CN219398730U - But radio control's photoelectric thermal physiotherapy equipment - Google Patents

Abstract

The utility model discloses a wireless-controllable photoelectric thermal physiotherapy instrument. The physiotherapy equipment comprises: the device comprises an electrotherapy module, a phototherapy module and a micro-control communication module; the electrotherapy module comprises an electrotherapy circuit, an electrode and an electric shock layer, wherein the electrotherapy circuit comprises a first control end and a pulse output end, the electrode is electrically connected with the pulse output end, and the electric shock layer is arranged on one side of the electrode far away from the pulse output end; the phototherapy module comprises a switch circuit and a light-emitting unit, the switch circuit comprises a second control end, and the switch circuit is connected with the light-emitting unit; the micro-control communication module comprises a wireless communication antenna and a processing unit, and the processing unit is respectively connected with the first control end, the second control end and the wireless communication antenna. The utility model discloses a portable degree of physiotherapy effect and instrument can be improved to this application scheme.

Description

But radio control's photoelectric thermal physiotherapy equipment

Technical Field

The embodiment of the utility model relates to a machine manufacturing technology, in particular to a wireless-controllable photoelectric thermal physiotherapy instrument.

Background

Dysmenorrhea afflicts most women, and with the development of science and technology, more and more people begin to relieve the affliction caused by dysmenorrhea in different ways. The symptoms can be relieved by drinking red sugar water or taking medicines, but the improper implementation of the modes brings certain negative effects, so that more women tend to be safer relieving modes, namely physiotherapy.

Regarding physiotherapy, the following methods are generally adopted at present for relieving dysmenorrhea symptoms: the acupoint therapy is to massage or moxibustion the appointed acupoint; the heat therapy is to compress the abdomen; the phototherapy method comprises irradiating abdomen with red light or infrared light; the low frequency electrotherapy method is to stimulate nerves by micro-current.

However, the existing dysmenorrhea physiotherapy products have the problems of troublesome carrying and use and poor effect, and cannot meet the requirements of consumers for carrying with them.

Disclosure of Invention

The utility model provides a photoelectric thermal physiotherapy instrument capable of being controlled wirelessly so as to improve physiotherapy effect and portability of the instrument.

The embodiment of the utility model provides a wireless-controllable photoelectric thermal physiotherapy instrument, which comprises: the device comprises an electrotherapy module, a phototherapy module and a micro-control communication module;

the electrotherapy module comprises an electrotherapy circuit, an electrode and an electric shock layer, wherein the electrotherapy circuit comprises a first control end and a pulse output end, the electrode is electrically connected with the pulse output end, the electric shock layer is arranged on one side of the electrode far away from the pulse output end, and the electrotherapy circuit is used for outputting pulse current to the electrode from the pulse output end according to a first control signal received by the first control end;

The phototherapy module comprises a switch circuit and a light-emitting unit, the switch circuit comprises a second control end, the switch circuit is connected with the light-emitting unit, and the switch circuit is used for controlling the working state of the light-emitting unit according to a second control signal received by the second control end;

the micro-control communication module comprises a wireless communication antenna and a processing unit, wherein the processing unit is respectively connected with the first control end, the second control end and the wireless communication antenna, and the processing unit is used for generating the first control signal and/or the second control signal according to wireless control signals received by the wireless communication antenna.

Optionally, the wireless-controllable photo-thermal physiotherapy instrument further comprises: the temperature control heating module comprises a temperature control unit and a temperature measurement unit, the temperature control unit comprises a third control end and a heating element, the third control end is connected with the micro control communication module, and the temperature control unit is used for controlling the temperature of the heating element according to a third control signal received by the third control end;

the temperature measuring unit is closely attached to the heating element and is connected with the processing unit and used for collecting the real-time temperature of the heating element and sending the real-time temperature to the processing unit;

The processing unit is further connected with the third control end and is further used for generating a third control signal according to the wireless control signal received by the wireless communication antenna and the real-time temperature.

Optionally, the temperature control unit includes a fifth switch tube, a twenty-ninth resistor and a thirty-eighth resistor, the third control end is connected with the control end of the fifth switch tube through the thirty-seventh resistor, the control end of the fifth switch tube is grounded through the twenty-ninth resistor, the first end of the fifth switch tube is connected with the heating element, and the second end of the fifth switch tube is grounded.

Optionally, the wireless-controllable photo-thermal physiotherapy instrument further comprises: the power supply module comprises a charging circuit and a rechargeable battery, and the charging circuit is connected with the rechargeable battery; the charging circuit comprises a charging interface, wherein the charging interface is used for being connected with a charging power supply to charge the rechargeable battery; the charging circuit is also connected with the processing unit and used for collecting state parameters of the rechargeable battery and sending the state parameters to the processing unit.

Optionally, the charging circuit further includes a charging management chip, a charging protection chip, a charging detection port, a power supply detection port, a battery voltage acquisition port, a first diode, a fifteenth switching tube, a second switching tube, a third switching tube, a first resistor, a third resistor, a sixth resistor, an eleventh resistor, a twelfth resistor, and a power supply end;

The sixth end of the charging interface is connected with the fourth end of the charging management chip, the sixth end of the charging interface is also connected with the power supply end through the first diode, the seventh end of the charging management chip is connected with the power supply end through the first resistor, the seventh end of the charging management chip is also connected with the micro-control communication module through the charging detection port, the fifth end of the charging management chip is connected with the power supply end through the fifteen switching tubes and the second switching tubes which are connected in series, and the fifth end of the charging management chip is also connected with the micro-control communication module through the sixth resistor and the battery voltage acquisition port in sequence; the second end of the charging protection chip is connected with the negative electrode of the rechargeable battery through the third switch tube, the third end of the charging protection chip is connected with the positive electrode of the rechargeable battery through the third resistor, the control end of the third switch tube is connected with the fifth end of the charging management chip and the positive electrode of the rechargeable battery respectively, the fourth end and the fifth end of the charging protection chip are connected in series and then grounded, the control end of the fifteenth switch tube and the control end of the second switch tube are connected in series and then connected with the micro-control communication module through a power supply detection port, the power supply detection port is connected with the fourth end of the charging management chip through the twelfth resistor, and the power supply detection port is grounded through the eleventh resistor.

Optionally, the electrotherapy circuit includes a boost unit, a pulse current detection port, a pulse voltage detection port, a pulse width adjustment port, a boost control port, a first pulse signal control terminal, a second pulse signal control terminal, a sixth switching tube, a seventh switching tube, an eighth switching tube, a tenth switching tube, an eleventh switching tube, a twelfth switching tube, a fifth resistor, an eighth resistor, a seventeenth resistor, an eighteenth resistor, a thirty-ninth resistor, and a twenty-second resistor;

the boosting unit is respectively connected with the power supply end, the pulse width adjusting port, the boosting control port and the pulse voltage detecting port, and is also respectively connected with a first pin and a second pin of the pulse output end through the sixth switching tube; the first pulse signal control end is connected with the control end of the seventh switching tube through the fifth resistor, and the second end of the seventh switching tube is connected with the control end of the sixth switching tube through the eighth resistor; the second pulse signal control end is connected with the control end of the tenth switching tube through the seventeenth resistor, the second end of the tenth switching tube is connected with the control end of the eighth switching tube through the eighteenth resistor, the first end of the eighth switching tube is connected with the first end of the sixth switching tube, and the second end of the eighth switching tube is respectively connected with the third pin and the fourth pin of the pulse output end; the pulse current detection port is respectively connected with the second end of the twelfth switching tube and the second end of the eleventh switching tube through a thirty-ninth resistor, the first end of the twelfth switching tube is connected with the first pin of the pulse output end, the first end of the eleventh switching tube is connected with the fourth pin of the pulse output end, the control end of the twelfth switching tube is connected with the second end of the tenth switching tube through a twenty-second resistor, and the control end of the eleventh switching tube is connected with the second end of the seventh switching tube through a sixteenth resistor.

Optionally, the switching unit includes a first switching circuit and a second switching circuit, the light emitting unit includes a first light emitting unit corresponding to the first switching circuit and a second light emitting unit corresponding to the second switching circuit, the first light emitting unit includes a plurality of dual-band light emitting beads, a forty-two resistor and a forty-four resistor, a first positive electrode and a second positive electrode of the plurality of dual-band light emitting beads are all connected with the power supply terminal, a first negative electrode of the plurality of dual-band light emitting beads is all connected with a first end of the first switching circuit through the forty-four resistor, a second negative electrode of the plurality of dual-band light emitting beads is all connected with a first end of the first switching circuit through the forty-two resistor, and a second ground of the first switching circuit is connected with a second ground; the second light-emitting unit may further include at least three dual-band light-emitting lamp beads, a nineteenth resistor and a twentieth resistor, at least three first anodes and second anodes of the dual-band light-emitting lamp beads are all connected with the power supply end, at least three first cathodes of the dual-band light-emitting lamp beads are all connected with the first end of the second switch circuit through the nineteenth resistor, at least three second cathodes of the dual-band light-emitting lamp beads are all connected with the first end of the second switch circuit through the twentieth resistor, the second end of the second switch circuit is grounded, and the first switch circuit and the second switch circuit are also connected with the second control end respectively.

Optionally, the wireless-controllable photoelectric thermal physiotherapy instrument further comprises a physiotherapy contact surface, the heating element and the electrode are respectively printed and arranged on the physiotherapy contact surface, the dual-band light-emitting lamp beads are embedded and arranged on the physiotherapy contact surface, and the physiotherapy contact surface is used for being in direct contact with a user body so as to provide light, electricity or heating physiotherapy.

Optionally, the light emitting band of the dual-band light emitting lamp bead is 660nm and 850nm.

Optionally, the wireless communication antenna is a bluetooth antenna, and the bluetooth antenna is in communication connection with the mobile terminal and is configured to receive a wireless control signal output by the mobile terminal.

The wireless-controllable photoelectric thermal physiotherapy instrument provided by the embodiment is provided with an electrotherapy module, a phototherapy module and a micro-control communication module, wherein an electrotherapy circuit can provide different power supplies according to a first control signal of the micro-control communication module, and pulse current is formed in an electric shock layer to provide electrotherapy services for users; the phototherapy module can switch the on or off state of the switch unit according to the second control signal of the micro-control communication module, so as to provide an on or off power supply line for the light-emitting unit, thereby providing phototherapy service for a user; the micro-control communication module further comprises a wireless communication antenna, can receive wireless control signals sent by the portable mobile terminal, transmits the wireless control signals to the processing unit, and the processing unit can generate first control signals, second control signals, mode switching signals and switching signals according to the wireless control signals, so that various physiotherapy services are provided for users, requirements of different users can be met through phototherapy, electrotherapy and photoelectric two-in-one therapy, dysmenorrhea and other body pains can be effectively relieved, the portable mobile terminal can be carried about and controlled through the mobile terminal, and physiotherapy effects and portability of the photoelectric thermal physiotherapy instrument are improved.

Drawings

Fig. 1 is a schematic structural diagram of a wireless-controllable photoelectric thermal physiotherapy apparatus according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of another wireless-controlled photo-thermal physiotherapy apparatus according to an embodiment of the present utility model;

fig. 3 is a schematic circuit diagram of a temperature-controlled heating module according to an embodiment of the present utility model;

fig. 4 is a schematic structural diagram of another embodiment of a wireless-controllable photo-thermal physiotherapy apparatus according to the present utility model;

fig. 5 is a schematic circuit diagram of a power supply module according to an embodiment of the present utility model;

fig. 6 is a schematic circuit diagram of an electrotherapy circuit according to an embodiment of the present utility model;

FIG. 7 is a schematic circuit diagram of a phototherapy circuit according to an embodiment of the present utility model;

fig. 8 is a schematic structural diagram of a micro-control communication module according to an embodiment of the present utility model.

Detailed Description

The utility model is described in further detail below with reference to the drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the utility model and are not limiting thereof. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present utility model are shown in the drawings.

The embodiment of the utility model provides a photoelectric thermal physiotherapy instrument capable of being controlled wirelessly. Fig. 1 is a schematic structural diagram of a wireless-controllable photo-thermal physiotherapy apparatus according to an embodiment of the present utility model, and referring to fig. 1, a wireless-controllable photo-thermal physiotherapy apparatus 100 includes: an electrotherapy module 101, a phototherapy module 102, and a micro-control communication module 103; the electrotherapy module 101 comprises an electrotherapy circuit 104, an electrode 105 and an electric shock layer 106, wherein the electrotherapy circuit 104 comprises a first control end a and a pulse output end d, the electrode 105 is electrically connected with the pulse output end d, the electric shock layer 106 is arranged on one side of the electrode 105 far away from the pulse output end d, and the electrotherapy circuit 104 is used for outputting pulse current to the electrode 105 from the pulse output end d according to a first control signal received by the first control end a; the phototherapy module 102 comprises a switch circuit 107 and a light emitting unit 108, the switch circuit 107 comprises a second control end b, the switch circuit 107 is connected with the light emitting unit 108, and the switch circuit 107 is used for controlling the working state of the light emitting unit 108 according to a second control signal received by the second control end b; the micro-control communication module 103 includes a wireless communication antenna 109 and a processing unit 110, where the processing unit 110 is connected to the first control end a, the second control end b, and the wireless communication antenna 109, and the processing unit 110 is configured to generate a first control signal and/or a second control signal according to a wireless control signal received by the wireless communication antenna 109.

Specifically, the electrotherapy module 101 is a device for forming pain stimulus by electric shock to human skin using pulse current, and can implement percutaneous nerve stimulation electrotherapy. The electrotherapy circuit 104 may be a pulse current forming circuit that may boost the direct current supplied from the rechargeable battery and supply the boosted power to the electrode 105. The first control end a of the electrotherapy circuit 104 is connected with the processing unit 110 in the micro-control communication module 103, and can receive a first control signal sent by the processing unit 110, and the electrotherapy circuit 104 can adjust the voltage level and the value of the pulse current after the boosting treatment according to the first control signal. The pain sense of the human skin corresponding to different pulse current values is different, and the electric stimulation treatment with different intensities can be realized. The electrode 105 may be a pulse coating layer disposed on the surface of the physiotherapy contact layer, and the pulse coating layer is made of conductive metal. The electric shock layer 106 may be a patch of conductive material, and is disposed on the surface of the electrode 105, so as to buffer, conduct electricity and form an electric shock arc between the electrode 105 and the skin of the human body. The phototherapy module 102 is an infrared physiotherapy device, and can emit infrared light to perform infrared physiotherapy on human body. The switch circuits 107 are in one-to-one correspondence with the light emitting units 108, and can switch on or off the power supply loop of the corresponding light emitting unit 108 according to the second control signal of the processing unit 110, so as to realize the switching of the working state of the light emitting unit 108. The light emitting unit 108 may include a plurality of infrared beads, and may emit infrared light to perform infrared physiotherapy on a human body. The wireless communication antenna 109 is connected to the processing unit 110, and can receive a wireless control signal sent by the portable mobile terminal, and send the wireless control signal to the processing unit 110. The processing unit 110 may be a signal analysis, calculation and processing device, and may generate the first control signal and/or the second control signal, as well as other mode switch control signals and intensity adjustment signals, based on the wireless control signal.

For example, when a user needs to be treated, the electro-optical thermal physiotherapy instrument can be worn next to the skin of the user, so that the electric shock layer 106 is closely attached to the skin of the user. When the user needs electrotherapy, the user can click on the portable terminal in the hand, and the portable terminal can transmit a wireless control signal to the wireless communication antenna 109, wherein the wireless control signal comprises electrotherapy switching information. The wireless communication antenna 109 is a bluetooth antenna, a wifi antenna, a 4G antenna or any other antenna capable of implementing wireless communication, where the wireless communication antenna 109 may be connected to a mobile terminal in a communication manner, and may receive a wireless control signal output by the mobile terminal. The processing unit 110 may analyze and process the wireless control signal to generate a mode switching signal to switch the photothermal physiotherapy instrument to the electrotherapy mode, so as to generate a first control signal to control the boost level of the electrotherapy circuit 104. The electrotherapy circuit 104 can provide power for the electrodes 105, can form an electric arc on the electric shock layer 106, and can perform electric shock physiotherapy on the skin of a user by utilizing pulse current in the electric arc, so that pain similar to acupuncture is generated in nerve formation of the user. The electrotherapy circuit 104 may switch power supplies of different voltage levels, different frequencies and waveforms provided to the electrodes 105 according to the first control signal to achieve several different pulsed currents at the shock layer 106. When the user needs phototherapy, the user may click on a portable terminal in the hand, and the portable terminal may transmit a wireless control signal to the wireless communication antenna 109, the wireless control signal including phototherapy switching information. The processing unit 110 may analyze and process the wireless control signal to generate a mode switching signal to switch the photothermal physiotherapy instrument into the phototherapy mode, so as to generate a second control signal to control the state of the switch circuit 107 of the phototherapy module 102, where the switch circuit 107 may be intermittently turned on, normally turned on for a preset time, or any other state. The light emitting unit 108 may emit infrared light when the switching circuit 107 is turned on, providing phototherapy to the user.

The wireless-controllable photoelectric thermal physiotherapy instrument provided by the embodiment is provided with an electrotherapy module, a phototherapy module and a micro-control communication module, wherein an electrotherapy circuit can provide different power supplies according to a first control signal of the micro-control communication module, and pulse current is formed in an electric shock layer to provide electrotherapy services for users; the phototherapy module can switch the on or off state of the switch circuit according to the second control signal of the micro-control communication module, so as to provide an on or off power supply line for the light-emitting unit, thereby providing phototherapy service for a user; the micro-control communication module further comprises a wireless communication antenna, can receive wireless control signals sent by the portable mobile terminal, transmits the wireless control signals to the processing unit, and the processing unit can generate first control signals, second control signals, mode switching signals and switching signals according to the wireless control signals, so that various physiotherapy services are provided for users, the requirements of different users can be met through phototherapy, electrotherapy and photoelectric two-in-one therapy, the portable physiotherapy equipment can be carried about and controlled through the mobile terminal, and the physiotherapy effect and the portability degree of the photoelectric thermal physiotherapy equipment are improved.

Fig. 2 is a schematic structural diagram of another wireless-controlled photo-thermal physiotherapy apparatus according to an embodiment of the present utility model, and fig. 3 is a schematic circuit diagram of a temperature-controlled heating module according to an embodiment of the present utility model, and in combination with fig. 2 and fig. 3, optionally, the wireless-controlled photo-thermal physiotherapy apparatus 100 further includes: the temperature control heating module 201, the temperature control heating module 201 includes a temperature control unit 202 and a temperature measurement unit 203, the temperature control unit 202 includes a third control end c and a heating element 301 (not shown in fig. 2), the third control end c is connected with the micro control communication module 103, and the temperature control unit 202 is configured to control the temperature of the heating element 301 according to a third control signal received by the third control end c; the temperature measuring unit 203 is closely attached to the heating element 301, and the temperature measuring unit 203 is connected with the processing unit 110 and is used for acquiring the real-time temperature of the heating element 301 and sending the real-time temperature to the processing unit 110; the processing unit 110 is further connected to the third control terminal c, and is further configured to generate a third control signal according to the wireless control signal and the real-time temperature received by the wireless communication antenna 109.

Specifically, referring to fig. 2 and 3, the temperature control unit 202 further includes a fifth switching tube Q5, a twenty-ninth resistor R29, and a thirty-ninth resistor R30, the third control end c is connected to the control end of the fifth switching tube Q5 through the thirty-ninth resistor R30, the control end of the fifth switching tube Q5 is grounded through the twenty-ninth resistor R29, the first end of the fifth switching tube Q5 is connected to the heating element 301, and the second end of the fifth switching tube Q5 is grounded. The third control terminal c is connected to the processing unit 110, and can input a pwm signal and a switching signal, where the pwm signal and the switching signal act on the control terminal of the fifth switching tube Q5, so as to realize temperature adjustment and on/off of the heating element 301. Illustratively, the heat generating element 301 may be a heat generating electrode pad. The fifth switching transistor Q5 may be an enhancement type field effect transistor.

The temperature measuring unit 203 includes a first temperature measuring element NTC1, a second temperature measuring element NTC2, a third capacitor C3, a fifth capacitor C5, a forty-six resistor R46, a forty-seven resistor R47, a first temperature measuring end NTC3 and a second temperature measuring end NTC4, where a first end of the first temperature measuring element NTC1 is connected to the processing unit 110 as the first temperature measuring end NTC3, and a second end of the first temperature measuring element NTC1 is connected to the protection ground PGND. The first end of the second temperature measuring element NTC2 is connected to the processing unit 110 as a second temperature measuring end NTC4, and the second end of the second temperature measuring element NTC2 is connected to the protection ground PGND. One end of the third capacitor C3 is grounded, and the other end of the third capacitor C is connected with the first temperature measuring end NTC 3. One end of the fifth capacitor C5 is grounded, and the other end of the fifth capacitor C is connected with the second temperature measuring end NTC 4. The first end of the forty-sixth resistor R46 is connected with the first temperature measuring end NTC3, and the second end of the forty-sixth resistor R46 is connected with the temperature measuring power supply end VDDIO. The first end of the forty-seventh resistor R47 is connected with the second temperature measuring end NTC4, and the second end of the forty-seventh resistor R47 is connected with the temperature measuring power supply end VDDIO. The first and second temperature measuring elements NTC1 and NTC2 may be, for example, thermistor pieces, or only a single or a plurality of thermistor pieces may be provided as needed. The first temperature measuring end NTC3 and the second temperature measuring end NTC4 may be respectively connected to the processing unit 110, and transmit the temperature signal to the value processing unit 110, where the processing unit 110 may control the output pulse width modulation signal according to the temperature signal, so as to realize closed loop control of the heating element 301, set the temperature not higher than 45 ℃, and avoid the scald caused by long-time thermal contact. It should be noted that, the temperature measuring unit 203 may include one or more temperature measuring elements, where the temperature measuring elements may be disposed at different positions of the heating electrode plate, or directly disposed on the surface of the physiotherapy contact surface, so as to enlarge the temperature sensing area, improve the temperature adjustment precision, and make the physiotherapy apparatus more intelligent and effective.

Optionally, with continued reference to fig. 2, the wirelessly controllable photo-thermal physiotherapy apparatus 100 further includes a physiotherapy contact surface on which the heating element 301 and the electrode 105 are respectively printed, and the dual-band light-emitting lamp beads in the light-emitting unit 108 may be embedded and disposed on the physiotherapy contact surface, where the physiotherapy contact surface is used for direct contact with the body of the user to provide light, electricity or heating physiotherapy.

Illustratively, the treatment interface may be a plastic panel, a fabric panel, a combination panel, or any other panel that can contact the human skin and provide a treatment interface. The physical therapy contact surface can be in direct contact with the skin of a human body, the heating element 301 printed on the physical therapy contact surface can provide thermal physical therapy, the electrode 105 and the electric shock layer 106 can provide electrotherapy, and the luminous element inlaid can emit infrared light to provide infrared light physical therapy for the human body. The modes of phototherapy, electrotherapy and thermotherapy can be switched according to the modes of a user and simultaneously act on the skin of a human body, so that the combined action of multiple modes is realized, and the effect and the intelligent degree of the physiotherapy instrument are improved.

Fig. 4 is a schematic structural diagram of another embodiment of a wireless-controllable photo-thermal physiotherapy apparatus according to the present utility model, and fig. 5 is a schematic circuit diagram of a power supply module according to the embodiment of the present utility model, where, in combination with fig. 4 and fig. 5, the wireless-controllable photo-thermal physiotherapy apparatus 100 further includes: the power supply module 401, the power supply module 401 includes a charging circuit 403 and a rechargeable battery 402, the charging circuit 403 is connected with the rechargeable battery 402; the charging circuit 403 includes a charging interface 503, where the charging interface 503 is used to connect to a charging power source, and the charging power source charges the rechargeable battery 402; the charging circuit 403 is further connected to the processing unit 110, and is configured to collect a state parameter of the rechargeable battery 402 and send the state parameter to the processing unit 110.

Specifically, the charging circuit 403 further includes a charging management chip 501, a charging protection chip 502, a charging detection port CHARG, a power supply detection port 5v_check, a battery voltage acquisition port bat_ad, a resistance switching port gnd_en, a first diode D1, a fifteenth switching transistor Q15, a second switching transistor Q2, a third switching transistor Q3, a ninth switching transistor Q9, a first resistor R1, a third resistor R3, a sixth resistor R6, an eleventh resistor R11, a twelfth resistor R12, and a power supply terminal VCC.

The sixth end 6 of the charging interface 503 is connected with the fourth end 4 of the charging management chip 501, the sixth end 6 of the charging interface 503 is also connected with the power supply end VCC through the first diode D1, the seventh end 7 of the charging management chip 501 is connected with the power supply end VCC through the first resistor R1, the seventh end 7 of the charging management chip 501 is also connected with the micro-control communication module 103 through the charging detection port CHARG, the fifth end 5 of the charging management chip 501 is connected with the power supply end VCC through the fifteenth switching tube Q15 and the second switching tube Q2 which are connected in series, and the fifth end 5 of the charging management chip 501 is also connected with the micro-control communication module 103 through the sixth resistor R6 and the battery voltage acquisition port bat_ad in sequence; the second end 2 of the charging protection chip 502 is connected with the negative electrode of the rechargeable battery 402 through a third switch tube Q3, the third end of the charging protection chip 502 is connected with the positive electrode of the rechargeable battery 402 through a third resistor R3, the control end of the third switch tube Q3 is respectively connected with the fifth end of the charging management chip 501 and the positive electrode of the rechargeable battery 402, the fourth end and the fifth end of the charging protection chip 502 are connected in series and then grounded, the control end of the fifteenth switch tube Q15 and the control end of the second switch tube Q2 are connected in series and then connected with the micro-control communication module 103 through a power supply detection port 5v_check, the power supply detection port 5v_check is connected with the fourth end of the charging management chip 501 through a twelfth resistor R12, and the power supply detection port 5v_check is grounded through an eleventh resistor R11. The charging management chip 501 can detect the charging parameters such as voltage, current and power provided by the charging interface 503, and adjust the charging current and voltage according to the charging parameters, so as to realize constant-current charging or constant-voltage charging of the rechargeable battery 402. The charging protection chip 502 can collect charging parameters such as current, voltage and temperature in the charging circuit 403, and cut off the circuit when the charging parameters are abnormal, so as to prevent the rechargeable battery 402 and related circuits from being damaged. The charge detection port char is connected to the micro-control communication module 103, and may output a charge status signal to the micro-control communication module 103, where the charge status signal may include a charge, non-charge, or charge parameter. The power supply detection port 5v_check is connected with the micro-control communication module 103, and can output electric signals of the control ends of the second switching tube Q2 and the fifteenth switching tube Q15 to the micro-control communication module 103, and the micro-control communication module 103 can judge whether the charging interface 503 has power supply access according to the signals output by the power supply detection port 5v_check. The battery voltage acquisition port bat_ad is connected with the micro-control communication module 103, and can output a battery voltage signal to the micro-control communication module 103, and the micro-control communication module 103 can determine the voltage value of the battery according to the battery voltage signal. The power supply terminal VCC can supply power to the electrotherapy module 101, the phototherapy module 102, the temperature control heating module 201 and the micro control communication module 103, when the charging interface 503 is powered on, the power connected to the charging interface 503 directly supplies power to the module connected to the power supply terminal VCC, and when the charging interface 503 is powered on or not, the rechargeable battery 402 supplies power to the module connected to the power supply terminal VCC. The control end of the ninth switching tube Q9 is connected with the resistance switching port GND_EN and is connected with the micro-control communication module 103, the ninth switching tube Q9 can be switched on or off according to a control signal of the micro-control communication module 103, and the size of a battery detection resistor can be switched, so that the purpose of saving electricity is achieved.

The wireless-controllable photoelectric thermal physiotherapy instrument provided by the embodiment is provided with a power supply module, wherein the power supply module comprises a charging circuit and a rechargeable battery, and a charging interface can be connected with a charging power supply to charge the rechargeable battery; the charging circuit can collect state parameters of the rechargeable battery and send the state parameters to the processing unit, the charging circuit is connected with the micro-control communication module, the charging circuit can determine the charging state, whether a power supply is connected to the charging interface or not and the voltage value of the battery according to feedback signals of the charging circuit, a power supply end in the charging circuit can provide a stable power supply for other modules, the dual power supply functions of the rechargeable battery power supply and the peripheral charging power supply of the physiotherapy instrument are realized, and the power supply reliability and the degree of freedom of the physiotherapy instrument are improved.

Fig. 6 is a circuit schematic diagram of an electrotherapy circuit according to an embodiment of the present utility model, referring to fig. 6, optionally, the electrotherapy circuit 104 includes a boost unit 601, a pulse current detection port ems_ad, a pulse voltage detection port hv_ad, a pulse width adjustment port hv_pwm, a boost control port boost_en, a first pulse signal control port EMS1, a second pulse signal control port EMS2, a sixth switching tube Q6, a seventh switching tube Q7, an eighth switching tube Q8, a tenth switching tube Q10, an eleventh switching tube Q11, a twelfth switching tube Q12, a fifth resistor R5, an eighth resistor R8, a seventeenth resistor R17, an eighteenth resistor R18, a thirty-ninth resistor R39, and a twenty-second resistor R22. The boost unit 601 is respectively connected with the power supply end VCC, the pulse width regulating port HV_PWM, the boost control port BOOSTER_EN and the pulse voltage detecting port HV_AD, and the boost unit 601 is also respectively connected with the first pin 1 and the second pin 2 of the pulse output end d through a sixth switching tube Q6; the first pulse signal control end EMS1 is connected with the control end of a seventh switching tube Q7 through a fifth resistor R5, and the second end of the seventh switching tube Q7 is connected with the control end of a sixth switching tube Q6 through an eighth resistor R8; the second pulse signal control end EMS2 is connected with the control end of a tenth switching tube Q10 through a seventeenth resistor R17, the second end of the tenth switching tube Q10 is connected with the control end of an eighth switching tube Q8 through an eighteenth resistor R18, the first end of the eighth switching tube Q8 is connected with the first end of a sixth switching tube Q6, and the second end of the eighth switching tube Q8 is respectively connected with a third pin 3 and a fourth pin 4 of a pulse output end d; the pulse current detection port EMS_AD is respectively connected with the second end of the twelfth switching tube Q12 and the second end of the eleventh switching tube Q11 through a thirty-ninth resistor R39, the first end of the twelfth switching tube Q12 is connected with the first pin 1 of the pulse output end d, the first end of the eleventh switching tube Q11 is connected with the fourth pin 4 of the pulse output end d, the control end of the twelfth switching tube Q12 is connected with the second end of the tenth switching tube Q10 through a twenty-second resistor R22, and the control end of the eleventh switching tube Q11 is connected with the second end of the seventh switching tube Q7 through a sixteenth resistor.

Specifically, the boost unit 601 is connected to the micro-control communication module through the pulse width modulation port hv_pwm, and can perform width modulation of the pulse voltage according to the pulse width modulation signal sent by the micro-control communication module. The boost unit 601 is connected with the micro-control communication module through a boost control port boost_en, and can perform voltage level adjustment of pulse voltage according to a boost control signal sent by the micro-control communication module. The boost unit 601 is connected with the micro-control communication module through the pulse voltage detection port hv_ad, and can detect the pulse voltage processed by the boost chip and feed back to the micro-control communication module. The pulse current detection port EMS_AD is connected with the micro-control communication module, and the micro-control communication module can determine the pulse current generated by the electrotherapy circuit according to the current detection signal output by the pulse current detection port EMS_AD. The sixth switching tube Q6, the eighth switching tube Q8, the eleventh switching tube Q11, the twelfth switching tube Q12, and the resistors connected therebetween may form a full-bridge driving circuit, convert the complementary pulse signals into low-frequency pulse signals, and output the low-frequency pulse signals to the electrodes through the pulse output terminal d. The seventh switching tube Q7 and the tenth switching tube Q10 can control the full-bridge driving circuit according to complementary pulse signals accessed by control ends of the seventh switching tube Q7 and the tenth switching tube Q10, and conversion of the pulse signals is achieved. The electrotherapy circuit can generate low-frequency pulse current to output to the electrode plate, and form an electric arc on the electric shock layer, so that the stimulation electrotherapy of the percutaneous nerve of the user is realized, and the physiotherapy effect can be improved.

Fig. 7 is a circuit schematic diagram of a phototherapy circuit according to an embodiment of the present utility model, referring to fig. 7, optionally, the phototherapy module 102 includes a first switch circuit 701, a second switch circuit 702, a first light emitting unit 703 corresponding to the first switch circuit 701, and a second light emitting unit 704 corresponding to the second switch circuit 702, the first light emitting unit 703 includes a plurality of dual-band light emitting bead LEDs, a forty-two resistor R42, and a forty-four resistor R44, first anodes and second anodes of the plurality of dual-band light emitting bead LEDs are connected to a power supply terminal VCC, first cathodes of the plurality of dual-band light emitting bead LEDs are connected to a first terminal of the first switch circuit 701 through the forty-four resistor R44, second cathodes of the plurality of dual-band light emitting bead LEDs are connected to a first terminal of the first switch circuit 701 through the forty-two resistor R42, and a second terminal of the first switch circuit 701 is grounded. The second light emitting unit 704 may further include at least three dual-band light emitting bead LEDs, a nineteenth resistor R19, and a twentieth resistor R20, wherein a first positive electrode and a second positive electrode of the at least three dual-band light emitting bead LEDs are connected to the power supply terminal VCC, a first negative electrode of the at least three dual-band light emitting bead LEDs is connected to the first end of the second switch circuit 702 through the nineteenth resistor R19, and a second negative electrode of the at least three dual-band light emitting bead LEDs is connected to the first end of the second switch circuit 702 through the twentieth resistor R20, and a second ground of the second switch circuit 702. The luminous wave band of the dual-band luminous lamp bead LED is 660nm and 850nm, and each dual-band luminous lamp bead LED can emit infrared light and visible light.

The control end foton_led2 of the first switch circuit 701 and the control end foton_led1 of the second switch circuit 702 are both connected as a second control end with the processing unit of the micro-control communication module, and can control the working state of the phototherapy module 102 according to the second control signal of the processing unit, where the working state of the phototherapy module 102 may include infrared light emission, no infrared light emission and visible light flickering, each dual-band light-emitting bead LED emits light of 850nm band only under the condition of infrared light emission, each dual-band light-emitting bead LED stops working under the condition of no infrared light emission, and the first light-emitting unit 703 and the second light-emitting unit 704 alternately emit visible light of 660nm under the condition of visible light flickering, so as to form a flashing light effect of the switch machine, and improve user experience.

Fig. 8 is a schematic structural diagram of a micro-control communication module according to an embodiment of the present utility model, and referring to fig. 8, alternatively, the micro-control communication module 103 includes a wireless communication antenna 109 and a processing unit 110, where the processing unit 110 is connected to the wireless communication antenna 109.

Specifically, the wireless communication antenna 109 may be a bluetooth antenna, and may be in wireless communication connection with a mobile phone, a tablet computer or other mobile terminals. The processing unit 110 may be a chip with a bluetooth signal processing function, the processing unit 110 may be further connected to other various modules, and may process a signal received by the bluetooth antenna, and may control other modules according to a signal received by the bluetooth antenna, where the wireless communication antenna 109 and the processing unit 110 are both powered by the power supply VCC. In addition, the photo-thermal physiotherapy instrument capable of being controlled wirelessly can further comprise a key assembly and an indicator light assembly, and the key assembly and the indicator light assembly are connected with the processing unit 110. The key assembly comprises a power supply and mode switching key, a gear increasing key and a gear reducing key, wherein the power supply and mode switching key can input a switching signal and a gear switching signal, the gear increasing key can increase the stimulation intensity of the electrotherapy mode, and the gear reducing key can reduce the stimulation intensity of the electrotherapy mode. The indicator light assembly can display different light effects under different gears and intensities, so that the information display function is achieved, and the use feeling of a user is improved.

The wireless-controllable photoelectric thermal physiotherapy instrument provided by the embodiment is provided with an electrotherapy module, a phototherapy module, a temperature control heating module and a micro-control communication module, wherein an electrotherapy circuit can provide different power supplies according to a first control signal of the micro-control communication module, and pulse current is formed on an electric shock layer to provide electrotherapy services for users; the phototherapy module can switch the on or off state of the switch unit according to the second control signal of the micro-control communication module, so as to provide an on or off power supply line for the light-emitting unit, thereby providing phototherapy service for a user; the temperature control heating module can collect temperature signals and control signals of the processing unit to adjust the temperature of the heating element in a closed loop, hot compress physiotherapy is provided for users, the micro control communication module further comprises a wireless communication antenna, can receive wireless control signals sent by the portable mobile terminal and transmit the wireless control signals to the processing unit, the processing unit can generate first control signals, second control signals, mode switching signals and switching signals according to the wireless control signals, various physiotherapy services are provided for users, the requirements of different users can be met through phototherapy, electrotherapy, hot compress therapy and multi-therapy combined therapy, dysmenorrhea and other body pains can be effectively relieved, and the physiotherapy effect of the photoelectric thermal physiotherapy instrument is improved.

Note that the above is only a preferred embodiment of the present utility model and the technical principle applied. It will be understood by those skilled in the art that the present utility model is not limited to the particular embodiments described herein, and that various obvious changes, rearrangements, combinations, and substitutions can be made by those skilled in the art without departing from the scope of the utility model. Therefore, while the utility model has been described in connection with the above embodiments, the utility model is not limited to the embodiments, but may be embodied in many other equivalent forms without departing from the spirit or scope of the utility model, which is set forth in the following claims.

Claims (10)

1. A wirelessly controllable electro-optical thermal physiotherapy apparatus, comprising: the device comprises an electrotherapy module, a phototherapy module and a micro-control communication module;

the electrotherapy module comprises an electrotherapy circuit, an electrode and an electric shock layer, wherein the electrotherapy circuit comprises a first control end and a pulse output end, the electrode is electrically connected with the pulse output end, the electric shock layer is arranged on one side of the electrode far away from the pulse output end, and the electrotherapy circuit is used for outputting pulse current to the electrode from the pulse output end according to a first control signal received by the first control end;

The phototherapy module comprises a switch circuit and a light-emitting unit, the switch circuit comprises a second control end, the switch circuit is connected with the light-emitting unit, and the switch circuit is used for controlling the working state of the light-emitting unit according to a second control signal received by the second control end;

the micro-control communication module comprises a wireless communication antenna and a processing unit, wherein the processing unit is respectively connected with the first control end, the second control end and the wireless communication antenna, and the processing unit is used for generating the first control signal and/or the second control signal according to wireless control signals received by the wireless communication antenna.

2. The wirelessly controllable photothermal therapy apparatus according to claim 1, further comprising: the temperature control heating module comprises a temperature control unit and a temperature measurement unit, the temperature control unit comprises a third control end and a heating element, the third control end is connected with the micro control communication module, and the temperature control unit is used for controlling the temperature of the heating element according to a third control signal received by the third control end;

the temperature measuring unit is closely attached to the heating element and is connected with the processing unit and used for collecting the real-time temperature of the heating element and sending the real-time temperature to the processing unit;

The processing unit is further connected with the third control end and is further used for generating a third control signal according to the wireless control signal received by the wireless communication antenna and the real-time temperature.

3. The wirelessly controllable photo-thermal physiotherapy apparatus according to claim 2, wherein the temperature control unit comprises a fifth switching tube, a twenty-ninth resistor and a thirty-eighth resistor, the third control end is connected with the control end of the fifth switching tube through the thirty-seventh resistor, the control end of the fifth switching tube is grounded through the twenty-ninth resistor, the first end of the fifth switching tube is connected with the heating element, and the second end of the fifth switching tube is grounded.

4. The wirelessly controllable photothermal therapy apparatus according to claim 2, further comprising: the power supply module comprises a charging circuit and a rechargeable battery, and the charging circuit is connected with the rechargeable battery; the charging circuit comprises a charging interface, wherein the charging interface is used for being connected with a charging power supply to charge the rechargeable battery; the charging circuit is also connected with the processing unit and used for collecting state parameters of the rechargeable battery and sending the state parameters to the processing unit.

5. The wirelessly controllable photo-thermal physiotherapy instrument of claim 4, wherein the charging circuit further comprises a charge management chip, a charge protection chip, a charge detection port, a power supply detection port, a battery voltage acquisition port, a first diode, a fifteenth switching tube, a second switching tube, a third switching tube, a first resistor, a third resistor, a sixth resistor, an eleventh resistor, a twelfth resistor, and a power supply terminal;

the sixth end of the charging interface is connected with the fourth end of the charging management chip, the sixth end of the charging interface is also connected with the power supply end through the first diode, the seventh end of the charging management chip is connected with the power supply end through the first resistor, the seventh end of the charging management chip is also connected with the micro-control communication module through the charging detection port, the fifth end of the charging management chip is connected with the power supply end through the fifteen switching tubes and the second switching tubes which are connected in series, and the fifth end of the charging management chip is also connected with the micro-control communication module through the sixth resistor and the battery voltage acquisition port in sequence; the second end of the charging protection chip is connected with the negative electrode of the rechargeable battery through the third switch tube, the third end of the charging protection chip is connected with the positive electrode of the rechargeable battery through the third resistor, the control end of the third switch tube is connected with the fifth end of the charging management chip and the positive electrode of the rechargeable battery respectively, the fourth end and the fifth end of the charging protection chip are connected in series and then grounded, the control end of the fifteenth switch tube and the control end of the second switch tube are connected in series and then connected with the micro-control communication module through a power supply detection port, the power supply detection port is connected with the fourth end of the charging management chip through the twelfth resistor, and the power supply detection port is grounded through the eleventh resistor.

6. The wirelessly controllable electro-optical thermal physiotherapy apparatus according to claim 5, wherein the electrotherapy circuit comprises a boost unit, a pulse current detection port, a pulse voltage detection port, a pulse width adjustment port, a boost control port, a first pulse signal control port, a second pulse signal control port, a sixth switching tube, a seventh switching tube, an eighth switching tube, a tenth switching tube, an eleventh switching tube, a twelfth switching tube, a fifth resistor, an eighth resistor, a seventeenth resistor, an eighteenth resistor, a thirty-ninth resistor, and a twenty-second resistor;

the boosting unit is respectively connected with the power supply end, the pulse width adjusting port, the boosting control port and the pulse voltage detecting port, and is also respectively connected with a first pin and a second pin of the pulse output end through the sixth switching tube; the first pulse signal control end is connected with the control end of the seventh switching tube through the fifth resistor, and the second end of the seventh switching tube is connected with the control end of the sixth switching tube through the eighth resistor; the second pulse signal control end is connected with the control end of the tenth switching tube through the seventeenth resistor, the second end of the tenth switching tube is connected with the control end of the eighth switching tube through the eighteenth resistor, the first end of the eighth switching tube is connected with the first end of the sixth switching tube, and the second end of the eighth switching tube is respectively connected with the third pin and the fourth pin of the pulse output end; the pulse current detection port is respectively connected with the second end of the twelfth switching tube and the second end of the eleventh switching tube through a thirty-ninth resistor, the first end of the twelfth switching tube is connected with the first pin of the pulse output end, the first end of the eleventh switching tube is connected with the fourth pin of the pulse output end, the control end of the twelfth switching tube is connected with the second end of the tenth switching tube through a twenty-second resistor, and the control end of the eleventh switching tube is connected with the second end of the seventh switching tube through a sixteenth resistor.

7. The wirelessly controllable photo-thermal physiotherapy instrument according to claim 5, wherein the switching circuit comprises a first switching circuit and a second switching circuit, the light emitting unit comprises a first light emitting unit corresponding to the first switching circuit and a second light emitting unit corresponding to the second switching circuit, the first light emitting unit comprises a plurality of dual-band light emitting lamp beads, a forty-two resistor and a forty-four resistor, a first positive electrode and a second positive electrode of the plurality of dual-band light emitting lamp beads are connected with the power supply end, a first negative electrode of the plurality of dual-band light emitting lamp beads are connected with a first end of the first switching circuit through the forty-four resistor, a second negative electrode of the plurality of dual-band light emitting lamp beads are connected with a first end of the first switching circuit through the forty-two resistor, and a second ground of the first switching circuit is grounded; the second light-emitting unit may further include at least three dual-band light-emitting lamp beads, a nineteenth resistor and a twentieth resistor, at least three first anodes and second anodes of the dual-band light-emitting lamp beads are all connected with the power supply end, at least three first cathodes of the dual-band light-emitting lamp beads are all connected with the first end of the second switch circuit through the nineteenth resistor, at least three second cathodes of the dual-band light-emitting lamp beads are all connected with the first end of the second switch circuit through the twentieth resistor, the second end of the second switch circuit is grounded, and the first switch circuit and the second switch circuit are also connected with the second control end respectively.

8. The wirelessly controllable electro-optical thermal physiotherapy apparatus according to claim 7, further comprising a physiotherapy contact surface, wherein the heating element and the electrode are respectively printed on the physiotherapy contact surface, and the dual-band light-emitting lamp bead is embedded on the physiotherapy contact surface, and the physiotherapy contact surface is used for being in direct contact with a user's body to provide light, electricity or heating physiotherapy.

9. The wirelessly controllable photothermal therapy apparatus according to claim 7, wherein the dual-band light-emitting light beads have light emission bands of 660nm and 850nm.

10. The wireless-controllable photoelectric thermal physiotherapy apparatus according to claim 1, wherein the wireless communication antenna is a bluetooth antenna, and the bluetooth antenna is in communication connection with a mobile terminal and is configured to receive a wireless control signal output by the mobile terminal.