CN205411928U - Wearable portable pulse antiperspirant appearance of APP control - Google Patents

Abstract

The utility model relates to the technical field of medical and health care equipment, and discloses a wearable portable pulse antiperspirant device controlled by an APP, comprising: an intelligent mobile device APP and a portable pulse antiperspirant device, and the intelligent mobile device APP passes through a bluetooth communication module Wirelessly connected with the pulse generator; the pulse generator includes: DC voltage conversion circuit, MCU microcontroller, pulse output control module and load detection module, between the negative electrode of the output end of the MCU microcontroller and the pulse output control module A load detection module is provided to detect the state of load addition, so as to control the data output step by step through the MCU microcontroller; Various injuries or complications; provide users with intelligent, humanized, portable control and operation, and provide users with safety and protection measures.

Description

A wearable and portable pulse antiperspirant device controlled by APP

technical field

The utility model relates to the technical field of medical care equipment, in particular to a wearable and portable pulse antiperspirant instrument controlled by an APP.

Background technique

Human hyperhidrosis is a very common phenomenon. According to statistics, about 3% of the population has this problem. Hyperhidrosis generally affects the palms, soles, armpits, face, neck and back. Although hyperhidrosis is not a serious disease, it brings great inconvenience to people's daily life, work, and social activities. The prior art for the medical treatment of hyperhidrosis mainly adopts drug therapy and surgical treatment at present.

1. Disadvantages of drug treatment of hyperhidrosis: Most of the drugs for the treatment of hyperhidrosis contain pharmaceutical ingredients that are harmful to the human body, or cause varying degrees of side effects and damage to the human nervous system.

2. Disadvantages of surgical treatment of hyperhidrosis: At present, a more effective treatment method is thoracoscopic thoracic sympathetic clamping, which has significant effects on palms, soles, armpits, face, neck, and back hyperhidrosis. Effect. However, the biggest disadvantage of this surgical treatment is that it can lead to permanent anhidrosis and compensatory hyperhidrosis in other parts of the body, so it is gradually abandoned by hyperhidrosis patients.

Due to the shortcomings of the above-mentioned existing treatment techniques, there is a need for a new technique to solve or improve the shortcomings of the prior art. The present invention designs a wearable portable pulse antiperspirant instrument controlled by APP: (1) Stimulate the nerve synapses between the sweat induction nerves and sweat glands on the hyperhidrosis skin by generating pulse currents of a specific frequency. When the touch is stimulated by the pulse current to a certain level, the sensitivity of the sweat glands is reduced, and they are no longer stimulated and excited, thus stopping sweating. This antiperspirant principle does not directly act on sweat glands, so it does not cause harm to human sweat glands; (2) The wearable and portable pulse antiperspirant device controlled by APP allows users to treat hyperhidrosis anytime, anywhere in the home, office and other environments. treatment, bringing great convenience to users. According to the patent search query, there is no technology described in the patent in China at present.

Contents of the invention

In order to overcome the deficiencies of the prior art, the utility model provides a wearable and portable pulse antiperspirant instrument controlled by an APP.

For realizing above-mentioned invention, the utility model adopts technical scheme as follows:

A wearable and portable pulse antiperspirant device controlled by an APP, including: an intelligent mobile device APP, a Bluetooth communication module, a pulse generator, and a wearable soft rubber electrode. The positive and negative electrodes of the wearable soft gel electrodes are connected respectively.

The smart mobile device APP is an application program running on an Android or iOS smart mobile device with a bluetooth function. First, through the Bluetooth setting, the smart mobile device is paired with the Bluetooth communication module, and then the setting and control instructions are sent to the MCU microprocessor controlling the pulse generator through the Bluetooth communication module, including pulse frequency, pulse voltage value, and pulse current. value, pulse duty cycle, single working time, and the setting value of the treatment site, these setting values are adjusted and set through the corresponding plus/minus button and the setting button on the APP interface, and confirmed by pressing the "confirm" button . At the same time, the MCU microprocessor transmits the load status, pulse voltage value, pulse current value, or voltage and current limit alarm to the smart mobile device APP through the Bluetooth communication module, and displays it on the APP at the same time. The single working time is displayed on the APP through the timer of the smart mobile device, and the record of the total treatment time is the accumulation of the time when all loads are connected. When a satisfactory course of treatment is reached, the accumulated total treatment time can inform the user of the statistical total time of the course of treatment, and then the user can reset the accumulated time to zero through the "Reset" button set on the APP interface, so as to restart the timing for the next course of treatment . In addition, set a limited voltage and current limited alarm on the APP interface of the smart mobile device. When the voltage or current exceeds 30V or 20mA due to an abnormal circuit, the alarm will flash and beep; when the circuit abnormality is resolved, the alarm will be automatically cancelled. .

The Bluetooth communication module is a communication module between the smart mobile device and the pulse generator. Through this module, the instructions sent by the smart mobile device APP are transmitted to the MCU microprocessor, and then transmitted to the MCU microprocessor after being processed by the MCU microprocessor. Pulse generator circuit; at the same time, the MCU microprocessor also transmits real-time pulse voltage, pulse current, single working time, and load status information to the smart mobile device APP through the Bluetooth communication module.

The pulse generator includes: a DC voltage conversion circuit, an MCU microcontroller, a pulse output control module, and a load detection module. The output frequency of the pulse generator is adjustable between 0.2Hz and 10KHz, and the pulse width and duty ratio can be adjusted by Sets the regulated pulse wave.

The DC voltage conversion circuit includes a DC-DC boost circuit and a DC-DC step-down circuit. The signal input terminal of the MCU microcontroller is connected to the key switch to receive the key input value, the signal output terminal of the MCU microcontroller is connected to the information display device to output display information, and the A/D detection input of the MCU microcontroller The terminal receives the current sampling value of the current sampling module, the MCU microcontroller controls the PWM control module through its PWM (pulse width modulation) port, and the MCU microcontroller inputs to the voltage amplification module through the D/A conversion module through its data output port.

The pulse output control module includes: a D/A conversion module, a voltage amplification module, a voltage and current control module, a current sampling module, a PWM control module, and a resettable fuse. The output value of the D/A conversion module is used as the input of the voltage amplification module, the output terminal of the voltage amplification module is connected to the control terminal of the voltage and current control module, and the input terminal of the voltage and current control module is connected to the DC-DC booster circuit output The input terminal of the DC-DC step-up circuit is connected to the DC voltage input, and the DC power input is a rechargeable lithium battery; the output terminal of the voltage and current control module is connected to the PWM control module; the PWM control module is connected to the DC voltage via a resettable fuse Wearable soft gel electrodes are connected. The current sampling module is connected with the negative electrode of the wearable soft gel electrode, and feeds back the current sampling value to the A/D detection terminal of the MCU microcontroller.

A load detection module is arranged between the MCU microcontroller and the negative electrode of the output terminal of the pulse output control module, which is used to detect the state of load addition, so that the data output is controlled step by step by the MCU microcontroller.

A wearable and portable pulse antiperspirant device controlled by APP, the structure of the wearable soft gel electrode includes: two pieces of soft gel conductive electrodes and two metal wires connected thereto. Among them, the shape of the wearable soft gel electrode includes square, rectangular, curved n-shape, and mask shape with hollowed out eyes, nose and mouth, and its size is customized according to the size of the sweaty part.

By adopting the above-mentioned technical scheme, the utility model has the following advantages:

1. Health: Treat human hyperhidrosis with healthy methods, avoiding various injuries or complications to the human body caused by the above-mentioned drugs or surgical treatment;

2. Safety: By adopting adaptive voltage and current control output, multiple current limiting and voltage limiting methods and modules, it brings safe treatment and protection measures to users;

3. Intelligence: through the use of smart mobile device APP control, it provides users with intelligent and humanized control and operation;

4. Comfort: Through the pulse output controlled by the MCU, the control of the gradual change of pulse voltage and current is achieved, so that users can avoid experiencing sudden changes in voltage and current, thus bringing users a relaxed and comfortable treatment experience;

5. Efficient: Using pulse output, by adjusting and controlling the pulse duty cycle, the user can correspondingly increase the voltage peak value that can be tolerated during treatment, so as to bring users a therapeutic effect that takes into account both the comfort and efficiency of antiperspirant treatment ;

6. Convenience: The external rechargeable lithium battery is used as the DC power input, and the wearable soft rubber electrode can be pasted on any sweaty part of the body for treatment because of its own stickiness, so that the user can move freely during the treatment, providing users with Provide great mobility and convenience;

7. Long-lasting therapeutic effect: According to a large number of experiments of the present invention, ordinary hyperhidrosis patients can feel the curative effect after a total of about 10 hours of treatment, and after using it for 30-60 minutes a day for a course of treatment for about 8-10 days, the body will feel more The sweaty part will keep warm and dry for about 28-38 days. Afterwards, according to the user's own situation, when the sweat glands in the hyperhidrosis area gradually resume sweating, the antiperspirant effect will continue for about 28 to 38 days after another treatment with the same dose or a reduced dose.

Description of drawings

Figure 1 is a block diagram of the overall circuit principle of the wearable portable pulse antiperspirant instrument;

Figure 2 is the smart mobile device APP;

Fig. 3 is the structure embodiment 1 of the wearable portable pulse antiperspirant instrument;

Fig. 4 is the structure embodiment 2 of the wearable portable pulse antiperspirant instrument;

Figure 5 DC voltage conversion circuit;

Fig. 6 is a voltage amplification circuit diagram;

Fig. 7 is a voltage and current control module diagram;

Fig. 8 is a structural schematic diagram of a wearable soft gel electrode;

Figure 9 is a schematic diagram of the structure of a wearable soft gel electrode used in the armpit;

Fig. 10 is a schematic diagram of the structure of the soft gel conductive electrode used for the face.

detailed description

A wearable and portable pulse antiperspirant device controlled by APP. The design and use method of the present invention will be explained in detail below. On the basis of conforming to the principles shown in the following embodiments, various changes can be derived, including circuits, structural shapes Superior Design Variations. The purpose of disclosing the present invention is to protect all changes and improvements within the scope of the present invention, and the present invention is not limited to the following embodiments.

Example of APP-controlled wearable and portable pulse antiperspirant instrument:

As shown in Figure 1, a wearable portable pulse antiperspirant instrument controlled by APP includes: smart mobile device APP, Bluetooth communication module, pulse generator, wearable soft rubber electrode, the output of the pulse generator is positive and negative The electrodes are respectively connected to the positive and negative electrodes of the wearable soft gel electrode through metal wires.

The smart mobile device APP is an application program running on an Android or iOS smart mobile device with a bluetooth function. As shown in Figure 2, firstly, through the Bluetooth setting, the smart mobile device is paired with the Bluetooth communication module. Then, by sending the setting and control instructions to the MCU microprocessor controlling the pulse generator through the Bluetooth communication module, including pulse frequency, pulse voltage value, pulse current value, pulse duty cycle, single working time, cumulative treatment The total time, the setting value of the treatment part, these setting values are adjusted and set through the corresponding plus/minus button and the setting button on the APP interface, and confirmed by pressing the "confirm" button. For example: pulse frequency, duty cycle, pulse voltage, pulse current, and single working time can all be adjusted through the plus/minus buttons on their respective left and right sides, and their respective unit nominal values are kilohertz KHz and percentage % , volts, mA, and minutes. When adjusting the treatment part, you only need to press the button of the corresponding treatment part, including hands, feet, underarms, face, neck, or back, and the smart mobile device APP will display the preset values for the respective treatment parts, including the occupied area. Duty ratio, pulse voltage, pulse current and single working time. For example: for underarm antiperspirant treatment, due to the high sensitivity of the underarm skin, the pulse voltage and current setting values are correspondingly lowered in advance, and the duty cycle is also adjusted to a relatively low value. At the same time, the MCU microprocessor transmits the load status, pulse voltage value, pulse current value, or voltage and current limit alarm to the smart mobile device APP through the Bluetooth communication module, and displays it on the APP at the same time. The single working time is displayed on the APP through the timer of the smart mobile device, and the record of the total treatment time is the accumulation of the time when all loads are connected. When a satisfactory course of treatment is reached, the accumulated total treatment time can inform the user of the statistical total time of the course of treatment, and then the user can reset it to zero through the "Reset" button set on the APP interface, so as to restart the timing for the next course of treatment. In addition, set a limited voltage and current limited alarm on the APP interface of the smart mobile device. When the voltage or current exceeds 30V or 20mA due to an abnormal circuit, the alarm will flash and beep; when the circuit abnormality is resolved, the alarm will be automatically cancelled. .

The Bluetooth communication module is a communication module between the smart mobile device and the pulse generator. Through this module, the instructions sent by the smart mobile device APP are transmitted to the MCU microprocessor and then transmitted to the MCU microprocessor after processing by the MCU microprocessor. Pulse generator circuit; at the same time, the MCU microprocessor also transmits real-time pulse voltage, pulse current, load status, and voltage and current limiting information to the smart mobile device APP through the Bluetooth communication module. The bluetooth communication module preferably adopts the CC2540 low-power bluetooth module of TI Company, and the module is powered by a DC-DC step-down circuit. The MCU microprocessor is connected to the Bluetooth communication module through the serial port. After the Bluetooth module is started, it will automatically broadcast. When the smart mobile device APP is opened, the Bluetooth communication module will be scanned and connected. After the pairing is successful, the Bluetooth communication module can be connected to the general serial port. For two-way communication. When the smart mobile device writes to the Bluetooth communication module through the APP, the written data will be sent to the MCU microprocessor through the serial port, and then through the D/A digital-to-analog conversion module, the voltage amplification module, the voltage and current control module, and the PWM The control module performs regulatory control. When the smart mobile device reads the Bluetooth communication module through the APP, the Bluetooth communication module obtains the A/D analog-to-digital conversion data, load status, and voltage and current limiting information from the MCU microprocessor through the serial port, and then returns to the Bluetooth communication module through the Bluetooth protocol stack. The smart mobile device APP described above is displayed on the smart mobile device interface through the display interface of the APP.

The pulse generator includes: a DC voltage conversion circuit, an MCU microcontroller, a pulse output control module, and a load detection module. The output of the pulse generator is a pulse width duty cycle with a frequency between 0.2Hz and 10KHz, which can be passed Sets the regulated pulse wave.

The DC voltage conversion circuit includes a DC-DC boost circuit and a DC-DC step-down circuit. As shown in Figure 5, the DC-DC boost circuit is a boost circuit composed of a boost integrated chip LM2577S (U1). The DC power input voltage comes from an external rechargeable lithium battery, and its input voltage range is 5-12V . The DC power input is connected from the P5 terminal, whose terminal 2 is the positive pole and terminal 1 is the ground, and is connected to the boost circuit using the boost integrated chip U1 through the resettable fuse FB1. The comparison terminal COMP of U1 is connected to the capacitor C4 through the resistor R2, and is grounded through the C4. The feedback terminal BACK of U1 is connected to resistors R3, R64 and R25 respectively, the other end of R25 is grounded, the other end of R64 is connected to the collector of transistor Q26, the emitter of Q26 is grounded, and the base of Q26 is connected to the MCU microcontroller through resistor R65. A control port of the controller is connected to the RL_OFF terminal. This port controls the on-off of Q26 to control the different power supply voltages of the intelligent pulse generator in the power-on state and standby state. When no load is detected, the intelligent pulse generator is in the In standby mode, the boost circuit only outputs 12V. GND1 and GND2 of U1 are commonly grounded. The VIN end of U1 is grounded through capacitors C3 and C17. The SWITCH terminal of U1 outputs the voltage to the V-OUT terminal through the Schottky diode D2 (IN5821), and the V-OUT terminal is input to the voltage and current control module.

The DC-DC step-down circuit includes a three-terminal voltage stabilizing circuit module composed of two AMS1117 connected in series. The other way that the DC input power is connected from P5 terminal 2 is the input end of the three-terminal voltage regulator integrated block Q8 (AMS1117), the output end of Q8 is connected to the output filter capacitor C1, and the other end of C1 is grounded together with the ground end of Q8. The output 5V of Q8 supplies power for the D/A conversion module and also serves as the input of Q13. The circuit connection of Q13 is the same as that of Q8, and its output 3.3V supplies power for the MCU microprocessor and the Bluetooth communication module.

The model of the MCU microprocessor may be, but not limited to, STC12LE5A16AD. As the control core of the pulse generator, the input signal of the MCU microcontroller includes the reading signal from the smart mobile device APP via the Bluetooth communication module, the feedback signal of the current sampling module input via the A/D detection port, and the load detection The load status signal from the module; at the same time, the MCU microcontroller outputs the digital control signal to the D/A conversion module through the data output terminal, and outputs the PWM control signal to the PWM control module, and at the same time, the pulse voltage value, pulse current value, load status, The information of voltage limitation and current limitation is sent to the APP display interface of the smart mobile device through the Bluetooth communication module in real time.

The pulse output control module includes: a D/A conversion module, a voltage amplification module, a voltage and current control module, a current sampling module, a PWM control module, and a resettable fuse. The D/A conversion module is a digital-to-analog conversion circuit mainly composed of TLC5615 serial digital-to-analog converter, its power supply is powered by 5V of DC-DC step-down circuit, and its conversion update rate is 1.21MHz. The MCU microcontroller controls the output of the D/A conversion module by outputting binary codes through the data output terminal, with an interval of 0.1V and an output range of 0.1V~5V.

The voltage amplifying module is shown in Figure 6, the output of the D/A conversion module is connected to the input DA-IN port of the voltage amplifying module, and the triode group Q25, Q27, Q28, Q29, Q30, Q31, Q32, Q33, The differential voltage amplifier circuit composed of Q35 amplifies the input voltage by 12 times and outputs it to the voltage and current control module through K-OUT. In Fig. 6, a current protection circuit is also formed by the transistor Q36. When the conduction voltage drop between the emitter V-OUT2 and the base V-OUT1 of the transistor Q36 reaches 0.6V, the current of this part of the circuit reaches 20mA, at this time the voltage amplifying module will enter a limited state, and the circuit will stop amplifying , so as to achieve 20mA current limiting protection.

As shown in Figure 7, the input terminal of the voltage and current control module is connected to the output terminal V-OUT of the DC-DC booster circuit, the control terminal of the voltage and current control module is connected to the output terminal K-OUT of the voltage amplification module, and the voltage The output terminal of the current control module is connected with the input terminal of the PWM control module, and the output of the PWM control module is connected with the positive pole of the wearable soft rubber electrode terminal through a resettable fuse FB2. The voltage and current control module is composed of a group of parallel amplifying transistors and a group of current sharing resistors. Its working principle is to control the base current of the group of transistors and the collector voltage of the group of transistors, and then obtain The emitter of the emitter obtains an output voltage with a large current, and then outputs it to the PWM control module through a set of current sharing resistors.

As shown in FIG. 1 , one end of the current sampling module is connected to the negative electrode of the pulse generator, and the other end is connected to the A/D detection end of the MCU microcontroller. When the load is added, the current sampling module will feed back the collected real-time current value to the MCU microcontroller through the A/D detection terminal, and compare it with the current value set by the key input. In the setting state, set the maximum current output value to 20mA, so that the MCU microcontroller collects and detects the real-time current value in real time in the working state. When the current is less than the human body safety voltage 30V limited by the pulse generator divided by 2 kohms or 15mA, The MCU microcontroller will control the D/A conversion module, the voltage amplification module, and the voltage and current module through the data output to perform closed-loop control to increase the output; when the sampling current reaches 15mA, the voltage output reaches the maximum limit of 30V. The MCU microcontroller then stops increasing the voltage. Therefore, no matter which voltage or current reaches the maximum limit value (30V or 20mA) first, the MCU microcontroller will control the voltage and current limit accordingly. At the same time, when the instantaneous current of the input or output terminal of the pulse output control module reaches the maximum limit value of 20mA, the resistance value of the resettable fuse FB1/FB2 will increase with the increase of the current until it is equivalent to the infinity of the open circuit. After the abnormal problem is solved and disappears, the resettable fuse FB1/FB2 will return to the initial normal state. Feedback from the current sampling module to the MCU microcontroller, and then through the MCU microcontroller comparison processing, the result of the comparison operation is output to the D/A conversion module through data, and then to the voltage amplification module, voltage and current control module, PWM control module, Through the resettable fuse FB2 to the load, a closed-loop adaptive voltage and current control loop is formed; at the same time, the two resettable fuses FB1 and FB2 have performed double current limiting protection on the input and output terminals of the pulse output control module, thus ensuring The voltage and current output by the pulse generator are strictly limited within the safe range (30V, 20mA) allowed by the human body under the multiple protection of the circuit. The PWM control module is a circuit for controlling pulse frequency and duty ratio composed of a PWM control port of an MCU microcontroller, a group of triodes and a resistor. Set the frequency of the output PWM waveform by setting the period of the MCU microcontroller PWM timer, set the duty cycle of the output PWM waveform by setting the comparison value of the PWM timer, and control the PWM switch amplified output through a set of transistors and resistors.

The load detection module is a module connected between the output negative electrode of the pulse generator and the MCU microcontroller to monitor the load connection status in real time. The module consists of a group of capacitors, resistors and diodes connected in parallel. This circuit is responsible for testing the sampling voltage and current at both ends of the load, so as to judge the connection status of the load and the resistance range of the load. When there is a load added, the load detection module will generate a "load" signal and feed it back to the MCU microcontroller, and then the MCU microcontroller will send a step-by-step increase output to the D/A conversion module through the data output port The control signal, and then increase the output step by step through the voltage amplification module and the voltage and current control module. When the output voltage or current reaches the preset value, the MCU microcontroller will stop increasing the output; when no load is added, the load detection module will Generate a "no load" signal and feed it back to the MCU microcontroller, so that the MCU microcontroller sends a corresponding output cut-off or pause signal. At this time, the voltage amplifying circuit will only output 12V and be in a standby state; when a load is added and the timing When the countdown reaches zero, the MCU microcontroller will send a control signal to the D/A conversion module to reduce the output step by step through the data output port, and then reduce the output step by step through the voltage amplification module and the voltage and current control module until zero. Through the above-mentioned control on the step-by-step increase or decrease of the output amplitude, the user will obtain a smooth and comfortable treatment experience.

As shown in FIG. 3, the pulse generator includes a structural shell A1, which is flat and rectangular and can be placed in a pocket, or ring-shaped as shown in FIG. 4 and can be worn on the wrist or arm through a Velcro strap. A2 is the power switch, A3 is the DC power input external interface, which is connected to a rechargeable lithium battery, A4 is the positive and negative terminals of the pulse current output terminal, and A5 is the Velcro strap to help A1 be worn on the body.

To sum up, the pulse generator described in this embodiment generates a pulse with a frequency between 0.2 Hz and 10 KHz. The duty cycle can be adjusted by setting the pulse wave, and then transmitted to the corresponding wearable soft gel electrode via the metal wire. Treat hyperhidrosis.

The specific implementation of the wearable soft gel electrode is described in detail as follows:

Embodiment 1 of wearable soft gel electrodes:

As shown in FIG. 8 , an APP-controlled wearable portable pulse antiperspirant device, the structure of the wearable soft gel electrode includes: two pieces of soft gel conductive electrodes P2 and two metal wires P1 connected thereto. The shape of the soft gel conductive electrode in Embodiment 1 is square or rectangular, and it is suitable for treating hand sweat, foot sweat, facial hyperhidrosis, and neck and back hyperhidrosis, and its size depends on the size of the hyperhidrosis site.

When an APP-controlled wearable portable pulse antiperspirant instrument is in use, the DC power supply of the pulse generator comes from an external rechargeable lithium battery, which is convenient for carrying around. After the two pieces of wearable soft gel electrodes are pasted on the sweaty parts of the body, turn on the power switch A2, establish a pairing relationship with the smart mobile device through Bluetooth settings, and then enter the antiperspirant through the setting and control of the smart mobile device APP treatment process.

A wearable and portable pulse antiperspirant device controlled by APP, which stimulates the synapses between the sweat sensory nerve and the sweat gland on the hyperhidrosis skin by generating a pulse current with an adjustable frequency between 0.2Hz and 10KHz. When the nerve synapses are stimulated to a certain extent by the pulse current, the sensitivity of the sweat glands is reduced, and they are no longer stimulated and excited, thus stopping sweating. This antiperspirant principle does not directly act on sweat glands, so it does not cause damage to human sweat glands.

Wearable soft gel electrode implementation mode two:

As shown in Figure 9, an APP-controlled wearable portable pulse antiperspirant instrument, the structure of the wearable soft gel electrode includes: two pieces of soft gel conductive electrodes N1 and two metal wires N2 connected thereto, Among them, the soft rubber conductive electrode is bent into an n-shape, and the soft fabric N3 with sponge or soft cloth in the middle is used to place the wearable soft rubber electrode bent into an n-shape at the armpit. The second embodiment can be The shape of the wearable soft gel electrode is suitable for treating underarm hyperhidrosis, and its use method is the same as that of the first embodiment of the wearable soft gel electrode.

Wearable soft gel electrode implementation mode three:

As shown in Figure 10, a wearable portable pulse antiperspirant device controlled by APP, the structure of the wearable soft gel electrode includes: two soft gel conductive electrodes F1 in the shape of a half-sheet mask and two electrodes connected to it. Metal wire F2, wherein when applying to the face, there must be a gap F3 between the two F1s so as to insulate the two F1s from each other. The shape of the soft conductive electrode in the third embodiment is suitable for treating hyperhidrosis on the face. The soft conductive electrode in the shape of a mask can be customized by 3D printing, and its use method is the same as that in the first embodiment of the soft conductive electrode.

Claims (8)

1. the wearable Portable pulse hidroschesis instrument that an APP controls, it is characterized in that: including: Intelligent mobile equipment APP and Portable pulse hidroschesis device, the circuit of Portable pulse hidroschesis device is made up of bluetooth communication module, pulse generator, wearable flexible glue electrode, and described Intelligent mobile equipment APP is connected by bluetooth communication module is wireless with pulse generator；Described pulse generator, including: DC voltage converting circuit, MCU microcontroller, pulse output control module and load detecting module, the input of described pulse output control module is connected with MCU micro controller data outfan, the control end of pulse output control module is connected with MCU microcontroller PWM end, the outfan of pulse output control module is connected with wearable flexible glue electrode, described MCU microcontroller is provided with load detecting module with the negative electricity interpolar of pulse output control module outfan, for detecting load interpolation state, thus carry out being incremented by the most step by step or control of successively decreasing to data output by MCU microcontroller；Pulse output control module, the power end of MCU microcontroller are connected with DC voltage converting circuit；Pulse generator output frequency is the adjustable impulse wave of adjustable pulse duty cycle between 0.2Hz ~ 10KHz.

The wearable Portable pulse hidroschesis instrument that a kind of APP the most according to claim 1 controls, it is characterized in that: described Portable pulse hidroschesis device is that flat, rectangular can be positioned over the housing A1 of card form structure in pocket, it is provided with on and off switch A2, DC supply input interface A3, pulse current output interface A4 in card form structure, and is connected with the circuit in card form housing.

The wearable Portable pulse hidroschesis instrument that a kind of APP the most according to claim 1 controls, it is characterized in that: the structure of described Portable pulse hidroschesis device is the wrist type structure being worn on wrist or arm, wrist type structure is connected and composed with nylon fastener belt A5 by the circulus housing A1 of opening, it is provided with on and off switch A2, DC supply input interface A3, pulse current output interface A4 on the circulus body A1 of opening, and is connected with the circuit in the circulus housing of opening.

The wearable Portable pulse hidroschesis instrument that a kind of APP the most according to claim 1 controls, it is characterized in that: on the touch screen of described Intelligent mobile equipment APP, be provided with APP interface, APP interface is provided with the pulse frequency of correspondence, pulse duty cycle, voltage, electric current, " the plus/minus button ", " settings button " of therapentic part of time；Glittering and the sound that rings of the display and " reset button ", pressure-limit current-limit that are provided with the accumulative total time of correspondence on APP interface is reported to the police；Be provided with the functional part settings button of correspondence on APP interface, bluetooth communication is arranged and " ACK button ".

The wearable Portable pulse hidroschesis instrument that a kind of APP the most according to claim 1 controls, it is characterized in that: described bluetooth communication module, it is the communication module between Intelligent mobile equipment and pulse generator, via this module, the instruction that Intelligent mobile equipment APP sends is transferred to MCU microprocessor and is transferred to pulse-generator circuit after MCU microprocessor processes；Meanwhile, MCU microprocessor also passes to Intelligent mobile equipment APP real-time pulse voltage, pulse current, single working time and load state information by bluetooth communication module.

The wearable Portable pulse hidroschesis instrument that a kind of APP the most according to claim 1 controls, it is characterized in that: the DC voltage converting circuit of described pulse generator includes DC-DC booster circuit and DC-DC reduction voltage circuit, DC-DC booster circuit outfan is connected with pulse output control module, and DC-DC reduction voltage circuit outfan is connected with the power end of MCU microcontroller, bluetooth communication module；The signal input part of described MCU microcontroller is connected for receiving key-press input value with key switch, the signal output part of MCU microcontroller is connected with information display device for the A/D of output display information, MCU microcontroller detects that input receives the current sampling data of current sample module, MCU microcontroller is input to voltage amplification module by its data-out port via D/A modular converter by its PWM (pulsewidth modulation) port controlling PWM control module, MCU microcontroller.

The wearable Portable pulse hidroschesis instrument that a kind of APP the most according to claim 4 controls, it is characterized in that: described pulse output control module, including: D/A modular converter, voltage amplification module, voltage x current control module, current sample module, PWM control module and resettable fuse；The output valve of described D/A modular converter is connected with the control end of voltage x current control module as the input of voltage amplification module, the outfan of voltage amplification module, the input of described voltage x current control module is connected with DC-DC booster circuit outfan, the input of DC-DC booster circuit is connected with DC voltage input, and described DC supply input is chargeable lithium cell；The outfan of voltage x current control module is connected with PWM control module；PWM control module is connected with wearable flexible glue electrode via resettable fuse；Described current sample module is connected with the negative electrode of wearable flexible glue electrode, and current sampling data feeds back to the A/D test side of MCU microcontroller.

The wearable Portable pulse hidroschesis instrument that a kind of APP the most according to claim 1 controls, it is characterized in that: the structure of described flexible glue conductive electrode, including: two panels flexible glue conductive electrode and coupled two plain conductors, wherein, the shape of flexible glue conductive electrode include square, rectangle, inside it in the middle of fill out the facial film shape hollowed out at the bending n shape of pad soft fabric and eye nose mouth.