radiation generated by the LED light source assembly is used for simulating the traditional moxibustion, and innovative Chinese medical appliances are developed by modern advanced technological means and used for a mode of heat-sensitive moxibustion treatment.

disclosure of Invention

The invention aims to provide an LED light source assembly for a thermal moxibustion therapeutic apparatus and a preparation method thereof, and aims to solve the problems that the traditional moxibustion in the prior art is high in labor intensity of moxibustion workers, heavy in smoke, prone to residual odor on clothes and hair, prone to burn moxibustion parts and risks.

In order to achieve the purpose, the invention adopts the following technical scheme:

An LED light source assembly for a thermal moxibustion therapeutic apparatus comprises an aluminum substrate and LED lamp beads, wherein the LED lamp beads comprise 1 LED red light lamp bead with the emission peak wavelength of 640nm and 6 LED near-infrared lamp beads with the wavelength of 700 nm-1600 nm; the LED red light lamp bead with the emission peak wavelength of 640nm is fixedly arranged in the center of the surface of the aluminum substrate and used for indicating and irradiating human body parts, so that the thermosensitive acupuncture points can be accurately positioned; the 6 LED near-infrared lamp beads with the wavelength between 700nm and 1600nm are uniformly arranged on the surface of the aluminum substrate in an annular shape and are used for generating photothermal action on heat-sensitive acupuncture points of a human body to play a role in heat-sensitive moxibustion treatment.

Preferably, 1 LED red light bead with the emission peak wavelength of 640nm and 6 LED near-infrared light beads with the wavelength of 700 nm-1600 nm are electrically connected in series.

Preferably, the emission peak wavelengths of the 6 LED near-infrared lamp beads are 740nm, 840nm, 940nm, 980nm, 1050nm and 1500nm respectively.

Preferably, the 6 LED near-infrared lamp beads comprise 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 840nm and 940nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 740nm, 840nm and 940nm are symmetrically distributed on the surface of the aluminum substrate.

Preferably, the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 740nm, 840nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 740nm, 840nm and 980nm are symmetrically distributed on the surface of the aluminum substrate.

preferably, the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 740nm, 940nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 740nm, 940nm and 980nm are symmetrically distributed on the surface of the aluminum substrate.

Preferably, the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 840nm, 940nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelengths in the 840nm, 940nm and 980nm are symmetrically distributed on the surface of the aluminum substrate.

Preferably, the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 840nm, 1050nm and 1500nm respectively, and the 2 LED near-outer lamp beads with emission peak wavelengths of 840nm, 1050nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate.

Preferably, the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 980nm, 1050nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 980nm, 1050nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate.

The invention also provides a preparation method of the LED light source assembly for the thermal moxibustion therapeutic apparatus, which comprises the following steps:

S1, preparing an aluminum substrate, wherein the center of the surface of the aluminum substrate is provided with 1 central light groove, and the surface of the aluminum substrate is provided with 6 annular outer light grooves which are uniformly distributed at equal intervals by taking the center of the surface of the aluminum substrate as a circle center;

S2, manufacturing a circuit for connecting 1 central light groove and 6 outer light grooves in series on an aluminum substrate through the process flow of grinding a plate → pasting a film → exposing → developing → etching → film removing → drying → silk screen process → routing;

S3, preparing 1 LED red light bead with the emission peak wavelength of 640nm and 6 LED near-infrared beads with the wavelength of 700 nm-1600 nm in a matching manner, and respectively installing the LED red light beads and the 6 LED near-infrared beads in a center lamp groove and an outer lamp groove to finish the manufacture of the LED light source assembly for the thermal moxibustion therapeutic apparatus.

The invention has the technical effects and advantages that: compared with the prior art, the LED light source assembly for the thermal moxibustion therapeutic apparatus provided by the invention has the following advantages:

1. The LED light source is used as the heat source of the heat-sensitive moxibustion, so that the heat-sensitive moxibustion is smoke-free, not easy to burn, easy to operate and environment-friendly;

2. According to the invention, the LED red light bead emitting the peak wavelength of 640nm is used as a luminous body to form a visible light beam for indicating and irradiating human body parts, so that the thermosensitive acupuncture points can be accurately positioned; the 6 LED near-infrared lamp beads with the wavelength between 700nm and 1600nm are used for generating photothermal to act on the thermosensitive acupuncture points of the human body, so that the thermosensitive moxibustion therapy effect is achieved.

Drawings

FIG. 1 is a schematic structural diagram of an aluminum substrate according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. The specific embodiments described herein are merely illustrative of the invention and do not delimit the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

example 1

The invention provides an LED light source assembly for a thermal moxibustion therapeutic apparatus as shown in figure 1, which comprises an aluminum substrate and LED lamp beads, wherein the LED lamp beads comprise 1 LED red light lamp bead with the emission peak wavelength of 640nm and 6 LED near-infrared lamp beads with the wavelength of 700 nm-1600 nm; the LED red light bead with the emission peak wavelength of 640nm is fixedly arranged at the center (shown as the position I in the figure 1) of the surface of an aluminum substrate (the mark 8 in the figure 1 is the aluminum substrate) and used for indicating and irradiating human body parts, so that thermosensitive acupuncture points can be accurately positioned; the LED near-infrared lamp beads with the wavelengths between 700nm and 1600nm are uniformly arranged on the surface of the aluminum substrate in an annular mode and are used for generating photothermal action on heat-sensitive acupuncture points of a human body to play a role in heat-sensitive moxibustion treatment, and the LED red light lamp beads with the emission peak wavelengths of 640nm and the LED near-infrared lamp beads with the wavelengths between 700nm and 1600nm are electrically connected in series.

The preparation method comprises the following specific steps:

s1, preparing an aluminum substrate, wherein the center of the surface of the aluminum substrate is provided with 1 central light groove, and the surface of the aluminum substrate is provided with 6 annular outer light grooves which are uniformly distributed at equal intervals by taking the center of the surface of the aluminum substrate as a circle center;

s2, manufacturing a circuit for connecting 1 central light groove and 6 outer light grooves in series on an aluminum substrate through the process flow of grinding a plate → pasting a film → exposing → developing → etching → film removing → drying → silk screen process → routing;

s3, preparing 1 LED red light bead with the emission peak wavelength of 640nm and 6 LED near-infrared beads with the wavelength of 700 nm-1600 nm in a matching manner, and respectively installing the LED red light beads and the 6 LED near-infrared beads in a center lamp groove and an outer lamp groove to finish the manufacture of the LED light source assembly for the thermal moxibustion therapeutic apparatus.

Specifically, the emission peak wavelengths of the 6 LED near-infrared lamp beads are 740nm, 840nm, 940nm, 980nm, 1050nm and 1500nm, respectively, as shown in the positions from (c) to (c) in fig. 1.

example 2

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 840nm and 940nm respectively, and the LED near-infrared lamp beads with the same wavelength in the 740nm, 840nm and 940nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 3

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 840nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelength in 740nm, 840nm and 980nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 4

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 840nm and 1050nm respectively, and the LED near-infrared lamp beads with the same wavelength in 740nm, 840nm and 1050nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 5

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 840nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelength in 740nm, 840nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 6

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 940nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelength in the 740nm, 940nm and 980nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

example 7

Different from embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 940nm and 1050nm, respectively, and the LED near-infrared lamp beads with the same wavelength in 740nm, 940nm and 1050nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 8

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 940nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelength in 740nm, 940nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 9

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 980nm and 1050nm, respectively, and the LED near-infrared lamp beads with the same wavelength in 740nm, 980nm and 1050nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 10

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 980nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 740nm, 980nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

example 11

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 1050nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelength in 740nm, 1050nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 12

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 840nm, 940nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 840nm, 940nm and 980nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 13

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 840nm, 940nm and 1050nm respectively, and the LED near-infrared lamp beads with the same wavelength in 840nm, 940nm and 1050nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 14

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 840nm, 940nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelength in 840nm, 940nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 15

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 840nm, 980nm and 1050nm, and the LED near-infrared lamp beads with the same wavelengths in 840nm, 980nm and 1050nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

example 16

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 840nm, 980nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 840nm, 980nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 17

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 840nm, 1050nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 840nm, 1050nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 18

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 940nm, 980nm and 1050nm respectively, and the LED near-infrared lamp beads with the same wavelengths in the wavelengths of 840nm, 980nm and 1050nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 19

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 940nm, 980nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelengths in the wavelengths of 840nm, 980nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

Example 20

Different from the embodiment 1, the specific 6 LED near-infrared lamp beads include 2 LED near-infrared lamp beads with emission peak wavelengths of 980nm, 1050nm and 1500nm, respectively, and the LED near-infrared lamp beads with the same wavelength in 980nm, 1050nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate. As shown in fig. 1, three groups of LED near-infrared beads with different wavelengths are symmetric (c), and (c).

The following table is derived for the LED near-infrared lamp beads (specific positions) according to the embodiment:

Examples

1

2

3

4

5

6

7

1

640nm

740nm

840nm

940nm

980nm

1050nm

1500nm

2

640nm

740nm

840nm

940nm

740nm

840nm

940nm

3

640nm

740nm

840nm

980nm

740nm

840nm

980nm

4

640nm

740nm

840nm

1050nm

740nm

840nm

1050nm

5

640nm

740nm

840nm

1500nm

740nm

840nm

1500nm

6

640nm

740nm

940nm

980nm

740nm

940nm

980nm

7

640nm

740nm

940nm

1050nm

740nm

940nm

1050nm

8

640nm

740nm

940nm

1500nm

740nm

940nm

1500nm

9

640nm

740nm

980nm

1050nm

740nm

980nm

1050nm

10

640nm

740nm

980nm

1500nm

740nm

980nm

1500nm

11

640nm

740nm

1050nm

1500nm

740nm

1050nm

1500nm

12

640nm

840nm

940nm

980nm

840nm

940nm

980nm

13

640nm

840nm

940nm

1050nm

840nm

940nm

1050nm

14

640nm

840nm

940nm

1500nm

840nm

940nm

1500nm

15

640nm

840nm

980nm

1050nm

840nm

980nm

1050nm

16

640nm

840nm

980nm

1500nm

840nm

980nm

1500nm

17

640nm

840nm

1050nm

1500nm

840nm

1050nm

1500nm

18

640nm

940nm

980nm

1050nm

940nm

980nm

1050nm

19

640nm

940nm

980nm

1500nm

940nm

980nm

1500nm

20

640nm

980nm

1050nm

1500nm

980nm

1050nm

1500nm

In summary, the following steps: the LED light source is used as the heat source of the heat-sensitive moxibustion, so that the heat-sensitive moxibustion is smoke-free, not easy to burn, easy to operate and environment-friendly; according to the invention, the LED red light bead emitting the peak wavelength of 640nm is used as a luminous body to form a visible light beam for indicating and irradiating human body parts, so that the thermosensitive acupuncture points can be accurately positioned; the 6 LED near-infrared lamp beads with the wavelength between 700nm and 1600nm are used for generating photothermal to act on the thermosensitive acupuncture points of the human body, so that the thermosensitive moxibustion therapy effect is achieved.

finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (10)

1. The utility model provides a LED light source combination for temperature sensing moxibustion therapeutic instrument, includes aluminium base board and LED lamp pearl, its characterized in that: the LED lamp beads comprise 1 LED red light bead with the emission peak wavelength of 640nm and 6 LED near-infrared lamp beads with the wavelength of 700 nm-1600 nm;

The LED red light lamp bead with the emission peak wavelength of 640nm is fixedly arranged in the center of the surface of the aluminum substrate and used for indicating and irradiating human body parts, so that the thermosensitive acupuncture points can be accurately positioned; the 6 LED near-infrared lamp beads with the wavelength between 700nm and 1600nm are uniformly arranged on the surface of the aluminum substrate in an annular shape and are used for generating photothermal action on heat-sensitive acupuncture points of a human body to play a role in heat-sensitive moxibustion treatment.

2. the LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: 1 LED red light bead with the emission peak wavelength of 640nm and 6 LED near-infrared light beads with the wavelength of 700 nm-1600 nm are electrically connected in series.

3. The LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: the emission peak wavelengths of the 6 LED near-infrared lamp beads are respectively 740nm, 840nm, 940nm, 980nm, 1050nm and 1500 nm.

4. The LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: the 6 LED near-infrared lamp beads comprise 2 LED near-infrared lamp beads with emission peak wavelengths of 740nm, 840nm and 940nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 740nm, 840nm and 940nm are symmetrically distributed on the surface of the aluminum substrate.

5. The LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 740nm, 840nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 740nm, 840nm and 980nm are symmetrically distributed on the surface of the aluminum substrate.

6. The LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 740nm, 940nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 740nm, 940nm and 980nm are symmetrically distributed on the surface of the aluminum substrate.

7. The LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 840nm, 940nm and 980nm respectively, and the LED near-infrared lamp beads with the same wavelengths in the 840nm, 940nm and 980nm are symmetrically distributed on the surface of the aluminum substrate.

8. The LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 840nm, 1050nm and 1500nm respectively, and the 2 LED near-outer lamp beads with emission peak wavelengths of 840nm, 1050nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate.

9. The LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, wherein: the 6 LED near-infrared lamp beads comprise 2 LED near-outer lamp beads with emission peak wavelengths of 980nm, 1050nm and 1500nm respectively, and the LED near-infrared lamp beads with the same wavelengths in 980nm, 1050nm and 1500nm are symmetrically distributed on the surface of the aluminum substrate.

10. A method for preparing the LED light source assembly for the thermal moxibustion therapy apparatus of claim 1, comprising the steps of:

S1, preparing an aluminum substrate, wherein the center of the surface of the aluminum substrate is provided with 1 central light groove, and the surface of the aluminum substrate is provided with 6 annular outer light grooves which are uniformly distributed at equal intervals by taking the center of the surface of the aluminum substrate as a circle center;

S2, manufacturing a circuit for connecting 1 central light groove and 6 outer light grooves in series on an aluminum substrate through the process flow of grinding a plate → pasting a film → exposing → developing → etching → film removing → drying → silk screen process → routing;

S3, preparing 1 LED red light bead with the emission peak wavelength of 640nm and 6 LED near-infrared beads with the wavelength of 700 nm-1600 nm in a matching manner, and respectively installing the LED red light beads and the 6 LED near-infrared beads in a center lamp groove and an outer lamp groove to finish the manufacture of the LED light source assembly for the thermal moxibustion therapeutic apparatus.