TWM635871U - Flexible Infrared Thermal Magnets for Physiotherapy - Google Patents

Abstract

A flexible infrared thermal magnet for physiotherapy, comprising a body and a power supply module connected to the body, the body comprising a physiotherapy infrared unit and a physiotherapy electromagnetic unit stacked with the physiotherapy infrared unit, the physiotherapy electromagnetic unit and the physiotherapy electromagnetic unit The power supply module is electrically connected, and generates a pulse electromagnetic field after receiving the power of the power supply module, and the physiotherapy infrared unit generates at least one far infrared ray synchronously with the pulse electromagnetic field after receiving the power of the power supply module directly or indirectly, The far-infrared rays resonate at the same frequency as the human body's own far-infrared ray band. Through the new model, the pulsed electromagnetic field and the far infrared rays generated by the flexible infrared thermomagnet can be synchronously generated to provide physical therapy effects on the human body. At the same time, the flexible infrared thermomagnet has the characteristics of light and thin structure and low energy consumption, and has the effect of improving physiotherapy Effect.

Description

Flexible Infrared Thermal Magnets for Physiotherapy

The invention relates to a flexible infrared thermomagnet, in particular to a flexible infrared thermomagnet used for physiotherapy.

People often carry out appropriate physical therapy and health care in order to maintain their health. The so-called physical therapy is the abbreviation of physical therapy. According to Wikipedia: "Physical therapy is a method of preventing, treating and dealing with movement and pain problems caused by diseases or injuries. medical specialty, including all non-drug and non-invasive treatments with medical and scientific basis."

At present, there are many physiotherapy instruments for health care on the market, such as those implemented by pulse circuits, or those implemented by massage head movements. For those implementing the pulse circuit, they use the pulses generated by the pulse circuit to impact the acupuncture points of the human body to achieve the effect of health care, while those implementing the massage head massage the human body through the reciprocating movement of the massage head. The working principles of the aforementioned physiotherapy instruments are different, and the physiotherapy effects brought are also different.

In order to meet the growing needs of people, we have developed a smooth physiotherapy mechanism that can simultaneously generate far-infrared rays and low-frequency low-energy pulse electromagnetic fields that resonate with the human body's own far-infrared band at the same time. , and then produce corresponding physical and biological effects on the human body, so as to promote the microcirculation of the tissues in the contact parts of the human body. The structural design features of this new model are light, thin, easy to carry and flexible, and the power supply specification is more low-voltage DC and low power, which meets the demand for low energy consumption.

The main purpose of the present invention is to provide a smooth physiotherapy mechanism for promoting the microcirculation of human tissue.

To achieve the above purpose, the present invention provides a flexible infrared thermal magnet for physical therapy, which includes a body and a power supply module connected to the body. Further, the body includes a physiotherapy infrared unit and a physiotherapy electromagnetic unit stacked with the physiotherapy infrared unit, the physiotherapy electromagnetic unit is electrically connected to the power supply module, and generates a pulse after receiving power from the power supply module Electromagnetic field, the physiotherapy infrared unit receives the power of the power supply module directly or indirectly and generates at least one far infrared ray synchronously with the pulsed electromagnetic field, and the far infrared ray resonates at the same frequency as the human body's own far infrared ray band.

Through the aforementioned technical solution, when the power supply module of the present invention supplies power to the physiotherapy infrared unit and the physiotherapy electromagnetic unit, the pulse electromagnetic field can be generated by the physiotherapy electromagnetic unit to provide magnetic therapy to the human body. At the same time, the far-infrared rays produced by the physiotherapy infrared unit resonate with the far-infrared rays emitted by the human body itself, so as to jointly promote the smooth microcirculation of the contact parts of the human body with the flexible infrared thermomagnet together with the physiotherapy electromagnetic unit.

In one embodiment, the frequency range of the pulsed electromagnetic field is 1 Hz-16 Hz.

Through the foregoing technical solution, the physiotherapy electromagnetic unit of the present invention can generate the pulsed electromagnetic field with a frequency range of 1 Hz-16 Hz, and the pulsed electromagnetic field has the effect of providing magnetic therapy to the human body.

In one embodiment, the strength of the pulsed electromagnetic field is less than or equal to 70 Gauss.

Through the aforementioned technical solutions, the pulsed electromagnetic field generated by the physiotherapy electromagnetic unit of the present invention can specifically produce a magnetic therapy effect on the human body.

In one embodiment, the body includes an infrared reflection unit stacked with the physiotherapy infrared unit and reflecting the far infrared.

Through the foregoing technical scheme, the infrared reflection unit of the present invention can avoid the waste of the far infrared rays, so that the far infrared rays generated by the physiotherapy infrared unit can be irradiated to the position where the human body is in contact with the flexible infrared heating magnet, so as to improve the far infrared rays. Utilization Purposes.

In one embodiment, the material of the infrared reflection unit is food-grade micron aluminum foil.

Through the aforementioned technical solution, the infrared reflection unit of the present invention can provide a good far infrared reflection function.

In one embodiment, the physiotherapy infrared unit has a heating body for generating the far infrared rays, and the physiotherapy electromagnetic unit has an electromagnetic coil for generating the pulsed electromagnetic field and stacked with the heating body.

Through the foregoing technical proposal, the heating element in the new model generates the far-infrared rays that resonate at the same frequency as the far-infrared rays emitted by the human body after receiving the power of the power supply module directly or indirectly, and the electromagnetic coil receives the power of the power supply module. The pulsed electromagnetic field is generated, so that the flexible infrared thermal magnet can provide far-infrared energy and magnetic therapy to the human body at the same time, and achieve the purpose of promoting microcirculation.

In one embodiment, the physiotherapy infrared unit includes a conductor electrically connected to the heating element and the physiotherapy electromagnetic unit, the conductor has a positive circuit electrically connected to the physiotherapy electromagnetic unit, and a conductor electrically connected to the power supply module A set of negative electrode circuits, the positive electrode circuit includes a plurality of positive electrode bypasses arranged on the heating element, and the negative electrode circuit includes a plurality of negative electrode bypasses arranged on the heating element.

Through the above-mentioned technical solution, the present invention enables the electric current to be uniformly input into the heating body at multiple points synchronously through the setting of the positive circuit and the negative circuit, so that the heating body can generate heat evenly, and at the same time, the heating body can emit more uniform and This far infrared ray resonates at the same frequency as the human body's own far infrared ray band.

In one embodiment, the heating element is made of graphite carbon fiber or graphene.

Through the foregoing technical solution, the present invention enables the heating element to specifically provide heat energy to the human body by setting the material of the heating element, so that the human body can obtain the effect of promoting microcirculation after being in contact with the flexible infrared thermomagnet.

In one embodiment, the physiotherapy infrared unit includes a first insulating protective film that is laminated on the heating element by high temperature heat pressing and provides insulation protection for the heating element, and a first insulating protective film that is compounded on the conductor by high temperature heat pressing and providing the conductor A second insulating protective film for insulating protection.

Through the foregoing technical solution, the present invention provides insulation protection for the heating element and the conductor through the arrangement of the first insulation protection film and the second insulation protection film.

In one embodiment, the first insulating protection film is a PET film or a PI film, and the second insulating protection film is a PET film or a PI film.

Through the foregoing technical solution, the present invention enables the first insulation protection film and the second insulation protection film to provide insulation protection through the materials of the first insulation protection film and the second insulation protection film.

In one embodiment, the therapeutic infrared unit includes at least one EVA paint coated on at least one of the first insulation protection film and the second insulation protection film.

Through the foregoing technical solution, the present invention provides the EVA paint on at least one of the first insulating protective film and the second insulating protective film, through which the EVA paint will produce stickiness under high temperature and pressure, so as to bond the The first insulating protective film and the second insulating protective film are used to achieve the purpose of tightly pressing the conductor and the heating element.

In one embodiment, the physiotherapy electromagnetic unit includes a first insulator disposed on the electromagnetic coil, and a second insulator disposed on a side of the electromagnetic coil away from the first insulator.

Through the foregoing technical solutions, the present invention provides insulation protection for the electromagnetic coil through the arrangement of the first insulator and the second insulator.

In one embodiment, the power supply module includes a circuit control unit that is electrically connected to the physiotherapy electromagnetic unit and decides to work based on the operating state. The power supply voltage of the power supply module is DC 5V-24V, and the circuit control unit outputs when activated. A DC square wave with a voltage range of 5V-24V.

Through the aforementioned technical solution, the output voltage range of the circuit control unit of the present invention is a DC square wave in the range of 5V-24V, so as to facilitate the control of the heating temperature of the physiotherapy infrared unit and the pulse electromagnetic field intensity generated by the physiotherapy electromagnetic unit .

In one embodiment, the physiotherapy electromagnetic unit includes at least one thermistor located on the side of the heating element away from the infrared reflection unit, and the thermistor is arranged on the first insulator and electrically connected to the power supply module.

Through the foregoing technical solutions, the thermistor of the present invention can produce temperature changes based on the temperature of the heating element, thereby controlling the circuit between the power supply module and the electromagnetic coil.

In one embodiment, the circuit control unit has a temperature control component electrically connected to the thermistor and used for conducting the physiotherapy electromagnetic unit and the electromagnetic coil.

Through the aforementioned technical solution, the temperature control component of the present invention can be used in conjunction with the thermistor. When the temperature of the flexible infrared thermomagnet increases, the resistance value of the thermistor will also change. When the thermistor When the resistance value of the resistance changes to the preset resistance value, by triggering the temperature control component, an open circuit occurs between the temperature control component and the electromagnetic coil, thereby suspending the power supply of the power supply module to the physiotherapy infrared unit, so that the The temperature of the physiotherapy infrared unit is gradually reduced to avoid damage to the flexible infrared thermomagnet itself and the parts of the human body in contact with the flexible infrared thermomagnet.

In one embodiment, the flexible infrared thermomagnet includes at least one waterproof membrane connected to the body.

Through the foregoing technical solution, the waterproof membrane of the present invention can prevent water vapor from entering the flexible infrared thermomagnet by mistake, and at the same time avoid damaging the flexible infrared thermomagnet.

In one embodiment, the flexible infrared thermomagnet includes at least one medical breathable non-woven fabric wrapped on the waterproof membrane.

Through the aforementioned technical solution, when the flexible infrared thermomagnet of the present invention is in contact with the human body, the flexible infrared thermomagnet can provide good skin affinity and air permeability.

In one embodiment, the flexible infrared thermal magnet includes a medical polyurethane gel dressing connected to the side of the medical breathable non-woven fabric close to the human body.

Through the aforementioned technical solution, the medical polyurethane gel dressing of the present invention has good biocompatibility, so that the part of the human body that is in contact with the flexible infrared thermomagnet can be stably contacted with the flexible infrared thermomagnet.

Compared with the conventional ones, the present invention has the following characteristics: when the power supply module of the present invention supplies power to the physiotherapy infrared unit and the physiotherapy electromagnetic unit, the physiotherapy electromagnetic unit generates the pulsed electromagnetic field to perform magnetic therapy on the human body. At the same time, the physiotherapy infrared unit generates the far infrared rays to promote the microcirculation of the human body in contact with the flexible infrared thermomagnet.

The detailed description and technical content of this new model are described as follows in conjunction with the drawings:

Please refer to Fig. 1 to Fig. 4, the present invention provides a kind of flexible infrared thermomagnet 100 that is used for physiotherapy, comprises a body 10 and a power supply module 20, and this power supply module 20 is connected with this body 10, and this body 10 provides Power required for implementation. The body 10 includes a physiotherapy electromagnetic unit 11 and a physiotherapy infrared unit 12, the physiotherapy electromagnetic unit 11 is electrically connected to the power supply module 20, and the physiotherapy electromagnetic unit 11 receives the power from the power supply module 20 to generate a Pulse electromagnetic field, the electromagnetic field generated by the pulse electromagnetic field is a low-frequency pulse, which has the effect of magnetic therapy on the human body. It should be noted that, in order to ensure the effect of magnetic therapy, the frequency range of the pulsed electromagnetic field is 1 Hz-16 Hz, and the magnetic field strength of the pulsed electromagnetic field is less than or equal to 70 Gauss. At the same time, the physiotherapy infrared unit 12 receives the power of the power supply module 20 directly or indirectly to generate at least one far-infrared ray, which is generated synchronously with the pulsed electromagnetic field, and the far-infrared ray resonates at the same frequency as the human body's own far-infrared ray band , so as to promote blood circulation in the part of the human body irradiated by the far-infrared rays, and even activate the cell molecules in the subcutaneous deep tissue of the irradiated part due to the same frequency resonance and energy transmission, accelerate the synthesis of biological enzymes needed by the human body, and activate at the same time Biomolecules such as proteins can enhance the body's immunity and the tissue regeneration ability of biological cells, which is convenient for improving the effect of physical therapy. The flexible infrared thermal magnet 100 of the present invention integrates the physiotherapy effect brought by the pulsed electromagnetic field and the far infrared rays on the human body, and promotes the smooth flow of the microcirculation of human tissue.

1 to 3, the power supply module 20 includes a power supply unit 21 for outputting 5V-24V direct current. In one embodiment, the power supply unit 21 can be a mobile power supply that provides 5V direct current. It can also be an AC/DC power converter. Further, the power supply module 20 includes a circuit control unit 22 electrically connected to the power supply unit 21, the circuit control unit 22 is electrically connected to the physiotherapy electromagnetic unit 11 of the main body 10, and can be determined based on the operating state Work, for example, the work of the circuit control unit 22 may be to determine whether the circuit between the power supply unit 21 and the main body 10 is conducted, or to control the heating temperature of the main body 10 . In another embodiment, the circuit control unit 22 further includes a pulse signal output component 221 electrically connected to the power supply unit 21, the pulse signal output component 221 is driven to generate a DC square wave, and the frequency of the DC square wave is 1Hz-16Hz, the voltage range is 5V-24V.

As above, the physiotherapy electromagnetic unit 11 includes at least one electromagnetic coil 111, the electromagnetic coil 111 is electrically connected to the pulse signal output component 221, and the electromagnetic coil 111 receives the DC square wave output by the pulse signal output component 221 to generate This pulsed electromagnetic field is of low frequency. Moreover, the electromagnetic coil 111 is multi-layered, and the electromagnetic coil 111 has two shapes, one of which is in a rectangular spiral shape, and the other is in a circular spiral shape. It should be understood that the aforementioned state of the electromagnetic coil 111 is only an example. Note that in practice, the electromagnetic coil 111 can be designed according to specific requirements. Further, the physiotherapy electromagnetic unit 11 further has a first insulator 112 disposed on one side of the electromagnetic coil 111, and a second insulator 113 disposed on the other side of the electromagnetic coil 111 and opposite to the first insulator 112 , the first insulator 112 and the second insulator 113 may be arranged in a layered structure, the first insulator 112 and the second insulator 113 cover both sides of the electromagnetic coil 111, the first insulator 112 and the second insulator 113 are respectively a flexible circuit insulating base material with an insulating function, and the electromagnetic coil 111 is insulated and protected through the insulating function of the flexible circuit insulating base material.

As mentioned above, the physiotherapy infrared unit 12 includes a heating element 121, which is stacked with the electromagnetic coil 111, and the heating element 121 is a generator of the far infrared rays. In one embodiment, the material of the heating element 121 is a graphite carbon fiber or a graphene, and the heating element 121 is implemented in a layered structure. The graphite carbon fiber and the graphene can generate the far infrared rays after being energized and heated. The new type resonates at the same frequency as the far-infrared ray emitted by the human body itself, so as to promote the blood circulation of the human body irradiated by the far-infrared ray, and make the subcutaneous deep tissue of the irradiated part resonate at the same frequency and transmit energy. Activation, accelerates the synthesis of biological enzymes needed by the human body, and at the same time activates biological molecules such as proteins, thereby enhancing the body's immunity and the tissue regeneration ability of biological cells, so as to improve the effect of physical therapy.

Further, the physiotherapy infrared unit 12 further includes a conductor 122 electrically connected to the heating element 121, the conductor 122 is electrically connected to the electromagnetic coil 111, and the conductor 122 is located on the first insulator 112 away from the electromagnetic coil. 111 side. 1 to 3, the conductor 122 includes a positive loop 123 and a negative loop 124, the positive loop 123 is electrically connected to the electromagnetic coil 111, the negative loop 124 is electrically connected to the power supply module 20, the The positive circuit 123 includes a positive main circuit 125 and a plurality of positive bypasses 126 arranged on the positive main circuit 125. The positive bypasses 126 extend into the heating element 121 and are evenly arranged on it. The negative circuit 124 includes an electrical The negative pole main circuit 127 connected to the pulse signal output component 221 and a plurality of negative pole bypasses 128 arranged on the negative pole main circuit 127, the negative pole bypasses 128 extend into the heating element 121 and are uniformly arranged on it. In one embodiment, the material of the conductor 122 is a copper foil or a silver paste, and the positive electrode bypass 126 and the negative electrode bypass 128 are evenly distributed on the heating element 121, so that The electric current evenly flows through the heating element 121, so that the heating element 121 is energized and evenly generates heat.

Please refer to FIG. 1 and FIG. 2, the physiotherapy infrared unit 12 includes a first insulating protective film 129 located on the heating element 121, and a second insulating protective film 130 located on the conductor 122. The first insulating protective film The film 129 is attached to the outer wall of the heating element 121 away from the conductor 122 and its edge protrudes from the heating element 121 , and the second insulating protective film 130 is attached to the outer wall of the conductor 122 away from the heating element 121 And the edge protrudes from the heating element 121 . In one embodiment, the first insulating protective film 129 is a PET film or a PI film, and the second insulating protective film 130 is a PET film or a PI film. The material of the second insulation protection film 130 enables the first insulation protection film 129 and the second insulation protection film 130 to specifically provide insulation protection.

Based on the above, the present invention is to make the edges of the first insulating protective film 129 and the second insulating protective film 130 stick together so that the conductor 122 and the heating element 121 can be pressed together. The physiotherapy infrared unit 12 includes at least one EVA coating 131, and the EVA coating 131 has the characteristics of producing viscosity under high temperature and hot pressing. The second insulating protection film 130 may even be coated on the first insulating protection film 129 and the second insulating protection film 130 at the same time. In this embodiment, the EVA paint 131 is only coated on the side of the second insulating protective film 130 facing the conductor 122. During implementation, the second insulating protective film 130 is stick to the conductor 122, and at the same time make the edge portions of the first insulating protective film 129 and the second insulating protective film 130 stick together so that the conductor 122 and the heating element 121 are tightly pressed together. Purpose.

Again, after the heating element 121 is energized and heated, it mainly sends out the far-infrared rays through the side where the heating element 121 is connected to the first insulating protective film 129. The first insulating protective film 129 makes the far-infrared rays emitted by the heating element 121 connected to the first insulating protective film 129 directly irradiate the human body, but the heating element 121 is far away from the first insulating protective film. The far-infrared rays projected by one side of the 129 cannot irradiate the human body, which will cause waste of the far-infrared rays. Bearing this in mind, in order to avoid the waste of the far infrared rays, the body 10 of the present invention is provided with an infrared reflection unit 14 for reflecting the far infrared rays, the infrared reflection unit 14 is stacked with the physiotherapy infrared unit 12, and faces the second The insulator 113 is provided. In one embodiment, in order to improve the effect of reflecting the far-infrared rays, the material used for the infrared reflection unit 14 is a food-grade micron aluminum foil, which has a good far-infrared reflection effect, so that the heating element 121 is far away from the first The far-infrared rays projected from one side of an insulating protective film 129 are reflected by the infrared reflecting unit 14 and further irradiated to the part of the human body close to the first insulating protective film 129 , thereby improving the utilization rate of the far-infrared rays.

On the other hand, please refer to FIG. 1 to FIG. 4, the physiotherapy electromagnetic unit 11 includes at least one thermistor 114, and the thermistor 114 is used as the temperature sensor of the flexible infrared thermomagnet 100, and the thermistor 114 is based on the physiotherapy The temperature of the infrared unit 12 changes. In one embodiment, when the thermistor 114 is arranged on the first insulator 112 and is located on the side of the heating element 121 facing the human body, the thermistor 114 senses the far-infrared rays generated by the heating element 121 , and the heat energy reflected by the infrared reflection unit 14, so that the thermistor 114 of the present invention can specifically sense the temperature of the side of the flexible infrared thermomagnet 100 facing the human body. When the resistance value of the thermistor 114 is too high, the thermistor 114 blocks the circuit between the power supply module 20 and the electromagnetic coil 111, thereby avoiding heat damage to the user and avoiding damage to the flexible Infrared Thermomagnet 100.

In another embodiment, the thermistor 114 can also be located on the side of the physiotherapy electromagnetic unit 11 facing the second insulating protective film 130. The thermistor 114 of this embodiment also has the ability to sense the heating element 121 and the Due to the ability of the infrared reflection unit 14 to reflect heat energy, the thermistor 114 can effectively avoid thermal damage inside the flexible infrared thermomagnet 100 while sensing the temperature of the flexible infrared thermomagnet 100 . Further, the circuit control unit 22 has a temperature control component 222, the temperature control component 222 is electrically connected to the pulse signal output component 221 and the current input end of the electromagnetic coil 111, and is used to conduct the circuit control unit 22 and the electromagnetic coil 111. Between the coils 111 , that is, the temperature control component 222 has the function of determining whether the circuit between the circuit control unit 22 and the electromagnetic coil 111 is on or off. Moreover, in one embodiment, the thermistor 114 is electrically connected to the temperature control component 222 and disposed between the first insulator 112 and the second insulator 113 . As mentioned above, the heating element 121 will generate heat to generate the far-infrared rays when it is energized, but as the heating element 121 is energized, the heat generated by the heating element 121 will increase. Once too much heat will inevitably bring high temperature, and the resulting high temperature is likely to cause damage to the flexible infrared thermomagnet 100 and the parts where the human body contacts the flexible infrared thermomagnet 100 . Once the temperature of the flexible infrared thermomagnet 100 rises, the resistance of the thermistor 114 will also change, and when the resistance of the thermistor 114 reaches a safe preset value, the temperature control component 222 will be triggered, An open circuit is generated between the circuit control unit 22 and the electromagnetic coil 111 , thereby suspending the power supply of the power supply unit 21 to the heating element 121 . In this way, the temperature of the heating element 121 can be gradually lowered, thereby effectively avoiding damage to the flexible infrared thermomagnet 100 and the parts where the human body contacts the flexible infrared thermomagnet 100 .

On the other hand, the flexible infrared thermomagnet 100 of the present invention includes at least one waterproof membrane 30 connected to the body 10 , and the waterproof membrane 30 is used to prevent moisture from entering the flexible infrared thermomagnet 100 . On the other hand, the flexible infrared thermomagnet 100 further includes at least one medical breathable non-woven fabric 40 wrapped on the waterproof membrane 30, and the medical breathable nonwoven fabric 40 can be used when the flexible infrared thermomagnet 100 contacts the human body. Increase the air permeability and skin-friendly property of the flexible infrared thermomagnet 100 when in contact with human skin. In another embodiment, the flexible infrared thermal magnet 100 includes a medical polyurethane gel dressing 50 connected to the medical breathable non-woven fabric 40, and the medical polyurethane gel dressing 50 is positioned on the medical breathable non-woven fabric. 40 away from the side of the waterproof membrane 30, and located on the side of the flexible infrared thermomagnet 100 close to the human body. The gel dressing 50 has good biocompatibility, which can effectively reduce the adverse reaction of the human body in contact with the flexible infrared thermomagnet 100 , so that the flexible infrared thermomagnet 100 can provide a good user experience.

As can be seen from the above, the implementation principle of the flexible infrared thermomagnet 100 of the present invention is: when using the flexible infrared thermomagnet 100, start the power supply module 20 and drive the power supply unit 21 to work, and after the power supply unit 21 is started, by The circuit control unit 22 outputs the DC square wave with a frequency range of 1 Hz-16 Hz. Afterwards, the side of the flexible infrared thermal magnet 100 close to the physiotherapy infrared unit 12 contacts the skin of the human body, and the physiotherapy electromagnetic unit 11 receives the power of the power supply module 20 to generate the low-frequency pulsed electromagnetic field, and the human body approaches or touches the flexible infrared thermomagnet. The site of the thermal magnet 100 is subjected to magnetic therapy. At the same time, the physiotherapy infrared unit 12 receives the power of the power supply module 20 directly or indirectly to generate the far infrared rays, which resonate with the human body's own far infrared band at the same frequency, so as to achieve the purpose of physical therapy for the human body. In addition, the body 10 of the present invention is provided with the infrared reflection unit 14, the infrared reflection unit 14 can reflect the far-infrared rays from the heating element 121, thereby avoiding the waste of the far-infrared rays and effectively maintaining the body 10 Effect of temperature on startup. On the other hand, the flexible infrared thermomagnet 100 of the present invention has a temperature control function. Once the temperature of the physiotherapy infrared unit 12 is too high, the present invention will make the thermal resistance 114 and the circuit control unit 22 function to make the The temperature of the heating element 121 is lowered to avoid thermal damage to the human body and reduce damage to the flexible infrared thermomagnet 100 .

In summary, it is only a preferred embodiment of the present invention, and should not limit the scope of implementation of the present invention, that is, all equal changes and modifications made according to the patent scope of the present application should still belong to the present invention. patent coverage.

100: Flexible infrared thermal magnet 10: Ontology 11: Physiotherapy electromagnetic unit 111: electromagnetic coil 112: first insulator 113: Second insulator 114: Thermistor 12: Physiotherapy infrared unit 121: heating element 122: Conductor 123: positive circuit 124: negative circuit 125: positive main road 126: positive bypass 127: Negative pole main road 128: Negative bypass 129: the first insulating protective film 130: the second insulating protective film 131: EVA paint 14: Infrared reflection unit 20: Power supply module 21: Power supply unit 22: Circuit control unit 221: Pulse signal output component 222: Temperature control components 30: waterproof membrane 40:Medical breathable non-woven fabric 50: medical polyurethane gel dressing

Fig. 1 is a schematic diagram of the structure of a flexible infrared thermomagnet according to an embodiment of the present invention (1). Fig. 2 is a structural schematic diagram of a flexible infrared thermomagnet according to an embodiment of the present invention (2). Fig. 3 is a schematic diagram of the connection between the heating element and the conductor in an embodiment of the present invention. Fig. 4 is a schematic diagram of the structure of a flexible infrared thermomagnet according to an embodiment of the present invention (3).

100: Flexible infrared thermal magnet

10: Ontology

11: Physiotherapy electromagnetic unit

12: Physiotherapy infrared unit

14: Infrared reflection unit

20: Power supply module

21: Power supply unit

22: Circuit control unit

221: Pulse signal output component

222: Temperature control components

30: waterproof membrane

40:Medical breathable non-woven fabric

Claims (18)

A flexible infrared thermomagnet for physical therapy, comprising a body and a power supply module connected to the body, the flexible infrared thermomagnet is characterized in that: The body includes a physiotherapy infrared unit and a physiotherapy electromagnetic unit stacked with the physiotherapy infrared unit. The physiotherapy electromagnetic unit is electrically connected to the power supply module and generates a pulsed electromagnetic field after receiving power from the power supply module. The physiotherapy infrared ray unit generates at least one far-infrared ray resonating at the same frequency as the human body's own far-infrared ray band after receiving the power of the power supply module directly or indirectly. The flexible infrared thermomagnet for physiotherapy according to Claim 1, wherein the frequency range of the pulsed electromagnetic field is 1 Hz-16 Hz. The flexible infrared thermomagnet for physiotherapy according to Claim 2, wherein the pulsed electromagnetic field strength is less than or equal to 70 Gauss. The flexible infrared thermomagnet for physiotherapy according to any one of Claims 1 to 3, wherein the body includes an infrared reflection unit stacked with the physiotherapy infrared unit and reflecting the far infrared rays. The flexible infrared thermal magnet for physiotherapy according to claim 4, wherein the material of the infrared reflection unit is food-grade micron aluminum foil. The flexible infrared thermal magnet for physiotherapy as described in claim 4, wherein, the physiotherapy infrared unit has a heating body for generating the far infrared rays, and the physiotherapy electromagnetic unit has a body for generating the pulsed electromagnetic field and interacting with the heating Electromagnetic coils stacked in layers. The flexible infrared thermal magnet for physiotherapy as described in claim 6, wherein, the physiotherapy infrared unit has a conductor electrically connected to the heating element and the physiotherapy electromagnetic unit, and the conductor has a conductor electrically connected to the physiotherapy electromagnetic unit. A positive circuit of the unit, and a negative circuit electrically connected to the power supply module, the positive circuit includes a plurality of positive bypasses arranged on the heating element, and the negative circuit includes a plurality of negative bypasses arranged on the heating element. The flexible infrared thermomagnet for physiotherapy according to Claim 7, wherein the heating element is made of graphite carbon fiber or graphene. The flexible infrared thermal magnet for physiotherapy as described in Claim 7, wherein, the physiotherapy infrared unit comprises a high-temperature thermocompression compounded on the heating element and provides the insulation protection of the heating element for the first insulating protective film, and a high-temperature A second insulating protective film that is laminated on the conductor and provides insulation protection for the conductor by thermal compression. The flexible infrared thermomagnet for physiotherapy according to Claim 9, wherein the first insulating protective film is a PET film or a PI film, and the second insulating protective film is a PET film or a PI film. The flexible infrared thermomagnet for physiotherapy as claimed in claim 9, wherein the physiotherapy infrared unit comprises at least one EVA paint coated on at least one of the first insulation protection film and the second insulation protection film. The flexible infrared thermal magnet for physiotherapy as described in claim 11, wherein the physiotherapy electromagnetic unit comprises a first insulator disposed on the electromagnetic coil, and a first insulator disposed on the side of the electromagnetic coil away from the first insulator Two insulators. The flexible infrared thermal magnet for physiotherapy as described in claim 12, wherein the power supply module includes a circuit control unit electrically connected to the physiotherapy electromagnetic unit and determined to work based on the operating state, and the power supply voltage of the power supply module The direct current is 5V-24V, and the circuit control unit outputs a direct-current square wave with a voltage range of 5V-24V after starting. The flexible infrared thermal magnet for physiotherapy as described in claim 13, wherein the physiotherapy electromagnetic unit includes at least one thermistor located on the side of the heating element away from the infrared reflection unit, and the thermistor is arranged on the first The insulator is electrically connected to the power supply module. The flexible infrared thermomagnet for physiotherapy as claimed in claim 14, wherein the circuit control unit has a temperature control component electrically connected to the thermistor and used to conduct the physiotherapy electromagnetic unit and the electromagnetic coil. The flexible infrared thermomagnet for physiotherapy according to claim 15, wherein the flexible infrared thermomagnet comprises at least one waterproof membrane connected to the body. The flexible infrared thermomagnet for physiotherapy according to claim 16, wherein the flexible infrared thermomagnet comprises at least one medical breathable non-woven fabric wrapped on the waterproof membrane. The flexible infrared thermomagnet for physiotherapy as described in claim 17, wherein the flexible infrared thermomagnet includes a medical polyurethane gel dressing connected to the side of the medical breathable non-woven fabric close to the human body.

Images