WO2017020797A1

WO2017020797A1 - Heating physical therapy device

Info

Publication number: WO2017020797A1
Application number: PCT/CN2016/092454
Authority: WO
Inventors: 阚晓敏; 骆权峰; 陶振华; 徐洪格; 张靖
Original assignee: 深圳市挺美健康科技有限公司
Priority date: 2015-08-05
Filing date: 2016-07-30
Publication date: 2017-02-09
Also published as: CN105055074A; CN105055074B

Abstract

Disclosed is a heating physical therapy device (100), comprising a power circuit, a first drive circuit (30), a central processing unit and a graphene heating layer (2). The power circuit is connected to the first drive circuit (30). The first drive circuit (30) comprises multiple independent output interfaces (31) of positive electrode and negative electrode. The graphene heating layer (2) comprises multiple heating areas (20), wherein each heating area (20) is provided with a positive electrode and a negative electrode (21), and each heating area (20) is electrically connected to the output interface (31) of the positive electrode and the negative electrode of the first drive circuit (30) through the corresponding positive electrode and the negative electrode (21), so that the power circuit is connected to each heating area (20). The central processing unit is connected to the first drive circuit (30) to control the first drive circuit (30) to control the connection and disconnection of the power circuit with the multiple heating areas (20), and therefore the heating areas (20) are controlled to work independently. By means of the method in which the graphene heating layer (2) is divided into the multiple heating areas (20), a user can accurately choose the proper physical therapy temperature for each part according to requirements.

Description

Heating therapy device

The present application claims priority to the priority of the application Serial No. 201510474098.9, filed on Aug. 5, 2015, the disclosure of which is incorporated herein by reference.

Technical field

The invention relates to a physiotherapy device, in particular to a physiotherapy device for local heating of a human body.

Background technique

With the improvement of people's living standards, various physiotherapy and health care equipments have gradually gained attention, and health care equipment with thermotherapy effects has also been developed. The direct result of hyperthermia is to cause the blood vessels of the local tissue to expand, so that the blood flow is strengthened, the blocked capillaries are opened, and the blood perfusion to the human tissue is increased. The efficacy of this type of instrument is directly related to the human body's metabolism under the condition of improved blood circulation, so the degree of improvement of blood circulation directly corresponds to the therapeutic effect.

In the prior art, the belt body for locally heating various types of physiotherapy belts mainly adopts a structure in which an insulating layer (a surface layer directly in contact with a human body) is built in a heating wire heating body, and usually a metal electric heating element (for example, a tungsten wire or a molybdenum sheet, etc.) is used. ) is a basic heating unit. However, since the heat capacity of the metal electric heating element is high, the thermal response is slow, and the metal heating element is easily damaged due to multiple mechanical expansion and contraction and mechanical external forces such as tortuosity, especially bending or winding into a certain angle. It is easier to break, so the application is limited. In addition, the heat generated by the heating element made of metal is radiated outward at a common wavelength, and the electrothermal conversion efficiency is not high, which is disadvantageous for saving energy.

There is also a heating element using carbon fiber in the prior art which is usually coated with a waterproof insulating layer on the outside of the carbon fiber for use as an electrothermal converting element instead of the metal heating wire. Because carbon fiber has better toughness than metal, this solves the disadvantage that the heating wire is not easy to be broken. However, since the carbon fiber is still radiated outward at a normal wavelength, the problem of low electrothermal conversion rate of the wire is not solved. In addition, the strength of the carbon fiber is not large enough, and cracking easily occurs after repeated bending, resulting in insufficient durability of the heating element using the carbon fiber. In addition, the traditional physiotherapy device usually has the same physiotherapy temperature in all areas of the physiotherapy belt. When the actual situation is different in the physiotherapy temperature of different parts of the human body, different physiotherapy temperatures are required, and the user cannot be different according to his own needs. Heating part Choosing different physiotherapy temperatures will seriously affect the user's comfort.

Summary of the invention

It is an object of the present invention to provide a heating therapy device that has uniform heat generation, high comfort, and is capable of freely controlling the temperature of different physiotherapy sites.

In order to achieve the above object, the embodiments of the present invention provide the following technical solutions:

A heating physiotherapy apparatus according to the present invention includes a body and a power supply circuit, and further includes a first driving circuit, a central processing unit, a graphene heat generating layer encapsulated inside the body, the central processing unit and the power supply circuit, The driving circuit is electrically connected, the power circuit is configured to supply power to the driving circuit, the driving circuit includes a plurality of independent positive and negative output interfaces, and the graphene heat generating layer includes a plurality of heating regions, each The heating region is provided with positive and negative electrodes, and the heating region is electrically connected to the positive and negative output interfaces of the driving circuit through the positive and negative electrodes, respectively, and the central processing unit controls the driving circuit, The current of the negative output interface controls the state of the respective heating zones.

Wherein, the body comprises a heat conducting surface and a heat insulating surface, wherein the heat conducting surface is a heat conducting material for direct contact with a human body, and the heat insulating surface is a heat insulating material for preventing heat dissipation.

a vibrator is disposed between the heat conducting surface and the heat insulating surface, and the vibrator is electrically connected to the positive and negative output interfaces of the driving circuit, and the central processing unit passes through the control driving circuit. The current at the negative output interface controls the vibrator to operate.

Wherein, the heating physiotherapy device further comprises a plurality of temperature sensors electrically connected to the central processing unit, each of the heating regions being provided with a temperature sensor for detecting the temperature of the heating region The information is transmitted to the central processing unit for processing, and the central processing unit controls the operation of the drive circuit after processing.

The heating physiotherapy device further includes a control panel electrically connected to the central processing unit, the control panel being disposed outside the body for setting working parameters and states, and setting the work The parameters and status information are communicated to the central processing unit for processing.

The control panel includes a touch display screen for displaying status information of the heating physiotherapy device, and the heating physiotherapy device operating parameters and states can be set through the touch display screen.

Wherein, the control panel comprises an operation button for setting an operating parameter and a state of the heating physiotherapy device, and a display screen for displaying the state of the heating physiotherapy device information.

The power supply circuit includes a power protection circuit for preventing overheating and overloading of the power supply.

The heating physiotherapy device further includes an information transmission module electrically connected to the central processing unit, wherein the heating physiotherapy device forms a two-way communication connection with the background processing unit through the information transmission module, and the background processing unit passes the information. The module transmits control information to the central processing unit.

The heating physiotherapy device further includes a GPS positioning module, the GPS positioning module is configured to collect position information of the heating physiotherapy device, and the collected position information is transmitted to the central processing unit through the information transmission module. Processing, the central processing unit stores the processed information in the central processing unit.

Embodiments of the present invention have the following advantages or benefits:

In the heating physiotherapy device of the present invention, a graphene heat generating layer is disposed in the body of the heating physiotherapy device, and the graphene heat generating layer is divided into a plurality of heating regions, and the plurality of heating regions are independent under the control of the central processing unit. The running method solves the technical problem that the traditional heating physiotherapy device can not select different physiotherapy temperatures according to the user's needs, and the user can perform humanized setting, and the process of using is more comfortable, and the user can control different physiotherapy parts according to his own needs. Temperature, the effect of meeting the needs of different groups of users.

DRAWINGS

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the description of the prior art will be briefly described below. Obviously, the drawings in the following description are only It is a certain embodiment of the present invention, and other drawings can be obtained from those skilled in the art without any creative work.

Figure 1 is an exploded perspective view showing a first embodiment of the heating physiotherapy apparatus of the present invention;

2 is a schematic view showing the connection of the graphene heat generating layer of the present invention and a driving power source;

Figure 3 is a schematic view showing a second embodiment of the heating physiotherapy apparatus of the present invention;

Figure 4 is a schematic illustration of a third embodiment of the heating physiotherapy device of the present invention.

detailed description

The technical solutions in the embodiments of the present invention are clearly and completely described in the following with reference to the accompanying drawings in the embodiments of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, but not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative efforts are within the scope of the present invention.

In the description of the present invention, it should be noted that the term "connecting" should be understood broadly, unless otherwise explicitly defined and defined, for example, it may be a fixed connection, a detachable connection, or an integral connection; The mechanical connection may also be an electrical connection; it may be directly connected, or may be indirectly connected through an intermediate medium, and may be internal communication between the two elements.

Referring to FIG. 1 and FIG. 2 , the heating physiotherapy device 100 of the present invention comprises a body 10 , a graphene heat generating layer 2 encapsulated inside the body 10 , and a power supply circuit encapsulated outside the body 10 (not shown). a first driving circuit 30, a central processing unit (not shown) externally mounted on the body 10, the power circuit is electrically connected to the central processing unit, and the power circuit is used to The first driving circuit provides a power source, and further the power circuit provides energy for the central control unit, the first driving circuit 30 includes a plurality of independent positive and negative output interfaces 31, and the graphene heat generating layer 2 includes A plurality of heating regions 20, each of which is provided with positive and negative electrodes 21, each of which is electrically connected to a pair of positive and negative electrode output interfaces 31 in the first driving circuit 30 through the positive and negative electrodes 21 The first driving circuit 30 is electrically connected to the central processing unit circuit. Central processing order The first driving circuit 30 controls the connection or disconnection of the power supply circuit with the plurality of heating regions 20. The power supply circuit provides energy for heating in the heating zone, and each heating zone 20 operates independently of each other under the control of the central processing unit.

When a heating region 20 needs to be heated, the central processing unit controls the positive and negative electrode output interfaces 31 on the first driving circuit 30 corresponding to the heating region 20 to turn on the power circuit to output current, which is the corresponding heating region 20 heating. When a certain heating zone 20 does not need to be heated, the central processing unit controls the positive and negative electrode output interfaces 31 on the first driving circuit 30 corresponding to the heating zone 20 to be disconnected from the power circuit, thereby stopping. Output current, corresponding heating zone 20 Then stop heating.

The local heating treatment by graphene for the human body has a low demand voltage, the human body is heated uniformly, and the infrared spectrum of graphene is close to the infrared spectrum of the human body, and the radiation to the human body is small, and the positive heat is set on each heating region 20. The positive and negative electrodes 21 of each of the heating regions 20 are electrically connected to the positive and negative output interfaces 31 of the first driving circuit 30. The central processing unit can individually control each of the first driving circuits 30. The positive and negative output interfaces 31 are connected or disconnected from the power supply circuit, thereby controlling whether the heating regions 20 are heated, and only when the positive and negative output interfaces 31 of the first driving circuit 30 are connected to the power supply circuit to output current, The correspondingly connected heating region 20 generates heat, and the remaining heating regions 20 of the positive and negative output interfaces 31 of the first driving circuit 30 that are not connected to the power supply circuit are hardly heated (because the current passing through is small, the amount of heat generated can be Neglected) to achieve the effect of localized heating therapy.

As a further preferred embodiment, the body 10 includes a heat conducting surface 11 and a heat insulating surface 12, and the graphene heating layer is disposed between the heat conducting surface 11 and the heat insulating surface 12, and the heat conducting surface 11 is a heat conductive material. It can be made of cotton or other synthetic fibers, which are suitable for contact with the human body and comfortable. It is used for direct contact with the human body to heat the physiotherapy part. The advantage of using cotton cloth or other synthetic fibers is that the touch is mild, and when it comes into contact with the human body, the skin is comfortable. The degree of heat is high; the heat insulating surface 12 is a heat insulating material for preventing heat dissipation and reducing energy loss. Adiabatic materials such as aerogel felts and glass fibers can be used.

In addition, since the temperature of the heating physiotherapy belt is generally not higher than 80 ° C, the heat resistance of the material of the heat insulating surface 12 may not be high, so as to reduce the production cost, but it should be considered that the physiotherapy process may need to be frequently curled. Therefore, the flexibility of the material of the insulating layer should be relatively good. As a further preferred, the heat insulating surface 12 can employ various heat insulating materials having good flexibility in the prior art.

As a further preferred design, a plurality of vibrators 13 may be disposed between the heat conducting surface 11 and the heat insulating surface 12, and the vibrator 13 and the second driving circuit (not shown, the structure and the first The driving circuit is similar, the positive and negative output interfaces including a plurality of independent positive and negative output interfaces are electrically connected, the power circuit is connected to the second driving circuit, and the central processing unit controls the second driving circuit by The power supply states of the positive and negative output interfaces indirectly control the working state of the vibrator 13 (ie, vibration intensity, vibration time, vibration frequency, etc.). When a heating zone 20 needs to be vibrated The central processing unit controls the positive and negative electrode output interfaces on the second driving circuit corresponding to the heating region 20 to turn on the power circuit to output current, and supply power to the vibrator 13 on the corresponding heating region 20. The vibrator 13 in this area vibrates. When a certain heating area 20 does not require vibration massage, the central processing unit controls the positive and negative electrode output interfaces on the second driving circuit corresponding to the heating area 20 to stop outputting current, and the vibration on the heating area 20 corresponding thereto The device 13 stops vibrating, and the plurality of vibrators 13 are operated independently under the control of the central processing unit.

Obviously, the central processing unit can adjust the vibration intensity of the vibrator 13 by controlling the output current of each of the positive and negative output interfaces on the second driving circuit, and the output current of each of the positive and negative output interfaces on the second driving circuit. The larger the vibration intensity of the vibrator 13 connected thereto, the greater the massage intensity of the region.

Further preferably, the central processing unit can further adjust the output current frequency of each of the positive and negative output interfaces on the second driving circuit (ie, the duration and the off time of the output current, such as power supply for 1 second, power failure 1 Second, so cycle), thereby adjusting the vibration frequency of the vibrator 13 connected to each of the positive and negative output interfaces, the higher the output current frequency of each of the positive and negative output interfaces on the second driving circuit, the corresponding connected vibrator 13 The vibration frequency is also higher. vice versa. The vibration frequency of the vibrator 13 is also the massage frequency of the heating physiotherapy device. By placing the vibrator 13 in the physical therapy part of the body, the meridian can be dredged, and the human body can be massaged and relaxed.

As a further preferred embodiment, the heating therapy device 100 further includes a plurality of temperature sensors 4 electrically connected to the central processing unit, and each of the heating regions 20 is provided with one of the temperature sensors 4, The temperature information for detecting the corresponding heating region 20 is transmitted to the central processing unit for processing, and the central processing unit compares the temperature information with a preset temperature set in the central processing unit to output control information to control the first driving circuit. 30, when the temperature detected by the temperature sensor 4 is less than the preset temperature inside the central processing unit, the first driving circuit 30 is controlled to turn on the output current of the power circuit to heat the corresponding heating region 20, and vice versa, the central processing unit control station The first drive circuit 30 is disconnected from the power supply circuit to stop the output current and stop heating the corresponding heating zone 20 such that the temperature of the heating zone 20 remains constant over a certain range. The internal preset temperature can be set in the central processing unit in advance at the factory.

As a further preferred design, the heating therapy device 100 further includes a control panel 5 for setting the operating parameters of the heating therapy device 100, the control panel 5 being disposed outside the heat insulating surface 12, The central processing unit is also electrically connected to the control panel 5. In operation, the heating physiotherapy device 100 is activated by the control panel 5, and the heating region 20 and the heating temperature to be heated are set, and the set information is transmitted to the central processing unit, and the central processing unit controls the temperature sensor 4 to operate and sense the heating. Heating the temperature of the area 20 and transmitting the perceived temperature data to the central processing unit, the central processing unit comparing the temperature data with the set temperature adjustment temperature to determine whether heating is required, and if heating is required, the central processing unit controls the first The driving circuit 30 turns on the power supply circuit to supply power to the heating region 20 that needs to be heated, thereby heating the corresponding heating region 20, and when the temperature is heated to the set temperature range, the central processing unit controls the first driving circuit 30 to be disconnected from the power source. The connection of the circuits, so that the power supply circuit stops supplying power to the heating zone 20, thereby precisely controlling the heating temperature.

Further, the heating therapy device 100 is activated by the control panel 5, and the heating region 20 requiring vibration massage, the intensity of the vibration, the vibration frequency and the like are set, and the set vibration data is transmitted to the central processing unit, and the central processing is performed. After the unit is processed, the control information is output, and the output current frequency and size of the positive and negative output interfaces on the second driving circuit corresponding to the heating region 20 requiring vibration massage are controlled, and the vibration state of the vibrator 13.

Referring to FIG. 2 and FIG. 3, in a second embodiment of the present invention, the heating physiotherapy device can be made into a close-fitting garment 200, and a graphene heating layer 2 and a vibrator 13 are disposed in the interlayer of the garment 200. The graphene heat generating layer 2 and the vibrator 13 correspond to different acupuncture points of the human body, and the graphene heat generating layer 2 and the vibrator 13 are electrically connected to the first driving circuit 30 and the second driving circuit, respectively, and the control panel 5 is disposed in the clothes. On the outside, the user can set the temperature values of different acupoints on the control panel 5, and the control panel 5 transmits the temperature value information of the different acupoints to the central processing unit (not shown) for processing, and the central control unit controls the The positive and negative output interfaces of the first driving circuit 30 are electrically connected to the power supply circuit to control the corresponding heating region 20 of the laundry for local heating, and the central processing unit controls the temperature sensor 4 to sense the heating region 20 that needs to be heated. Temperature, and the sensing temperature data is transmitted to the central processing unit, and the central processing unit compares the temperature data with the set temperature adjustment temperature to determine whether heating is required If the heating is required, the central processing unit controls the power supply circuit to supply power to the heating region 20 that needs to be heated, thereby heating the corresponding heating region 20, and when the temperature is heated to the set temperature, the central processing unit controls the first driving circuit. 30 is disconnected from the power circuit to stop powering the heating zone 20, thereby accurately controlling the heating temperature of the different acupoints.

On the control panel 5, the working state of the vibrator 13 can also be set at the same time, and the user can Whether the vibrator of each acupuncture point is set to work, and when a certain area needs to be massaged, the central processing unit controls the positive and negative output interfaces of the second driving circuit to be connected to the power supply circuit to supply power to the vibrator 13 The user performs vibration massage; during the massage process, the user can also set the vibration parameters (current magnitude, time and current supply frequency, etc.) through the control panel, after the central processing unit receives the vibration parameters of the control panel, Controlling the current magnitude, time and frequency of each of the positive and negative output interfaces of the second driving circuit, thereby controlling the strength of the massage, the massage time and the frequency of the massage, so that the user can adjust the massage parameters of different acupoints according to their own massage habits. The whole massage effect is better and more humanized.

Referring to FIG. 2 and FIG. 4, in a third embodiment of the present invention, the heating physiotherapy device can be formed into an eye mask 300, wherein the eyewear is provided with a graphene heat generating layer 2 and a vibrator 13, the graphite The olefin heating layer 2 and the vibrator 13 correspond to different acupuncture points of the human body, and the graphene heat generating layer 2 and the vibrator 13 are electrically connected to the first driving circuit 30 and the second driving circuit through wires, respectively, the control panel (not shown) The outside of the eye mask, the user can set the temperature values of different acupoints on the control panel, and the control panel transmits the temperature value information of the different acupoints to the central processing unit (not shown) for processing, and the central control unit controls The positive and negative output interfaces 31 of the first driving circuit 30 are connected to the power supply circuit to locally heat the corresponding heating region 20 of the eye shield, and the central processing unit controls the temperature sensor 4 to sense the heating region 20 that needs heating. Temperature and transmit the perceived temperature data to the central processing unit. The central processing unit compares the temperature data with the set temperature adjustment temperature to determine if it is needed. If the heat is required, the central processing unit controls the first driving circuit 30 to be connected to the power supply circuit to supply power to the heating region 20 requiring heating, thereby heating the corresponding heating region 20, and when the temperature is heated to the set temperature, the central portion The processing unit controls the first driving circuit 30 to be disconnected from the power supply circuit to stop supplying power to the heating region 20, thereby accurately controlling different acupoint heating temperatures.

On the control panel, the working state of the vibrator 13 can also be set at the same time, and the user can set whether the vibrator of each acupoint is working. When a certain area needs to be massaged, the central processing unit controls the second driving. The positive and negative output interfaces of the circuit are connected to the power supply circuit to supply power to the vibrator 13 to perform vibration massage for the user; during the massage process, the user can also set the vibration parameters (current size, time and current supply) through the control panel. Frequency, etc., after the central processing unit receives the parameter of the vibration of the control panel, controlling the positive and negative poles of the second driving circuit The current size, time and frequency of the output interface control the intensity of the massage, the massage time and the frequency of the massage, so that the user can massage according to different reflection areas around the eye, and the heat of the graphene heat layer 2 drives the blood of the eye. Circulating, diminishing dark circles and eye lines, the central processing unit controls the vibrator 13 to vibrate, massages the acupuncture points around the eyes, multi-frequency vibration mode, makes the eyeball and eye muscles evenly rhythmically, accelerates eye microcirculation, and promotes high efficiency Free radical metabolism in the eye, the temperature of the whole eye massage and the frequency of vibration can be adjusted, suitable for various needs of the population.

As a further preferred design, the heating therapy device 100 of the present invention can be made into a personal wearable product, such as a bra, an insole, an underwear, a pant, a hat, a shoulder pad, etc., which are suitable for actual needs, and will not be described herein.

As a further preferred design, the control panel 5 may be a touch display screen for displaying the working state and parameters of the graphene heat generating layer 2 and the vibrator 13 (ie, power supply area, current magnitude, time, and current supply frequency). And the operating parameters of the graphene heat generating layer 2 and the vibrator 13 can be set through the touch display screen. In other embodiments, the control panel 5 may include an operation button and a display screen, the operation button includes a function button and an adjustment button, the function button is used to select a heating and/or vibration area, and when the vibration is selected, You can select the time, frequency and velocity of the vibration and use the adjustment keys to complete the setting. The display screen is used to display the working state and parameters of the graphene heat generating layer 2 and the vibrator 13, that is, the heating area, the heating time, the heating temperature, the massage area, the massage time, the massage intensity, the massage frequency, etc., the control panel 5 is electrically connected to the central processing unit, and the set information can be transmitted to the central processing unit for processing.

As an optional design, the power circuit is connected to an external power source through an AC or DC power interface, and the power supply circuit 100 is powered by an external power source, and the power circuit further includes a power protection circuit. The power protection circuit is used to prevent overheating during the working process of the heating physiotherapy device 100, causing burns to the user; and preventing overloading of the heating physiotherapy device 100 during operation, causing burnout of the heating physiotherapy device 100 and tripping.

As an optional design, the power circuit can use a battery to supply power to the circuit, and the battery can use a high-capacity battery such as a high-capacity lithium battery, a dry battery, or a super capacitor battery, so that the heating therapy device is in use. It is more convenient to operate without wires.

Further, the power circuit can be connected to an external charger unit. For example, an AC or DC power interface can be added to the body 10, and the battery can be connected via the AC or DC power interface. Charging. In other embodiments, the battery in the power circuit can also be charged by employing a wireless charging technique.

The power supply circuit further includes a power supply and a power protection circuit, the power supply being connected to the first driving circuit 30 and the second driving circuit, the power protection circuit for preventing overheating during operation of the heating physiotherapy device 100, The user is burned; it can also prevent excessive charging and discharging during the working process of the heating physiotherapy device 100, resulting in loss of battery life and the like.

The external power supply voltage that is usually used in life is 220V, so it is usually necessary to down-convert the output voltage of the external power supply. That is, when the wired charger is connected to an external power source, the voltage converter can be turned on to down convert the voltage of the wired charger (for example, 110V or 220V) into a voltage suitable for wired charging (for example, 3V or 5V). And transferring the converted voltage to the power supply circuit and the second drive circuit. That is, when the power circuit is connected to the external power source through a wired charger or a USB cable, the power circuit and the driving circuit 30 can use the power of the external power source to charge the battery in the power circuit, and while the charging is being performed, the external power source can also be used. The heating therapy device 100 is powered so that the heating therapy device 100 can continue to operate.

When the heating therapy device 100 needs to follow the user's movement, the connection wire with the external power source can be unplugged, and the internal power source of the high-capacity battery such as a high-capacity lithium battery, a dry battery, a super capacitor battery, etc. carried by the physiotherapy device 100 itself can be heated. Power can be supplied to the entire heated physiotherapy device 100.

Preferably, the internal power source carried by itself is rechargeable, and when the heating therapy device 100 is reconnected to the external power source, the external power source can not only provide energy to the heating therapy device 100, but also charge the internal power source. When the internal power supply is fully charged, under the protection of the battery protection circuit, the internal power supply circuit can be disconnected from the external power supply to stop charging. At the same time, under the protection of the battery protection circuit, when an overcurrent or overheat occurs, the power supply state of the power physiotherapy device 100 is also interrupted to ensure the personal safety of the user.

Preferably, when the external power source is removed from the heating therapy device 100, the user can obtain a prompt on the control panel 5, such as changing changes such as icon flicker and/or light. When the internal power source of the heating therapy device 100 is too low, an icon feature that promptly charges on the control panel 5 can be exemplified.

Further preferably, other operating states of the heating therapy device 100 (eg, overheating, overcurrent, etc.) may also be displayed on the control panel 5 by different icons.

The heating therapy device 100 may further be provided with an information transmission module (not shown), which enables the heating therapy device 100 to exchange information with a background processing unit (such as a mobile phone, a computer, a cloud terminal, etc.) The information transmission module may include sending command information to specify location data and graphic information automatically returned by the mobile phone satellite navigation software (GPS or Big Dipper client software); and including sending command information to specify data and graphics automatically returned by the network software on the mobile phone. Information, the network software includes QQ, WeChat, Weibo, weather calendar software; includes graphic information automatically returning the mobile phone number or short message, displaying the above graphic information; the graphic information is through the control panel 5 It is shown that the above data can be used by the central processing unit to record, calculate, and archive.

The working parameter can also be sent to the APP software in an electronic device such as a computer or a mobile phone by the information transmission module, and the APP software can operate the parameters of the physiotherapy device 100 (such as temperature, heating time, vibration intensity, vibration). Time, vibration frequency, etc.) are modified. The user can transmit the vibration time control information of the vibrator 13 to the heating therapy device 100 through an electronic product such as a computer and/or a mobile phone, and the vibration time control information is received by the information transmission module of the heating therapy device 100. And transmitting to the internal central processing unit, the central processing unit processes the vibration time control information, and outputs control information to control the working time of the vibrator 13, and the user can implement the heating therapy in the background terminal. The modification of the operating parameters of the device 100 makes the whole operation more convenient and fast.

As a further preferred technical solution, the information transmission module may adopt a Wifi chip, a Bluetooth chip, a near field communication (NFC) chip, a wireless communication chip, or the like, or a combination thereof. The information transmission module is electrically connected to the central processing unit, and can transmit information to the central processing unit for data processing, and the heating therapy device forms a two-way communication connection with the terminal device through the information transmission module.

Further preferably, the Wifi chip, the Bluetooth chip, the NFC chip, and the wireless communication chip perform communication according to the Wifi standard, the Bluetooth standard, the NFC standard, and the wireless communication standard, respectively. Among the chips, the NFC chip uses various radio frequency (RE)-ID bandwidths (such as 136 kHz, 13.56 megahertz (MHz), 433 MHz, 860 to 960 MHz, and 2.45 GHz (GHz). Among the chips operating in the 13.56MHz bandwidth NFC method.

Further preferably, when a Wifi chip or a Bluetooth chip is used, various connection information such as a service set identifier (SSID) and a session key may be first transmitted and received by using the received information. Communication, and then can send and receive a variety of information and data.

Further preferably, the wireless communication chip is established according to, for example, the Institute of Electrical and Electronics Engineers (IEEE), ZigBee, Third Generation (3G), Third Generation Partnership Project (3GPP), and Long Term Evolution (LTE). A chip that communicates with various communication standards of a standard to perform communication.

In other embodiments, the heating therapy device 100 may further include a GPS positioning module (not shown) electrically connected to the central processing unit, the GPS positioning module for collecting the heating therapy device Position information of 100, the GPS positioning module transmits the collected location information to the central processing unit for processing, and the central processing unit stores the processed information in the central processing unit and sends the information to the information transmission module. The information transmission module passes the information to the background processing unit.

For example, when the heating therapy device 100 is made into a wearing article (hat, insole, clothing, etc.) for use by an elderly person or a child, the operator can know the position of the old man or the child through the terminal, so as to prevent the elderly or child from being lost. The operator can also adjust the temperature adjustment by observing the location environment of the old man or the child. For example, when the outdoor activities are carried out in winter, the old man or the child will forget to add clothes, or take off his clothes and forget to wear it even at this time, the operator The temperature adjustment can be performed at the distal end to prevent the elderly or children from catching cold, or to vibrate by the remote control vibrator 13, thereby reminding the elderly or children to wear clothes and the like.

Alternatively, the guardian may be prompted when the minor enters a certain specific place (such as an internet cafe, a game hall, etc.), so as to promptly persuade the minor, for example, the guardian can remotely control the vibrator 13 to vibrate to remind the Adults should not enter and so on.

Obviously, the GPS positioning module can use various positioning methods such as GPS/AGPS, Wifi, LBS (base station positioning), Beidou, Bluetooth positioning, or the like, or a combination of centralized technical means, etc. Do not make an exhaustive list.

In other embodiments, the Wifi module can also be used for assisting positioning. When the wearer enters certain specific places, the Wifi module uploads the scanned Wifi hotspot (route) MC to the background through the information transmission module. The processing unit, the background processing unit obtains the latitude and longitude corresponding to the MC that can be obtained after the Wifi positioning database, thereby implementing the auxiliary positioning function when there is no satellite positioning data. When using the Wifi module to locate the recognition alarm of the wearer entering certain places, it is necessary to pre-deploy the Wifi hotspot with the signature code (reroute) in the restricted access place. Device). When the wearer of the heating therapy device 100 enters certain specific places, the background processing unit will issue a banned alarm to the guardian (for example, can be pushed by an app, or notified by a short message, etc.) and display the prohibited place so that the guardian can know in time.

As a further preferred design, the heating therapy device 100 can also have a built-in biosensor for reading information such as body temperature, electrocardiogram, blood sugar, etc., and the central processing unit saves the data periodically and transmits it through the communication module. Give mobile phones, doctor's computers, large databases, etc., to achieve personal health tracking, analysis, management and other functions. Biosensors may include blood glucose sensors, blood pressure sensors, electrocardiographic sensors, myoelectric sensors, body temperature sensors, etc., and the main functions of these sensors include health management, medical monitoring, and entertainment.

In addition, the present invention can also have a technical solution of the heart rate monitoring function such as heart rate and body surface temperature, and establish a personalized reference log curve by collecting the relationship between the heart rate and the body surface temperature and the corresponding values at different times of the day, and the wearer's The real-time heart rate and body surface temperature values are compared to a reference log to identify whether the heating therapy device 100 is worn on the person's limb.

The embodiments described above do not constitute a limitation on the scope of protection of the technical solutions. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the above-described embodiments are intended to be included within the scope of the technical solutions.

Claims

A heating therapy device includes a power circuit, a first driving circuit, a central processing unit, and a graphene heat generating layer, the power circuit connecting the first driving circuit, wherein the first driving circuit includes a plurality of independent positive circuits a negative output interface, the graphene heat generating layer includes a plurality of heating regions, each of the heating regions is provided with positive and negative electrodes, and each heating region is respectively connected to the first driving circuit through respective positive and negative electrodes The positive and negative output interfaces are electrically connected for connecting the power circuit to each heating region, and the central processing unit is connected to the first driving circuit to control the first driving circuit to control the A power circuit is coupled or disconnected from the plurality of heating zones to control the heating zones to operate independently of each other.
The heating therapy device according to claim 1, further comprising a body, said graphene heat generating layer being disposed inside said body, said central processing unit, said power supply circuit and said driving circuit being disposed on said body Outside.
The heating physiotherapy apparatus according to claim 2, wherein said body comprises a heat conducting surface and a heat insulating surface, said heat conducting surface being a heat conductive material for conducting heat, said heat insulating surface being a heat insulating material for preventing heat dissipation.
A heating therapy apparatus according to claim 1, further comprising a second drive circuit and said plurality of vibrators, said power supply circuit being connected to said second drive circuit, said plurality of vibrators and said second drive circuit The positive and negative output interfaces are electrically connected, and the central control unit controls the second driving circuit to control a connection state between the power supply circuit and the plurality of vibrators, thereby controlling the plurality of vibrators to operate independently .
The heating therapy device according to claim 4, further comprising a control panel electrically connected to said central processing unit, said control panel for setting said graphene heat generating layer and said vibrator Operating parameters and states, and transmitting the set operating parameters and status information to the central processing unit for processing, the central processing unit controlling the first driving circuit and the second driving circuit to control the graphene The work of the heat generating layer and the vibrator.
A heating therapy device according to claim 4, wherein said power supply circuit comprises a power source and a power source protection circuit, said power source being connected to said first drive circuit and said second drive circuit, said power source A protection circuit is coupled to the power source to provide overcurrent protection of the power source.
The heating therapy device according to claim 6, further comprising a control panel electrically connected to said central processing unit, said control panel for setting said graphene heat generating layer and said vibrator Operating parameters and states, and transmitting the set operating parameters and status information to the central processing unit for processing, the central processing unit controlling the first driving circuit and the second driving circuit to control the graphene The work of the heat generating layer and the vibrator.
The heating therapy device according to claim 1, further comprising a plurality of temperature sensors electrically connected to said central processing unit, each of said heating regions being provided with said one temperature sensor, The heating zone temperature information is detected and transmitted to the central processing unit for processing, and the central processing unit controls the driving circuit to connect the power circuit with the heating zone to be heated, so that the heating zone to be heated is kept at a constant temperature.
The heating therapy device according to claim 8, further comprising a control panel electrically connected to said central processing unit, said control panel for setting said graphene heat generating layer and said vibrator Operating parameters and states, and transmitting the set operating parameters and status information to the central processing unit for processing, the central processing unit controlling the first driving circuit and the second driving circuit to control the graphene The work of the heat generating layer and the vibrator.
The heating therapy device according to claim 5, wherein said control panel comprises a touch display screen for displaying status information of said graphene heat generating layer and said vibrator, and said touch display screen The working parameters and states of the graphene heat generating layer and the vibrator are set.
A heating physiotherapy apparatus according to claim 5, wherein said control panel includes an operation button and a display screen, and said operation button is for setting an operating parameter and state of said graphene heat generating layer and said vibrator, said A display screen is used to display the operating parameters and states of the graphene heat generating layer and the vibrator.
The heating therapy device according to claim 1, further comprising an information transmission module electrically connected to said central processing unit, said heating therapy device forming a two-way communication with said background processing unit of said remote terminal through said information transmission module And connecting, the background processing unit transmits control information to the central processing unit via the information module to implement control of the heating physiotherapy device by the remote terminal.
The heating therapy device according to claim 12, wherein said heating therapy device further comprises The GPS positioning module is configured to collect location information of the heating therapy device, and the collected location information is stored in the central processing unit and transmitted to the background processing unit through the information transmission module.