CN210960459U - Intelligence far infrared physiotherapy brassiere - Google Patents

Abstract

The utility model relates to an intelligent far infrared physiotherapy bra, which comprises two lower supporting bowls and a controller which are symmetrically distributed, wherein the lower supporting bowls comprise electric heating layers; the electric heating layer comprises a heating layer and an infrared reflecting layer; the heating layer is a carbon nanofiber layer, emits heat in a far infrared mode, is connected with a low-voltage direct-current power supply through the controller, and is used for starting and stopping the heating action of the heating layer and adjusting the heating temperature; the infrared reflecting layer is arranged on the outer side of the heating layer, and the reflecting surface faces the heating layer and is used for reflecting far infrared rays generated by the heating layer to the direction of a human body. The utility model discloses a safe heating method realizes the physiotherapy function of heating to the chest.

Description

Intelligence far infrared physiotherapy brassiere

Technical Field

The utility model relates to a women's underwear, concretely relates to intelligence far infrared physiotherapy brassiere.

Background

With the continuous development of society, women have higher and higher requirements on the selection and the use of bras. The bra has the functions of supporting, protecting and beautifying in daily wearing, and a plurality of additional functions are gradually added, such as shaping, chest ventilation, massage, health care and the like, which are accepted by women.

However, many women are thin even when wearing the garment at low temperature for pursuing beauty, and the body is not protected from cold; in addition, under the conditions of recycling a large amount of pesticides, transgenosis, synthetic materials, waste and the like, the living standard is greatly improved, and meanwhile, a plurality of side effects are hidden, the side effects can easily invade the human body through diet, living habits, wearing habits, sanitation and the like, and for women, the traditional Chinese medicine preparation is similar to breast diseases such as hyperplasia of mammary glands and breast cancer, has the characteristic of high morbidity and is found to be in a middle and late stage.

Therefore, some bras have increased the heating physiotherapy function at present. If a heating wire, graphene glue or a graphene heating film is arranged in the cup to be electrified and heated. But because the heating wire is not corrosion resistant and easy to break, the service life of the bra is greatly reduced; the graphene glue is formed by mixing and curing graphene powder and certain chemical glue, has extremely poor air permeability, and is easy to become a pathogen due to unhealthy compound glue; compared with the prior two materials, the graphene heating film has obvious advantages, almost all wearing requirements can be met, the defect of the graphene heating film is that the graphene heating film is not breathable, and the specific application range of the graphene heating film in the wearing field is influenced to a great extent.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides an intelligence far infrared physiotherapy brassiere. This brassiere passes through safe heating methods, realizes the physiotherapy function of heating to the chest.

In order to achieve the above object, the utility model provides a following technical scheme:

an intelligent far infrared physiotherapy bra is characterized by comprising two lower support bowls and a controller, wherein the lower support bowls are symmetrically distributed and comprise electric heating layers;

the electric heating layer comprises a heating layer and an infrared reflecting layer; the heating layer is a carbon nanofiber layer, emits heat in a far infrared mode, is connected with a low-voltage direct-current power supply through the controller, and is used for starting and stopping the heating action of the heating layer and adjusting the heating temperature; the infrared reflecting layer is arranged on the outer side of the heating layer, and the reflecting surface faces the heating layer and is used for reflecting far infrared rays generated by the heating layer to the direction of a human body.

Further, the shape of the heating layer corresponds to that of the lower supporting bowl; the electrode strips drawn along the outer edge of the heating layer are not closed and are U-shaped electrode strips; the U-shaped electrode strips are inwards deflected and contracted by a preset radius towards the inside of the heating layer and are drawn in a closed manner to form annular electrode strips; the annular electrode strip and the U-shaped electrode strip are connected with positive and negative electrodes through leads, and the leads are led out from one end of the annular electrode strip close to the opening of the U-shaped electrode strip.

Furthermore, the heating layer is provided with a finger-inserted positive and negative electrode strip, and the finger-inserted positive and negative electrode strip comprises a positive and negative main electrode strip which are parallel to each other and a plurality of positive and negative sub-electrode strips which are connected with the side edges of the positive and negative main electrode strip and are arranged in parallel in a staggered manner.

Furthermore, the heating layer is of a hollow heating structure, and the inner side and the outer side of the heating layer are respectively connected with the positive electrode strip and the negative electrode strip through leads; the electrodes of the hollow heating structure are designed into a U shape or a square shape.

Furthermore, a plurality of temperature sensing probes are uniformly distributed on the heating layer and are respectively connected with the controller through a temperature control module.

Further, the infrared reflecting layer is a water-based aluminum reflecting coating layer with a matrix distribution wave point pattern.

Further, the electric heating layer also comprises a circuit integration device and a first connector; the line integration device is arranged on the electric heating layer and is connected with the first connector through an electric lead; the underwear also comprises a parallel device; the parallel device comprises an electric wire and two second connectors which are respectively connected by an electric wire;

the electric heating layers in the two lower supporting bowls are connected with the second connector in a splicing mode through the first connector respectively; the parallel device is connected with the controller through the electric wire.

Further, the underwear also comprises a first magnetic suction buckle; the controller comprises a display screen, a switch, an adjusting button, a second magnetic suction buckle and a connecting head; the parallel device is connected with the first magnetic buckle through the electric wire; the first magnetic attraction buckle is connected with the second magnetic attraction buckle through magnetic attraction force; the controller is connected with the power supply through the connecting head, and the display screen is used for displaying the current set temperature and the preset time; the switch is used for switching on and off the heating work of the electric heating layer; the adjusting button is used for accurately adjusting the heating temperature of the electric heating layer.

Further, the power supply is a battery, the controller comprises a wireless control chip and a mobile phone, the battery is connected with the parallel device through the wireless control chip, and the wireless control chip is in communication connection with the mobile phone to control the electric heating layer.

Further, the underwear also comprises a side position, wherein the side position comprises a zipper and a front middle position; the middle parts of the two lower supporting bowls are connected through the front middle position, the lower parts of the two lower supporting bowls are connected with the side position and the front middle position through the zippers, and the electric heating layer can be disassembled and assembled after the lower supporting bowls are unzipped through the zippers.

The utility model has the advantages that:

the utility model has simple structure, and different heating physical therapy effects can be realized by different electrode design modes in the heating layer; the electric heating layer is convenient to assemble and disassemble through the zipper and the splicing of the first connector and the second connector, and can realize constant-temperature heating and keep temperature comfort through the matching use of the temperature sensing probe and the controller; under the prerequisite of guaranteeing that women's chest is pleasing to the eye, comfortable, moulding, utilize the nanometer carbon fiber layer to make low voltage heating element on the layer that will generate heat, through its electric heating of low-voltage direct current power supply, reach the effect of heating safely to the chest, under the circumstances of not circular telegram, also can utilize "spontaneous heating" of nanometer carbon fiber layer to keep warm the chest, to a certain extent, solved the women and kept warm the potential safety hazard under the insufficient condition. Simultaneously, carbon nanofiber layer pliability is good, ventilative, safe in utilization, and heating brassiere long service life traditional relatively still has the fuel effect, promotes blood circulation to reach the activation energy, alleviate tired effect, when heating, through far-infrared to the key physiotherapy in chest acupuncture point, can improve the blood circulation of chest in daily dressing, prevent the emergence of chest disease. Under the cooperation of controller, can real-time audio-visual understanding self chest health, when detecting women's chest health, convenient real-time physiotherapy lets the women obtain more sense of security.

Drawings

FIG. 1 is a schematic view of the appearance of the intelligent far infrared physiotherapy bra of the present invention;

FIG. 2 is a structural diagram of the lower supporting bowl of the present invention;

FIG. 3 is a structural view of the middle electric heating layer of the present invention;

FIG. 4 is a circuit diagram of the intelligent far infrared physiotherapy bra of the utility model;

FIG. 5 is a layout diagram of the finger-shaped electrode of the heating layer of the present invention;

FIG. 6 is a layout view of U-shaped electrodes of the heating layer of the present invention;

FIG. 7 is a diagram of the arrangement of the electrodes in the shape of a circle in the middle heating layer of the present invention;

FIG. 8 is an electrode layout diagram of the U-shaped and annular electrode strips combined in the middle heating layer of the present invention;

FIG. 9 is a schematic view of a parallel connection device according to the present invention;

FIG. 10 is a schematic structural view of a controller according to the present invention;

FIG. 11 is a flow chart of the intelligent far infrared physiotherapy bra of the utility model;

FIG. 12 is a graph showing a wavelength range of far infrared rays generated from a filamentous nanocarbon material.

Wherein: 1. side comparison positions; 11. a zipper; 12. a front middle position; 2. a bowl is held down; 21. a skin-friendly layer; 22. an electric heating layer; 221. a line integration device; 222. a first connector; 223. a heat dissipation protective layer; 224. a heat generating layer; 2241. a temperature sensing probe; 225. an infrared reflecting layer; 23. a sponge layer; 24. outer layer cloth; 25. a decorative layer; 3. clamping and bending; 4. a first magnetic catch; 5. a parallel device; 51. an electric wire; 52. a second connector; 6. a controller; 61. a display; 62. a switch; 63. an adjustment button; 64. a second magnetic catch; 65. connecting a power head; 66. and (4) conducting wires.

Detailed Description

The following description will be made in detail with reference to the accompanying drawings and examples. The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

In the present specification, terms of orientation or positional relationship such as up, down, left, right, inside, outside, front, rear, head, and tail are established based on the orientation or positional relationship shown in the drawings. The corresponding positional relationship may also vary depending on the drawings, and therefore, should not be construed as limiting the scope of protection.

The present invention relates to a portable electronic device, and more particularly, to a portable electronic device, which can be connected to a portable electronic device, and can be connected to a portable electronic device through a connection structure, such as a connector, a. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

This embodiment has recorded an intelligence far infrared physiotherapy brassiere, as shown in fig. 1 the brassiere include side than position 1, lower support bowl 2 and press from both sides position 3. The two symmetrically distributed lower supporting bowls 2 are respectively arranged between the side comparison position 1 and the clamping bending position 3.

The side position 1 comprises a zipper 11 and a front middle position 12, the middles of the two lower supporting bowls 2 are connected through the front middle position 12, the lower parts of the two lower supporting bowls 2 are connected with the side position 1 and the front middle position 12 through the zipper 11, and the zipper 11 can be pulled outwards from the side of the front middle position 12.

As shown in fig. 2, the lower bowl 2 has a multi-layer structure, which comprises a skin-friendly layer 21, an electric heating layer 22, a sponge layer 23, an outer layer cloth 24 and a decoration layer 25 from inside to outside. The electric heating layer 22 is arranged between the skin-friendly layer 21 and the sponge layer 23, and the electric heating layer 22 can be freely disassembled and assembled after the zipper 11 is unzipped.

As shown in fig. 2 and 3, the electrothermal layer 22 may be rectangular, oval, or other shape. A line integration device 221 is further disposed on the electrothermal layer 22, the line integration device 221 is connected to a first connector 222 through an electric wire, as shown in fig. 4, and the first connector 222 is connected to the parallel device 5.

The electric heating layer 22 is composed of a protective layer 223, a heating layer 224 and an infrared reflecting layer 225, the heating layer 224 is sandwiched between the two protective layers 223 and is tightly connected with the protective layers 223 through gluing, the infrared reflecting layer 225 is arranged on the outer side of one protective layer 223 and is connected with the sponge layer 23, the reflecting surface of the infrared reflecting layer 225 faces the heating layer 224, far infrared rays generated by the heating layer 224 can be reflected towards the human body, and the absorption rate of the human body to the far infrared rays is improved.

In this embodiment, the heating layer 224 is provided with the finger-inserted positive and negative electrode strips, as shown in fig. 5, the positive and negative electrode strips include positive and negative main electrode strips and positive and negative sub-electrode strips, wherein the positive and negative main electrode strips are arranged in parallel, the positive and negative sub-electrode strips are respectively connected with the sides of the positive and negative main electrode strips, and the positive and negative sub-electrode strips are arranged in parallel in a manner of being interlaced with each other in a finger insertion manner. In this embodiment, the electrode strips are made of conductive silver paste having excellent conductivity.

The heat generating layer 224 can also be arranged in a hollow heat generating structure, and the electrodes are designed in a U shape or a clip shape, as shown in FIGS. 6 and 7. A notch is arranged in the heating layer 224 designed by the U-shaped electrode, and a lead is led out from the notch to be connected with the electrode strip, so that complex circuits can be conveniently integrated. In the heating layer 224 designed by the square-wave electrode, the inside and the outside of the heating layer 224 are respectively connected with a positive electrode strip and a negative electrode strip through leads, and the leads connected with the electrodes are made of high-temperature resistant materials to prevent the leads from being embrittled and aged by being baked for a long time. Different with inserting finger-type electrode heating structure, hollow heating structure is after the circular telegram, because the length of positive and negative electrode strip differs, when electric charge moves between the two poles of the earth, in shorter electrode one end, the electric charge is concentrated, and long electrode one end, the electric charge is sparse gradually, so produced temperature reduces from inside to outside electrode one end gradually, hollow structure makes the nipple portion that is located in the middle not receive the influence of heating, and guarantee ventilative, play the physiotherapy of heating that massages with different temperatures by the nipple to the breast side to the chest, avoided the nipple to receive the high temperature promptly, again to the acupuncture point physiotherapy that heats around the nipple, reach the effect of key nursing.

Or the shape of the heating layer 224 corresponds to that of the bra lower supporting bowl 2, the electrodes are designed as shown in fig. 8, one electrode strip is drawn along the outer edge of the heating layer 224 and is not closed to form a U-shaped electrode strip, the other electrode strip is the same as the outer edge of the heating layer 224 in shape, inwardly deflects and contracts with a preset radius and is closed to form a ring-shaped electrode strip, the ring-shaped electrode strip is arranged at one end close to the opening of the U-shaped electrode strip, a lead is led out to the outer edge in a straight line mode, and the ring-shaped electrode strip and the U-shaped electrode strip are connected with a positive electrode. The electrode arrangement mode can ensure that the heating layer 224 does not need to adopt a hollow structure, the center does not generate heat, the nipple position is protected, the same distance between the two electrodes can be ensured, the heating layer 224 generates heat uniformly, and the purpose of comprehensively and uniformly nursing the breasts and acupuncture points is achieved.

Further, the protection layer 223 is a thin film made of a material with strong heat dissipation capability, temperature resistance and insulation, so as to protect the heating layer 224 and also fully dissipate heat, so as to transfer heat to the human body.

Generate heat the nanometer carbon fiber layer that layer 224 formed for novel nanometer carbon fiber material preparation, used novel nanometer carbon fiber material has flexibility, ventilative and possess the high heat conductivility of high far-infrared emissivity (see fig. 12), it can absorb self with the slight temperature change of object on every side, distribute the conduction with the form of far infrared again and come out, still usable electricity generates heat and realizes the far infrared transmission, make this carbon fiber material have efficient far infrared physiotherapy effect from this, make underwear keep warm, have obvious effect in the aspect of the physiotherapy.

The far infrared physiotherapy in the embodiment can be realized in two ways, firstly, the emissivity of the carbon nanofiber material is as high as 0.87, and the carbon nanofiber material can release energy by far infrared rays of 4-16 micrometers after absorbing environmental energy; secondly, after the heating layer 224 is powered by weak current (3V-5V direct current electric field) to generate heat, the temperature is rapidly increased to 35-55 ℃ within 10s, and the heat generates 4-16 micron far infrared rays. The far infrared waves generated by the two modes can directly penetrate through skin and subcutaneous tissues, act on blood vessels, nerve endings and lymphatic vessels to cause molecular resonance, and realize the functions of accelerating blood circulation, relieving ache, eliminating inflammation and the like. Different from the traditional isolated heat preservation mode, the electric heating layer 22 depends on the principle of absorption and re-heat dissipation, and under the condition of no electricity, after the temperature of the human body is absorbed by the electric heating layer 22, the electric heating layer 22 gives off heat in a far infrared mode, and the human body (chest) is kept warm. The far infrared rays can be absorbed by the human body and can generate heat effect to the human body, so that the blood circulation is promoted, and the beneficial effects of activating energy and relieving fatigue are achieved.

The infrared reflecting layer 225 is a water-based aluminum reflective coating layer printed by screen printing with a matrix distribution wave point pattern, and can increase the reflection of far infrared rays to the human body, so as to improve the absorption efficiency of the human body.

Still equipartition a plurality of temperature sensing probe 2241 on layer 224 generates heat for detect the accurate temperature of layer 224 and the body surface that generates heat, but its accurate perception is surveyed regional temperature variation, temperature sensing probe 2241 links to each other with controller 6 through accuse temperature module, give controller 6 with temperature information transmission, controller 6 opens and close layer 224 that generates heat according to temperature information and generates heat, with the temperature that generates heat of layer 224 that controls, realize blood microcirculation monitoring, other functions such as health status detection, form intelligent temperature sensing system.

The clamping bent position 3 is provided with a first magnetic attraction buckle 4 which is used for connecting a controller 6 to be electrified. The first magnetic catch 4 is not limited to be disposed on the clamping bent part 3, and may be disposed at other positions according to use and design requirements.

As shown in fig. 4 and 9, the parallel device 5 is disposed in the front center 12, and the parallel device 5 is connected to the first magnetic catch 4 through the electric wire 51. The parallel device 5 is also provided with two second connectors 52 which are respectively connected by electric leads, and the second connectors 52 are fixed on the side edge of the lower support bowl 2 and are in the same layer with the electric heating layer 22. The second connector 52 is connected with the first connector 222 in a splicing manner, so that the electric heating layers 22 in the two lower support bowls 2 are connected into a heating circuit in parallel, and then the parallel device 5 uniformly leads out the heating circuit after being connected in parallel through the electric wire 51. The splicing connection of the second connector 52 and the first connector 222 facilitates the realization of the free disassembly and assembly of the electric heating layer 22.

As shown in fig. 10, the controller 6 is arranged outside the underwear, and the controller 6 is provided with a display screen 61, a switch 62 and an adjusting button 63, wherein the display screen 61 is used for displaying the current set temperature and the preset time; the switch 62 is used for connecting or disconnecting the circuit, so as to start and stop the heating work of the electric heating layer 22; the adjusting button 63 can precisely adjust the heating temperature of the electrothermal layer 22. One end of the controller 6 is connected with the second magnetic attraction buckle 64 through a lead 66, and the second magnetic attraction buckle 64 is matched with the first magnetic attraction buckle 4, connected by means of magnetic attraction and electrified for the electric heating layer 22. The other end of the controller 6 is connected with a power connection head 65 through a wire, and the power connection head 65 can be connected with an external low-voltage safe direct-current power supply supporting reverse discharge, such as a mobile phone, a charger and the like according to the model and the form so as to electrify and heat the electric heating layer 22. The controller 6 can be freely connected and folded through the magnetic attraction of the second magnetic attraction buckle 64 and the first magnetic attraction buckle 4, and when the heating is not needed, the controller is folded, so that the embarrassing situation of pulling the clothes can be avoided.

In another embodiment, a rechargeable and easily detachable battery can be arranged in the front middle position 12 or other parts of the underwear as a power supply, and the controller 6 is connected with the battery and is connected into the heating circuit, so that the complexity of an external controller can be avoided. Or in another embodiment, the controller 6 is composed of a wireless control chip and a mobile phone, the battery is connected with the parallel device 5 through the wireless control chip, the wireless control chip is in communication connection with the mobile phone, and the APP on the mobile phone performs operations such as switching on and off, displaying temperature, adjusting temperature and the like on the electric heating layer 22 through the wireless control chip.

As shown in fig. 11, the working flow of the electrothermal layer 22 in the underwear is as follows: the controller 6 starts the electric heating layer 22 through the temperature control module to heat, and controls the heating temperature to be a preset temperature. In this embodiment, 6-8 temperature probes 2241 are uniformly distributed in the electric heating layer 22, after the electric heating layer 22 generates heat, the temperature probes 2241 capture the instant temperature difference of the blood in the human body, the plurality of temperature probes 2241 transmit the collected temperature data to the data chip of the controller 6 in real time, the controller 6 calculates the real-time blood flow rate through a data processing algorithm preset in the data chip, and simultaneously, the temperature is used as the basis on the display 61 or the mobile phone APP, the temperature information of the chest is visually displayed (namely, different temperature areas display different colors) in different colors, and the microcirculation condition of the human body can be visually observed. If the color is displayed, the distribution is uniform, color blocks are not piled up, the image is a normal human body microcirculation image, if the blood circulation is blocked by pathological changes, the blood can not be normally circulated, the temperature of the image can be displayed on the image in the form of the color blocks, and therefore when the obvious color blocks are piled up or disordered on the image, the situation that the blood circulation is blocked by pathological changes at the part of the breast is shown. While heating, the major physiotherapy of acupuncture points on the breasts can promote blood circulation and improve the blood circulation of the breasts by far infrared rays. The above-mentioned manner for observing the blood microcirculation status is not limited to the scheme used in this embodiment, but may also be implemented by means of other data algorithms, intelligent chips, elements, etc.

While the principles of the invention have been described in detail in connection with the preferred embodiments thereof, it will be understood by those skilled in the art that the above-described embodiments are merely illustrative of exemplary implementations of the invention and are not limiting of the scope of the invention. The details in the embodiments do not constitute the limitations of the scope of the present invention, and any obvious changes such as equivalent transformation, simple replacement, etc. based on the technical solution of the present invention all fall within the protection scope of the present invention without departing from the spirit and scope of the present invention.

Claims (10)

1. An intelligent far infrared physiotherapy bra is characterized by comprising two lower support bowls (2) and a controller (6), wherein the lower support bowls (2) are symmetrically distributed, and each lower support bowl (2) comprises an electric heating layer (22);

the electric heating layer (22) comprises a heating layer (224) and an infrared reflecting layer (225); the heating layer (224) is a carbon nanofiber layer, the heating layer (224) emits heat in a far infrared mode, the heating layer (224) is connected with a low-voltage direct-current power supply through the controller (6), and the controller (6) is used for starting and stopping the heating action of the heating layer (224) and adjusting the heating temperature; the infrared reflecting layer (225) is arranged on the outer side of the heating layer (224), and the reflecting surface faces the heating layer (224) and is used for reflecting far infrared rays generated by the heating layer (224) to the direction of a human body.

2. The intelligent far infrared physiotherapy bra of claim 1, wherein the heating layer (224) is shaped to correspond to the lower supporting bowl (2); the electrode strips drawn along the outer edge of the heating layer (224) are not closed and are U-shaped; the U-shaped electrode strips are inwards deflected and contracted by a preset radius in the heating layer (224) and are drawn in a closed manner to form annular electrode strips; the annular electrode strip and the U-shaped electrode strip are connected with positive and negative electrodes through leads, and the leads are led out from one end of the annular electrode strip close to the opening of the U-shaped electrode strip.

3. The intelligent far infrared physiotherapy bra of claim 1, wherein the heating layer (224) is provided with a finger-inserted positive and negative electrode strip, and the finger-inserted positive and negative electrode strip comprises a positive and negative main electrode strip parallel to each other and a plurality of positive and negative electrode strips connected with the side edges of the positive and negative main electrode strip and arranged in parallel in a staggered manner.

4. The intelligent far infrared physiotherapy bra of claim 1, wherein the heating layer (224) is a hollow heating structure, and the inner side and the outer side of the heating layer (224) are respectively connected with a positive electrode strip and a negative electrode strip through leads; the electrodes of the hollow heating structure are designed into a U shape or a square shape.

5. The intelligent far infrared physiotherapy bra of claim 1, wherein a plurality of temperature sensing probes (2241) are further uniformly distributed on the heating layer (224), and the temperature sensing probes (2241) are respectively connected with the controller (6) through a temperature control module.

6. The intelligent far infrared physiotherapy bra of claim 1, wherein the infrared reflection layer (225) is a water-based aluminum system reflection coating layer with a matrix distribution wave point pattern.

7. The intelligent far infrared physiotherapy bra of claim 1, wherein the electric heating layer (22) further comprises a line integration device (221) and a first connector (222); the line integration device (221) is arranged on the electrothermal layer (22), and the line integration device (221) is connected with the first connector (222) through an electric wire; the bra also comprises a parallel device (5); the parallel device (5) comprises an electric wire (51) and two second connectors (52) respectively connected by electric wires;

the electric heating layers (22) in the two lower support bowls (2) are connected with the second connector (52) in a splicing manner through the first connector (222); the parallel device (5) is connected with the controller (6) through the electric wire (51).

8. The intelligent far infrared physiotherapy bra of claim 7, wherein the bra further comprises a first magnetic suction button (4); the controller (6) comprises a display screen (61), a switch (62), an adjusting button (63), a second magnetic suction button (64) and a connecting head (65); the parallel device (5) is connected with the first magnetic attraction buckle (4) through the electric wire (51); the first magnetic attraction buckle (4) is connected with the second magnetic attraction buckle (64) through magnetic attraction; the controller (6) is connected with the power supply through the electric connecting head (65), and the display screen (61) is used for displaying the current set temperature and the preset time; the switch (62) is used for switching on and off the heating work of the electric heating layer (22); the adjusting button (63) is used for accurately adjusting the heating temperature of the electric heating layer (22).

9. The intelligent far infrared physiotherapy bra of claim 7, wherein said power source is a battery, said controller (6) comprises a wireless control chip and a mobile phone, said battery is connected to said parallel device (5) through said wireless control chip, said wireless control chip is in communication connection with said mobile phone to control said electrothermal layer (22).

10. The intelligent far infrared physiotherapy bra of claim 1, wherein the bra further comprises side guides (1), the side guides (1) comprising zippers (11) and a front medial side (12); the middle parts of the two lower supporting bowls (2) are connected through the front middle position (12), the lower parts of the two lower supporting bowls (2) are connected with the side position (1) and the front middle position (12) through the zippers (11), and the electric heating layer (22) can be disassembled and assembled after the lower supporting bowls (2) are unzipped through the zippers (11).

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