CN115531720A - Skin physical therapy device, equipment and parameter adjusting method thereof - Google Patents

Abstract

The present disclosure provides a skin physiotherapy apparatus, a device and a parameter adjustment method thereof, the apparatus including: the skin physiotherapy device comprises a first identification module, a second identification module, a conversion module and an output module, wherein the first identification module receives regulation and control information and identifies selection information and basic intensity information, the second identification module selects a working mode and identifies information components, the conversion module obtains intensity parameters, and the output module carries out physiotherapy on skin. The apparatus comprises: the controller selects the working mode and identifies the information component, and the working device obtains the intensity parameter and carries out physical therapy on the skin. The method comprises the following steps: and receiving the regulation and control information, identifying the selection information and the basic strength information in the regulation and control information, identifying the working mode and the information component, obtaining the strength parameter and carrying out physical therapy on the skin. Therefore, the skin physical therapy device and equipment which can simultaneously regulate and control parameters when responding in a multifunctional mode and the parameter regulation method thereof can be obtained.

Description

Skin physical therapy device, equipment and parameter adjusting method thereof

Technical Field

The disclosure relates to the field of medical instruments, in particular to a skin physiotherapy device, equipment and a parameter adjusting method thereof.

Background

With the increasing demand of beauty-seeking people and patients with skin diseases, the field of medical science and the art of medical science gradually appears intelligent and automatic emerging transdermal drug delivery technology, such as an electron beam water light technology. Compared with the traditional needle transdermal injection technology, the emerging transdermal drug delivery technology does not need a needle, and a single type of current is applied to the skin to change the structure of the cutin and generate reversible hydrophilic 'electric pores' so as to increase the transdermal permeability of macromolecular drugs.

There are only a single type of current-responsive mode of the emerging transdermal drug delivery technology available. Clinical experience shows that a single type of current-assisted heating, mechanical vibration and other treatments and a plurality of current mixing and superposing introduction modes are more beneficial to the percutaneous permeability of the emerging drug delivery technology. The existing physiotherapy device can not regulate and control various parameters such as various types of current electrotherapy, heating, vibration and the like.

Disclosure of Invention

The present disclosure has been made in view of the above-mentioned state of the art, and an object thereof is to provide a skin treatment apparatus and device capable of responding in a multifunctional mode and also performing parameter control, and a parameter adjustment method thereof.

To this end, a first aspect of the present disclosure provides a parameter adjustment method of a skin treatment apparatus, including: receiving regulation and control information, and identifying selection information and basic strength information in the regulation and control information; identifying a working mode based on the selection information and identifying an information component in the base strength information based on the working mode; obtaining an intensity parameter based on the information component and performing physical therapy on the skin based on the intensity parameter. In this case, selection information and basic intensity information in the regulation information are recognized, a working mode is selected based on the selection information, and parameters of the skin treatment apparatus are regulated based on the basic intensity information, thereby enabling the skin treatment apparatus to simultaneously perform various parameter regulation and control using the multi-functional mode combination therapy.

According to the parameter adjustment method of the present disclosure, optionally, if the working mode is a superimposed wave mode, whether the information component includes a conductance intensity information component and a heating intensity information component is identified. In this case, the operation mode of the skin therapy apparatus can be adjusted to the superimposed wave mode, and the operation parameters in the superimposed wave mode can be adjusted based on the electrical conduction strength information component and the heating strength information component.

According to the parameter adjustment method related to the present disclosure, optionally, if the information component includes the conductance intensity information component and does not include the heating intensity information component, obtaining a conductance intensity parameter based on the conductance intensity information component, obtaining an overlap wave intensity quantity based on the conductance intensity parameter, and performing electrical therapy on the skin based on the overlap wave intensity quantity. In this case, the skin treatment apparatus can be made to perform electrical treatment on the skin using a superimposed wave microcurrent of a specific intensity in a superimposed wave mode.

According to the parameter adjustment method related to the present disclosure, optionally, if the information component includes the electrical conductivity intensity information component and the heating intensity information component, obtaining an electrical conductivity intensity parameter based on the electrical conductivity intensity information component and obtaining a heating intensity parameter based on the heating intensity information component, obtaining a superimposed wave intensity quantity based on the electrical conductivity intensity parameter and performing electrical therapy on the skin based on the superimposed wave intensity quantity, and performing thermal therapy on the skin based on the heating intensity parameter. In this case, it is possible to enable the skin treatment apparatus to perform electric treatment on the skin using the superimposed wave micro-current of a specific strength in the superimposed wave mode while performing thermal treatment on the skin using the thermal energy of a specific strength.

According to the parameter adjustment method related to the present disclosure, optionally, if the working mode is a square wave mode, whether the information component includes a basic intensity information component or not is identified, and whether the regulation information includes a vibration intensity parameter or not is identified. In this case, the operation mode of the skin treatment apparatus can be adjusted to the square wave mode, and the operation parameter in the square wave mode can be adjusted based on the basic intensity information component and the vibration intensity parameter.

According to the parameter adjustment method related to the present disclosure, optionally, if the information component includes the basic intensity information component and the adjustment information does not include the vibration intensity parameter, obtaining a basic intensity parameter based on the basic intensity information component, obtaining a square wave intensity value based on the basic intensity parameter, and performing electrical therapy on the skin based on the square wave intensity value. In this case, it is possible to enable the skin treatment apparatus to electrically treat the skin using square wave micro-current of a certain intensity in a square wave mode.

According to the parameter adjustment method related to the present disclosure, optionally, if the information component includes the basic intensity information component and the regulation information includes the vibration intensity parameter, obtaining the basic intensity parameter based on the basic intensity information component and obtaining a square wave intensity value based on the basic intensity parameter, performing electrical therapy on the skin based on the square wave intensity value, and performing mechanical therapy on the skin based on the vibration intensity parameter. In this case, it is possible to enable the skin treatment apparatus to perform electrical treatment on the skin using square wave micro-current of a specific intensity while performing mechanical treatment on the skin using kinetic energy of a specific intensity in a square wave mode.

According to the parameter adjustment method related in the present disclosure, optionally, the method further includes: generating feedback information based on the working mode and identifying the basic strength information based on the feedback information. Under the condition, the accuracy of the skin physiotherapy device in selecting the working mode can be improved through the feedback information, and the accuracy of the skin physiotherapy device in adjusting the working parameters is further improved.

A second aspect of the present disclosure provides a skin physiotherapy apparatus, including a first identification module, a second identification module, a conversion module, and an output module, where the first identification module receives regulation and control information and identifies selection information and basic intensity information in the regulation and control information, the second identification module selects a working mode of the output module based on the selection information in the regulation and control information and identifies an information component in the basic intensity information based on the selected working mode, and the conversion module obtains an intensity parameter based on the information component; the output module performs physical therapy on the skin based on the intensity parameter. In this case, the skin treatment apparatus can respond to a plurality of operation modes through the first recognition module, the second recognition module and the conversion module, select at least one of the operation modes and adjust parameters at the same time, and then output treatment through the output module.

According to the skin physiotherapy apparatus related to the present disclosure, optionally, if the operation mode is a superimposed wave mode, the second identification module identifies whether the information component includes a conductance intensity information component and a heating intensity information component, if the information component includes the conductance intensity information component and does not include the heating intensity information component, the conversion module obtains a conductance intensity parameter based on the conductance intensity information component and obtains a superimposed wave intensity value based on the conductance intensity parameter, and the output module performs physiotherapy on the skin based on the superimposed wave intensity value; if the information component comprises the electric conduction strength information component and the heating strength information component, the conversion module obtains an electric conduction strength parameter based on the electric conduction strength information component, obtains a heating strength parameter based on the heating strength information component, obtains a superposed wave strength quantity based on the electric conduction strength parameter, and the output module performs electric physical therapy on the skin based on the superposed wave strength quantity and performs thermal physical therapy on the skin based on the heating strength parameter. In this case, the skin treatment apparatus can perform electric treatment on the skin through the output module using the superimposed wave micro-current of specific strength in the superimposed wave mode, or perform electric treatment and thermal treatment on the skin through the output module using the superimposed wave micro-current and thermal energy of specific strength simultaneously in the superimposed wave mode.

According to the skin physiotherapy apparatus related to the present disclosure, optionally, if the working mode is a square wave mode, the second identification module identifies whether the information component includes a basic intensity information component, and the regulation information includes a vibration intensity parameter, if the information component includes the basic intensity information component and the regulation information does not include the vibration intensity parameter, the conversion module obtains a basic intensity parameter based on the basic intensity information component and obtains a square wave intensity value based on the basic intensity parameter, and the output module performs an electric physiotherapy on the skin based on the square wave intensity value; if the information component comprises the basic strength information component and the regulation and control information comprises the vibration strength parameter, the conversion module obtains the basic strength parameter based on the basic strength information component and obtains the square wave strength based on the basic strength parameter, and the output module carries out electric physical therapy on the skin based on the square wave strength and carries out mechanical physical therapy on the skin based on the vibration strength parameter. In this case, the skin treatment apparatus can perform electrical treatment on the skin through the output module using square wave micro-current of a specific strength in a square wave mode, or perform electrical treatment and mechanical treatment on the skin through the output module using both square wave micro-current of a specific strength and kinetic energy in a square wave mode.

A third aspect of the present disclosure provides a skin physiotherapy apparatus including a controller and a working device, the controller receiving regulation information and recognizing selection information and basic intensity information in the regulation information, the controller selecting a working mode of the working device based on the selection information in the regulation information and recognizing an information component in the basic intensity information based on the selected working mode, the working device obtaining an intensity parameter based on a recognition result of the controller, the working device performing physiotherapy on skin based on the intensity parameter. In this case, at least one of the plurality of operation modes may be selected by the controller and parameter adjustment may be simultaneously performed, thereby performing physical therapy on the skin of the human body through the operation device.

According to the skin treatment apparatus to which the present disclosure relates, optionally, the working device includes a waveform generator, a heating component that outputs thermal energy, a superimposed wave microcurrent generation component that outputs a superimposed wave microcurrent, a square wave microcurrent generation component that outputs a square wave microcurrent, and a vibration component that outputs mechanical energy. Under the condition, the heating component generates heat energy with specific strength to carry out thermal physical therapy on the skin, the superposed wave micro-current generating component generates superposed wave micro-current with specific strength to carry out electrical physical therapy on the skin, the square wave micro-current generating component generates square wave micro-current with specific strength to carry out electrical physical therapy on the skin, and the vibrating component generates kinetic energy with specific strength to carry out mechanical physical therapy on the skin.

According to the skin physiotherapy apparatus related to the present disclosure, optionally, if the operation mode is a superimposed wave mode, the controller identifies whether the information component includes a conductance intensity information component and a heating intensity information component, and if the information component includes the conductance intensity information component and does not include the heating intensity information component, the operation device obtains a conductance intensity parameter based on the conductance intensity information component and obtains a superimposed wave intensity quantity based on the conductance intensity parameter, and outputs a superimposed wave microcurrent to the skin based on the superimposed wave intensity quantity; if the information component comprises the conductance intensity information component and the heating intensity information component, the working device obtains a conductance intensity parameter based on the conductance intensity information component, obtains a heating intensity parameter based on the heating intensity information component, obtains a superposed wave intensity quantity based on the conductance intensity parameter, outputs a superposed wave micro-current to the skin based on the superposed wave intensity quantity, and outputs heat energy to the skin based on the heating intensity parameter. In this case, it is possible to select the operation mode of the superimposed wave by the controller and to perform the electro-physical therapy on the skin by generating the superimposed wave micro-current of a specific intensity through the operation device, or to generate the superimposed wave micro-current of a specific intensity and to generate the thermal energy of a specific intensity through the operation device to simultaneously perform the electro-physical therapy and the thermal therapy on the skin.

According to the skin physiotherapy apparatus related to the present disclosure, optionally, if the working mode is a square wave mode, identifying whether the information component includes a basic intensity information component and the regulation information includes a vibration intensity parameter, if the information component includes the basic intensity information component and the regulation information does not include the vibration intensity parameter, the working device obtains a basic intensity parameter based on the basic intensity information component and obtains a square wave intensity value based on the basic intensity parameter, and outputs a square wave microcurrent to the skin based on the square wave intensity value; if the information component comprises the basic strength information component and the regulation and control information comprises the vibration strength parameter, the working device obtains a basic strength parameter based on the basic strength information component, obtains a square wave strength quantity based on the basic strength parameter, outputs square wave microcurrent to the skin based on the square wave strength quantity, and outputs mechanical energy to the skin based on the vibration strength parameter. In this case, the square wave operation mode can be selected by the controller, and the square wave micro-current of a specific strength is generated by the operation device to perform the electrical therapy on the skin, or the square wave micro-current of a specific strength is generated by the operation device to generate the kinetic energy of a specific strength to simultaneously perform the electrical therapy and the mechanical therapy on the skin.

According to the three aspects of the disclosure, a skin treatment device, an apparatus and a parameter adjusting method thereof capable of responding in a multifunctional mode and simultaneously performing parameter regulation and control can be provided.

Drawings

Fig. 1 is a schematic view showing an application scenario of a skin treatment apparatus according to an example of the present disclosure.

Fig. 2 is a flowchart illustrating a parameter adjustment method of a skin treatment apparatus according to an example of the present disclosure.

Fig. 3 is a flowchart illustrating a parameter adjustment method of a skin treatment apparatus according to another example of the present disclosure.

Fig. 4 is a schematic diagram showing a structure and a signal relationship of a skin treatment apparatus according to an example of the present disclosure.

Fig. 5 is a schematic diagram illustrating a structure and signal relationship of a skin treatment apparatus according to another example of the present disclosure.

Fig. 6 is a block diagram showing a general structure of a skin treatment apparatus according to an example of the present disclosure.

Fig. 7 is a block diagram showing a structure of a skin treatment apparatus according to an example of the present disclosure.

Fig. 8 is a block diagram showing a structure of a heating assembly according to an example of the present disclosure.

Fig. 9 is a block diagram showing a structure of a vibration component according to an example of the present disclosure.

Fig. 10 is a block diagram showing a structure of a superimposed wave microcurrent generation module according to an example of the present disclosure.

Fig. 11 is a block diagram illustrating a square wave micro-current generating assembly according to an example of the present disclosure.

Fig. 12 is a schematic diagram showing a structure and signal relationship of a skin treatment apparatus according to another example of the present disclosure.

Description of reference numerals:

1 … … skin physiotherapy device, 11 … … first identification module, 12 … … second identification module, 13 … … conversion module, 14 … … output module, 15 … … feedback module,

2 … … skin treatment device, 21 … … controller, 22 … … working device, 211 … … IO port, 212 … … main controller, 213 … … control switch, 221 … … heating component, 222 … … vibration component, 224 … … superposition wave micro current generation component, 225 … … square wave micro current generation component, 226 … … selection switch, 227 … … waveform generator, 228 … … hand tool, 229 … … electrode sheet, 2211 … … heating regulator, 2212 … … heater, 2221 zxft 3734 vibration regulator, 2 … … vibrator, 5852 zxft 3575 vibration regulator, 3575 intermediate frequency feedback vibrator.

Detailed Description

The technical solutions in the embodiments of the present disclosure will be clearly and completely described below with reference to the drawings in the embodiments of the present disclosure, and it is obvious that the described embodiments are only a part of the embodiments of the present disclosure, and not all of the embodiments. All other embodiments, which can be filled by a person with ordinary skill in the art without any creative effort based on the embodiments in the present disclosure, belong to the protection scope of the present disclosure.

It should be noted that the terms "first," "second," "third," and "fourth," etc. in the description and claims of the present disclosure and in the above-described drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus. In the following description, the same components are denoted by the same reference numerals, and redundant description thereof is omitted. The drawings are schematic and the ratio of the dimensions of the components and the shapes of the components may be different from the actual ones.

The present disclosure relates to a skin physiotherapy apparatus, a device, and a parameter adjustment method thereof. Fig. 1 shows an application scenario of a skin treatment device according to an example of the present disclosure. In some examples, the skin treatment may be divided into a plurality of operation modes to implement the corresponding treatment. As shown in fig. 1, the first, second, and third modes … … N, etc., the basic functions constituting each operation mode may include changing the temperature of the skin, applying an electrical signal to the skin to introduce a liquid, and applying mechanical vibration to the skin, etc., and at least two functions are included in each operation mode, and the kind of the functions is not limited to the foregoing.

To this end, an aspect of the present disclosure first provides a parameter adjustment method of a skin treatment apparatus. For convenience of description, the "parameter adjustment method of the skin treatment apparatus" may be sometimes referred to as "parameter adjustment method", "adjustment method", or "method".

Fig. 2 is a flowchart illustrating a parameter adjustment method of a skin treatment apparatus according to an example of the present disclosure.

In some examples, as shown in fig. 2, a method may include: receiving regulation and control information, and identifying selection information and basic strength information in the regulation and control information (S100); identifying an operation mode based on the selection information and identifying an information component in the base strength information based on the operation mode (S200); intensity parameters are obtained based on the information components and physical therapy is performed on the skin based on the intensity parameters (S300).

In the parameter adjustment method according to the present disclosure, selection information and basic intensity information in the regulation information are identified, the operation mode is selected based on the selection information, and the parameter of the skin treatment apparatus is regulated based on the basic intensity information, whereby the skin treatment apparatus can respond in the multifunctional mode while the parameter regulation is performed.

In some examples, the regulatory information may include selection information and base strength information. In an optional scene, a user inputs regulation and control information through the interaction device to set a working mode and treatment intensity in the mode, the selection information corresponds to the selection of the working mode, and the basic intensity information corresponds to the setting of the treatment intensity in the mode. There are a variety of alternative modes of operation, any of which may include two or more functions including, but not limited to, changing the temperature of the skin, applying an electrical signal to the skin to introduce a fluid, applying a mechanical shock to the skin, etc. For the intensity of treatment in the mode, the user can input a specific numerical value of a certain intensity; alternatively, the user-acceptable intensity range may be pre-classified into certain classes, and after a certain class is selected by the user, the adaptive value fluctuates within the value of the class range to treat.

Optionally, the basic strength information is embodied as a strength value of each function in the working mode, or is embodied as a variation sequence of each value within a corresponding range of a strength level corresponding to each function in the working mode. For example, if a certain operation mode includes a function one and a function two, the basic strength information is represented as a strength value of the function one and a strength value of the function two.

In some examples, since at least two functions are included in any of the operation modes, the intensity of at least two functions is included in the basic intensity information, and then the intensity corresponding to each function is represented as an information component, for example, the basic intensity information includes a first information component and a second information component, the first information component corresponds to the intensity of the first function, and the second information component corresponds to the intensity of the second function. For another example, the basic strength information includes a first information component, a second information component, and a third information component, where the first information component corresponds to the strength of function one, the second information component corresponds to the strength of function two, and the third information component corresponds to the strength of function three, etc.

In some examples, the categories of the information components may include, but are not limited to, a conductance intensity information component, a heating intensity information component, a base intensity information component; in other examples, the category of the information component may also include a vibration intensity information component. Alternatively, the information component may comprise only the conductance intensity information component; alternatively, the information component may include both the conductance intensity information component and the heating intensity information component; alternatively, the information component may comprise only the base intensity information component; alternatively, the information component may include both the base intensity information component and the vibration intensity information component; alternatively, if the information component includes only the conductivity intensity information component, the corresponding quantity of the function of controlling the vibration intensity may be directly embodied as the vibration intensity parameter.

In some examples, for the operational mode, the first and second names may be used according to some ordering rule. Alternatively, the operation modes may be named according to the kind of information component, such as heating mode, vibration mode. Alternatively, nomenclature can be used according to the type of current applied to the skin, such as square wave patterns, superimposed wave patterns, and the like. Different types of working modes can preset corresponding types of selection information for subsequent identification.

Alternatively, the selection information may be embodied as an identifier, with different selection information corresponding to different identifiers. In some examples, for example, if the selection information is identifier one, then it corresponds to a first mode of operation; if the selected information is the identifier II, the selected information corresponds to a second working mode; if the selection information is the identifier three, the selection information corresponds to a third working mode; if the selection information is the identifier four, the selection information corresponds to a fourth working mode; and if the selection information is the identifier five, the selection information corresponds to a fifth working mode. If the selection information is of type one, corresponding to a first working mode; and if the selection information is of type two, corresponding to a second working mode. If the selection information is a mark one, corresponding to the superposition wave working mode; and if the selection information is the second mark, the square wave working mode is corresponding to. If the selection information is a mark one, corresponding to the square wave working mode; if the selection information is the second mark, corresponding to the first superposed wave working mode; if the selection information is the mark three, corresponding to the second superposed wave working mode; if the selection information is the mark four, corresponding to the superposed wave three working mode; if the selection information is the mark five, the corresponding superposed wave four working modes are obtained, and the like.

And after the working mode is determined, identifying an information component corresponding to the corresponding function in the mode in the basic strength information. As can be understood by those skilled in the art, different working modes are pre-mapped with corresponding functions, and when a certain working mode is identified, whether corresponding information components exist in the received basic strength information is searched according to the pre-mapped function. For example, if a mode-to-heating-and-superimposed-wave-conductance function is preset, when the received selection information corresponds to a mode one, whether a heating intensity information component and a superimposed-wave-conductance intensity information component exist in the base intensity information is searched for to identify the information component in the base intensity information.

In some examples, the selected information, the information component, is a digital signal, the intensity parameter is a converted analog signal, and after obtaining the intensity parameter, the skin is treated.

It will be appreciated by those skilled in the art that the intensity parameter in some examples is a reference to the intensity of the electrical signal applied to the skin of the human body.

In some examples, if the operating mode is a superimposed wave mode, it may be identified whether the information component includes a conductance intensity information component and a heating intensity information component. In this case, if the operation mode is adjusted to the superimposed wave mode, the operation parameter in the superimposed wave mode can be adjusted based on the electric conductivity intensity information component and the heating intensity information component.

In some examples, the function in the superimposed wave mode includes applying an electrical signal to the skin; in some examples, the function in the superimposed wave mode includes applying an electrical signal to the skin, causing the skin to change temperature. It should be noted that the electrical signal mentioned in this example is a multi-type current, and the current is modulated by superimposing two or more waveforms. Alternatively, the waveform may include a sine wave, a triangular wave, a sawtooth wave, a square wave, a staircase wave, and the like.

In some examples, if the information component includes a conductance intensity information component and does not include a thermal intensity information component, the conductance intensity parameter may be obtained based on the conductance intensity information component. In some examples, further, an overlay wave strength amount may be obtained based on the conductance intensity parameter and the electrical therapy may be performed on the skin based on the overlay wave strength amount. In this case, it is possible to electrically perform physical therapy on the skin using a superimposed wave micro-current of a certain intensity in a superimposed wave mode.

In some examples, the information component is a digital signal, whereupon the conductance intensity information component is a digital signal. In some examples, the conductance intensity information component is converted from a digital signal to an analog signal to obtain the conductance intensity parameter.

In some examples, the intensity parameter is converted into an intensity quantity, and the conversion may include signal amplification and the like. For example, the conductance intensity parameter is amplified to obtain a superimposed wave intensity amount.

In some examples, the intensity parameter may be first subjected to voltage stabilization and then converted into the intensity quantity. For example, the conductance intensity parameter is subjected to voltage stabilization processing and then converted into a superimposed wave intensity quantity.

In some examples, if the information component includes a conductance intensity information component and a heating intensity information component, the conductance intensity parameter may be obtained based on the conductance intensity information component and the heating intensity parameter may be obtained based on the heating intensity information component. In some examples, further, an overlay wave strength amount may be obtained based on the conductance intensity parameter and the electrical therapy may be performed on the skin based on the overlay wave strength amount. In some examples, further, thermal treatment of the skin may be performed based on the heating intensity parameter. In this case, it is possible to perform the electrical therapy on the skin using the superimposed wave micro-current of a specific intensity in the superimposed wave mode while performing the thermal therapy on the skin using the thermal energy of a specific intensity.

In some examples, the information component is a digital signal, and the information component is subjected to digital-to-analog conversion to obtain the intensity parameter. In some examples, the digital signal conductance intensity information component is subjected to digital-to-analog conversion to obtain an analog signal conductance intensity parameter. In some examples, the digital signal heating intensity information component is digital-to-analog converted to obtain an analog signal heating intensity parameter.

In some examples, the heating intensity parameter may be stabilized after being obtained and then output.

In some examples, if the operation mode is a square wave mode, it may be identified whether the information component includes a basic intensity information component, and whether the regulation information includes a vibration intensity parameter. In this case, if the operation mode is the square wave mode, the operation parameter in the square wave mode can be adjusted based on the basic intensity information component and the vibration intensity parameter.

In some examples, the function of the square wave pattern includes applying an electrical signal to the skin; in some examples, the function of the square wave pattern includes applying an electrical signal to the skin, applying mechanical vibration to the skin.

In some examples, if the information component includes a base intensity information component and the regulatory information does not include the vibration intensity parameter, the base intensity parameter may be obtained based on the base intensity information component. In some examples, further, a square wave intensity amount may be obtained based on the base intensity parameter and the electrophysical therapy may be performed on the skin based on the square wave intensity amount. In this case, it is possible to electrically treat the skin using square wave micro-current of a certain intensity in a square wave pattern.

In some examples, the information component is a digital signal, and the information component is subjected to digital-to-analog conversion to obtain the intensity parameter. For example, the basic intensity information component is subjected to digital-to-analog conversion to obtain a basic intensity parameter.

In some examples, the intensity parameter is converted into an intensity quantity, and the conversion may include signal amplification and the like. For example, the basic intensity parameter is amplified to obtain the square wave intensity.

In some examples, the intensity parameter may be stabilized after being obtained and then converted into the intensity quantity. For example, the square wave intensity parameter is subjected to voltage stabilization and then converted into a square wave intensity value.

It will be appreciated by those skilled in the art that in some cases, the analog signal may be obtained directly from the regulatory information, for example, the amount of vibration intensity may be obtained directly from the regulatory information.

In some examples, if the information component includes a base intensity information component and the modulation information includes a vibration intensity parameter, a base intensity parameter may be obtained based on the base intensity information component and a square wave intensity amount may be obtained based on the base intensity parameter. In some examples, further, the skin may be electrically treated based on the square wave intensity amount, and the skin may be mechanically treated based on the vibration intensity parameter. In this case, it is possible to perform an electrical therapy on the skin using square wave micro-current of a specific intensity in a square wave mode while performing a mechanical therapy on the skin using kinetic energy of a specific intensity.

In some examples, the vibration intensity amount may be stabilized and then output.

Fig. 3 is a flowchart illustrating a parameter adjustment method of a skin treatment apparatus according to another example of the present disclosure.

In some examples, as shown in fig. 3, a method may include: receiving regulation and control information and identifying selection information and basic strength information in the regulation and control information (S101); generating feedback information based on the working mode and identifying the basic strength information based on the feedback information (S201); identifying an operation mode based on the selection information and identifying an information component in the base strength information based on the operation mode (S301); intensity parameters are obtained based on the information components and physical therapy is performed on the skin based on the intensity parameters (S401). Under the condition, the accuracy of the skin physiotherapy device in selecting the working mode can be improved through the feedback information, and the accuracy of the skin physiotherapy device in adjusting the working parameters is further improved.

As can be understood by those skilled in the art, in the skin treatment process, the output electrical signal acting on the skin needs to be conducted to the skin through the conducting component, and the conducting component is generally connected to the output port of the electrical signal in a plug-in manner, so as to achieve the effect of moving the skin surface for treatment. In some examples, to ensure the conduction reliability of the conducting component, the feedback information may include connection condition information of the conducting component in the corresponding mode, and the connection condition may include connection, disconnection, contact failure, and the like.

In some examples, if the feedback information includes that the conductive member in the corresponding mode is open or not in actual contact, the identification of the information component is stopped, and warning information is output.

In some examples, the feedback information may include skin feedback information after the amount of intensity has acted on the skin. Optionally, after the operation mode is identified, the basic intensity information may be corrected based on the feedback information, for example, the basic intensity information may be corrected based on the impedance information of the skin of the human body in the feedback information, so that the treatment effect of the skin treatment apparatus can be improved.

In some examples, the regulatory information may be input by an operator of the skin treatment device prior to performing the operation. In some examples, the regulation information input by the operator may include at least one of selection information and basic intensity information to make the skin treatment apparatus work after initialization.

A second aspect of the present disclosure provides a skin treatment device. In some examples, for convenience of description, the following "skin treatment device" may sometimes also be referred to as "treatment device" or "device". Fig. 4 is a schematic diagram showing the structure and signal relationship of the skin therapy apparatus 1 according to the example of the present disclosure.

In some examples, the skin treatment device 1 may comprise: a first recognition module 11, a second recognition module 12, a conversion module 13 and an output module 14.

In some examples, first identification module 11 may receive regulatory information and identify selection information and base strength information in the regulatory information.

In some examples, second identification module 12 may select an operating mode of output module 14 based on selection information in the regulatory information and may identify an information component in the base strength information based on the selected operating mode.

In some examples, the translation module 13 may obtain the intensity parameter based on the information component. In some examples, the output module 14 may apply a treatment to the skin based on the intensity parameter.

In the skin treatment apparatus 1 according to the present disclosure, at least one of the plurality of operation modes can be selected and parameter adjustment can be performed simultaneously by the first recognition module 11, the second recognition module 12, and the conversion module 13 in response to the plurality of operation modes, and output treatment can be performed by the output module 14.

In some examples, if the operating mode is a superimposed wave mode, the second identification module 12 may identify whether the information components include a conductance intensity information component and a heating intensity information component. In some examples, further, if the information component includes the conductance intensity information component and does not include the heating intensity information component, the conversion module 13 may obtain the conductance intensity parameter based on the conductance intensity information component. In some examples, further, the transforming module 13 may obtain an intensity of the superimposed wave based on the conductance intensity parameter, and the output module 14 performs the electrical therapy on the skin based on the intensity of the superimposed wave. In this case, the skin treatment apparatus 1 can electrically treat the skin through the output module 14 using a superimposed wave micro-current of a certain intensity in a superimposed wave mode.

In some examples, if the operating mode is a superimposed wave mode, the second identification module 12 may identify whether the information components include a conductance intensity information component and a heating intensity information component. In some examples, further, if the information component includes a conductance intensity information component and a heating intensity information component, the transformation module 13 may obtain the conductance intensity parameter based on the conductance intensity information component and may obtain the heating intensity parameter based on the heating intensity information component. In some examples, further, the conversion module 13 may obtain a superimposed wave intensity amount based on the electrical conductivity intensity parameter, and the output module 14 performs electrical therapy treatment on the skin based on the superimposed wave intensity amount and thermal therapy treatment on the skin based on the heating intensity parameter. In this case, it is possible to simultaneously perform electrical and thermal therapies on the skin through the output module 14 using a superimposed wave micro-current and thermal energy of a specific intensity in the superimposed wave mode.

In some examples, if the operating mode is a square wave mode, second identification module 12 may identify whether the information component includes a base intensity information component and identify whether the regulatory information includes a vibration intensity parameter. In some examples, further, if the information component includes a basic intensity information component and the regulation information does not include the vibration intensity parameter, the transformation module 13 may obtain the basic intensity parameter based on the basic intensity information component. In some examples, further, the transforming module 13 obtains an intensity amount of the square wave based on the basic intensity parameter, and the output module 14 performs the electrical therapy on the skin based on the intensity amount of the square wave. In this case, the skin can be electrically treated with a square wave micro-current of a certain intensity in a square wave pattern through the output module 14.

In some examples, if the operating mode is a square wave mode, second identification module 12 may identify whether the information component includes a base intensity information component and identify whether the regulatory information includes a vibration intensity parameter. In some examples, further, if the information component includes a basic strength information component and the control information includes a vibration strength parameter, the transformation module 13 may obtain the basic strength parameter based on the basic strength information component, and the transformation module 13 may obtain the square wave strength amount based on the basic strength parameter. In some examples, further, output module 14 applies electrical therapy to the skin based on the square wave intensity quantity and applies mechanical therapy to the skin based on the vibration intensity parameter. In this case, it is possible to perform electrical and mechanical therapies on the skin through the output module 14 using square wave micro-current and kinetic energy of a specific intensity simultaneously in a square wave mode.

In some examples, the operating mode may include a plurality of modes, such as a superimposed wave mode or a square wave mode. In some examples, any one mode of operation may include two or more functions including, but not limited to, causing the skin to change temperature, applying an electrical signal to the skin to introduce a liquid, applying mechanical shock to the skin, etc., e.g., a function in a superimposed wave mode may include applying an electrical signal to the skin, and a function in a superimposed wave mode may also include applying an electrical signal to the skin, causing the skin to change temperature; the function of the square wave pattern may comprise applying an electrical signal to the skin, and the function of the square wave pattern may also comprise applying an electrical signal to the skin, applying mechanical vibrations to the skin. In some examples, the first and second designations may be based on certain ordering rules. Alternatively, the operation modes may be named according to the kind of information component, such as heating mode, vibration mode. Alternatively, nomenclature can be used according to the type of current applied to the skin, such as square wave patterns, superimposed wave patterns, and the like. Different types of working modes can preset corresponding types of selection information for subsequent identification. In this case, the plurality of operation modes or function modes can satisfy the demand that people hope to obtain more physical therapy effects through less times of skin physical therapy.

Fig. 5 is a schematic diagram showing the structure and signal relationship of a skin treatment apparatus 1 according to another example of the present disclosure. As shown in fig. 5, in some examples, the skin treatment device 1 may further comprise a feedback module 15. In some examples, feedback module 15 may generate feedback information based on the operating mode and may send the feedback information to second identification module 12, and second identification module 12 may identify the base strength information based on the feedback information. In this case, the degree of intelligence of the skin treatment apparatus 1 can be improved by the feedback information.

In some examples, the feedback module 15 may generate feedback information based on impedance information of the skin of the human body, and may transmit the feedback information to the second recognition module 12, and then the second recognition module 12 may correct the basic strength information based on the feedback information, thereby being capable of improving the physical therapy effect of the skin physical therapy device 1.

In an optional scenario, the user may set the operation mode and the treatment intensity in the mode, the selection information corresponds to the selection of the operation mode, and the basic intensity information corresponds to the setting of the treatment intensity in the mode. For example, for the intensity of treatment in a mode, the user may enter a specific numerical value for a certain intensity. Alternatively, the user-acceptable intensity range may be pre-classified into certain classes, and after a certain class is selected by the user, the adaptive value fluctuates within the value of the class range to treat. Thereby, a more accurate medical effect can be provided.

A third aspect of the present disclosure also provides a skin treatment apparatus. In some examples, for convenience of description, the following "skin treatment device" may sometimes also be referred to as "treatment device" or "device". Fig. 6 is a block diagram showing the general structure of the skin treatment apparatus 2 according to the example of the present disclosure.

As shown in fig. 6, in some examples, the skin treatment apparatus 2 may comprise a controller 21 and a working device 22. In some examples, the controller 21 may receive the regulatory information and identify selection information and base strength information in the regulatory information. In some examples, further, the controller 21 may also select an operation mode of the operation device 22 based on the selection information in the regulation information and identify an information component in the base strength information based on the selected operation mode. In some examples, further, the operative device 22 may also obtain an intensity parameter based on the information component. In some examples, working device 22 may perform a treatment on the skin based on the intensity parameter. In this case, at least one of the plurality of operation modes can be selected by the controller 21 and parameter adjustment can be simultaneously performed, thereby performing physical therapy on the skin of the human body through the operation device 22.

In some examples, if the operation mode is a superimposed wave mode, the controller 21 may identify whether the information components include a conductance intensity information component and a heating intensity information component.

In some examples, further, if the information component includes a conductance intensity information component and does not include a heating intensity information component, then the working device 22 may obtain a conductance intensity parameter based on the conductance intensity information component and may obtain a superimposed wave intensity quantity based on the conductance intensity parameter. In some examples, further, the superimposed wave microcurrent may be output to the skin based on the superimposed wave intensity amount. In some examples, working device 22 includes a waveform generator 227, and waveform generator 227 may obtain a conductance intensity parameter based on the conductance intensity information component. In some examples, the worker 22 includes a superimposed wave micro-current generator 2241, and the superimposed wave micro-current generator 2241 may obtain the superimposed wave intensity amount based on the conductance intensity parameter. In this case, it is possible to select the superimposed wave operation mode by the controller 21 and generate the superimposed wave intensity amount by the superimposed wave micro-current generator 2241 to output the superimposed wave micro-current of a certain intensity to perform the electrical therapy on the skin.

In some examples, further, if the information component includes a conductance intensity information component and a heating intensity information component, the working device 22 may obtain a conductance intensity parameter based on the conductance intensity information component, may obtain a heating intensity parameter based on the heating intensity information component, and may obtain a superimposed wave intensity amount based on the conductance intensity parameter. In some examples, further, the superimposed wave microcurrent may be output to the skin based on the superimposed wave intensity amount, and the thermal energy may be output to the skin based on the heating intensity parameter. In some examples, the working device 22 includes a superposed wave micro-current generator 2241 and a heater 2212, the superposed wave micro-current generator 2241 may obtain a superposed wave intensity amount based on the electric conductance intensity parameter to output a superposed wave micro-current to the skin, and the heater 2212 may obtain a heating intensity parameter based on the heating intensity parameter and output thermal energy to the skin based on the heating intensity parameter. In this case, it is possible to select the superimposed wave operation mode by the controller 21, and to generate the amount of intensity of the superimposed wave by the superimposed wave micro-current generator 2241 to output the amount of intensity of the superimposed wave micro-current to perform the electrical therapy on the skin, and to generate the amount of heat energy by the heater 2212 to perform the thermal therapy on the skin.

In some examples, if the operation mode is a square wave mode, the controller 21 of the skin treatment device 2 may identify whether the information component includes a basic intensity information component, and identify whether the modulation information includes a vibration intensity parameter.

In some examples, further, if the information component includes a base intensity information component and the modulation information does not include a vibration intensity parameter, then the working device 22 may obtain a base intensity parameter based on the base intensity information component and a square wave intensity amount based on the base intensity parameter. In some examples, further, a square wave microcurrent may be output to the skin based on the square wave intensity amount. The working device 22 includes a square wave micro-current generator 2251, and the square wave micro-current generator 2251 can obtain an intensity value of the square wave based on the base intensity parameter and output the square wave micro-current to the skin. In this case, the square wave operation mode can be selected by the controller 21, and the square wave micro-current generator 2251 generates a square wave micro-current of a certain intensity to electrically treat the skin.

In some examples, further, if the information component includes a basic intensity information component and the modulation information includes a vibration intensity parameter, the working device 22 may obtain the basic intensity parameter based on the basic intensity information component and may obtain the square wave intensity amount based on the basic intensity parameter. In some examples, further, the square wave microcurrent may be output to the skin based on the square wave intensity quantity, and the mechanical energy may be output to the skin based on the vibration intensity quantity. The working device 22 includes a square wave micro-current generator 2251 and a vibrator 2222, wherein the square wave micro-current generator 2251 can output square wave micro-current to the skin based on the square wave intensity quantity obtained by the basic intensity parameter, and the vibrator 2222 can output mechanical energy to the skin based on the vibration intensity parameter. In this case, the square wave operation mode can be selected by the controller 21, and the square wave micro-current of a certain intensity can be generated by the square wave micro-current generator 2251 and the kinetic energy of a certain intensity can be generated by the vibrator 2222 to simultaneously perform the electrical and mechanical therapy on the skin.

Fig. 7 is a schematic diagram showing the structure and signal relationship of the skin treatment apparatus 2 according to the example of the present disclosure.

As shown in fig. 7, in some examples, controller 21 may include an IO port 211, a main controller 212, and a control switch 213. In some examples, IO port 211 may receive regulatory information and transmit to main controller 212. In some examples, master controller 212 may identify selection information and base strength information in the regulatory information. In some examples, further, the master controller 212 may also select an operating mode of the operating device 22 based on selection information in the regulatory information. In some examples, master controller 212 may also identify an information component in the base strength information based on the selected operating mode and input into operating device 22 through control switch 213. In some examples, further, the operative device 22 may also obtain an intensity parameter based on the information component. In this case, at least one of the plurality of operation modes can be selected and the parameter adjustment can be simultaneously performed, so that the physical therapy can be performed on the skin of the human body.

As shown in fig. 7, in some examples, the working device 22 may include, but is not limited to, a heating component 221 that outputs thermal energy, a superimposed wave microcurrent generation component 224 that outputs a superimposed wave microcurrent, a square wave microcurrent generation component 225 that outputs a square wave microcurrent, a vibration component 222 that outputs mechanical energy, and a selection switch 226 for switching the mode of operation. Optionally, the heating component 221 generates heat energy with specific strength according to the heating strength parameter to perform thermal physical therapy on the skin, the superposed wave micro-current generating component 224 generates a superposed wave strength according to the conductivity strength parameter to output a superposed wave micro-current to assist in performing electrical physical therapy on the skin, the square wave micro-current generating component 225 generates a square wave strength according to the basic strength parameter to generate a superposed wave micro-current to assist in performing electrical physical therapy on the skin, and the vibrating component 222 generates kinetic energy with specific strength according to the vibration strength parameter to perform mechanical physical therapy on the skin.

As shown in fig. 7, in some examples, the working device 22 may further include a waveform generator 227, the waveform generator 227 being configured to generate the intensity parameters to form the control waveform. The working device 22 may also include electrode pads 229 and hand tool 228 to conduct microcurrents generated by the superimposed wave microcurrent generating assembly 224, the square wave microcurrent generating assembly 225 to the skin. In some examples, the electrode pads 229 may receive the superimposed wave strength amount to perform a treatment on the human skin. In some examples, the hand piece 228 may receive a square wave intensity value to perform a physical therapy on the human skin. In other examples, the type of energy received by the electrode pads 229 and the hand tool 228 may not be limiting, for example, in some examples, the electrode pads 229 may also receive a square wave intensity amount, or the like. In some examples, the electrode tabs 229 are mechanically secured to the heating assembly 221. In some examples, the hand piece 228 is mechanically secured to the vibration assembly 222. In some examples, the working device 22 may also include a position feedback 289. In some examples, the in-place feedback 289 may generate feedback information to the controller 21 to cause the controller 21 to identify the base strength information based on the feedback information. In this case, the safety and accuracy of the skin treatment process can be improved by the feedback information.

Fig. 8 is a block diagram showing the structure of the heating unit 221 according to the example of the present disclosure. Fig. 9 is a block diagram showing a structure of the vibration component 222 according to an example of the present disclosure. Fig. 10 is a block diagram illustrating a structure of a superimposed wave micro-current generating component 224 according to an example of the present disclosure. Fig. 11 is a block diagram illustrating the structure of a square wave micro-current generating assembly 225 according to an example of the present disclosure.

As shown in fig. 8, in some examples, heating assembly 221 may include a heating potentiostat 2211 and a heater 2212. In some examples, the heating regulator 2211 may regulate the heating intensity parameter and then input the regulated heating intensity parameter to the heater 221, so that the heater 221 outputs the heat energy.

As shown in fig. 9, in some examples, the vibration component 222 may include a vibration regulator 2221 and a vibrator 2222. In some examples, the vibration stabilizer 2221 may stabilize the vibration intensity parameter and then input the stabilized vibration intensity parameter to the vibrator 2222, so that the vibrator 2222 outputs mechanical energy.

As shown in fig. 10 and 11, in some examples, the superimposed wave microcurrent generating assembly 224 may include an intermediate frequency voltage regulator 245 and a superimposed wave microcurrent generator 2241. In some examples, the square wave microcurrent generation assembly 225 may include an intermediate frequency voltage regulator 245 and a square wave microcurrent generator 2251. In some examples, the superimposed wave micro-current generator 2241 and the square wave micro-current generator 2251 may share one voltage regulator, that is, the if voltage regulator 245 may perform voltage stabilization on the intensity parameter and then input the intensity parameter to the superimposed wave micro-current generator 2241 or the square wave micro-current generator 2251. The intensity parameters processed by the intermediate frequency voltage stabilizer 245 may include a basic intensity parameter or a conductivity intensity parameter, and the basic intensity parameter after voltage stabilization is sent to the square wave micro-current generator 2251 by the intermediate frequency voltage stabilizer, so that the square wave micro-current generator 2251 generates a square wave intensity amount; and the conductance intensity parameter after voltage stabilization processing can be sent to the superposed wave micro-current generator 2241 by the intermediate frequency voltage stabilizer so as to generate a superposed wave intensity value.

Fig. 12 is a schematic diagram showing the structure and signal relationship of a skin treatment apparatus 2 according to another example of the present disclosure.

As shown in fig. 12, in some examples, the master controller 212 may select and activate the superposition wave micro-current generator 2241 or the square wave micro-current generator 2251 through the selection switch 226 based on the control information, that is, the master controller 212 may also control the selection switch 226 to select the operation mode of the operation device 22 based on the selection information in the control information. In some examples, waveform generator 227 may generate an intensity parameter based on an information component in the intensity information and input to heating regulator 2211 or intermediate frequency regulator 245. In this case, the heater 2212, the superimposed wave micro-current generator 2241, or the square wave micro-current generator 2251 can be controlled in intensity, time, frequency, or the like by the waveform.

In some examples, the working device 22 may also include a waveform generator 227, the waveform generator 227 for generating the intensity parameter. In some examples, waveform generator 227 may generate an intensity parameter based on an information component in the base intensity information identified by main controller 212 and input to heating regulator 2211 or intermediate frequency regulator 245.

As shown in fig. 12, in some examples, to facilitate the fit of the device to human skin, the working device 22 may further include conductive members such as electrode pads 229 and hand piece 228 to conduct micro-current or the like to the skin. In some examples, the electrode tabs 229 are mechanically fastened to the heater 2212 and the hand piece 228 is mechanically fastened to the vibrator 2222, thereby facilitating the conduction of mechanical and thermal energy. In some examples, the electrode pads 229 may receive a superimposed wave microcurrent and conform to human skin for therapeutic treatment. In some examples, the hand piece 228 may receive square wave microcurrent and perform physical therapy by contacting human skin. In other examples, the type of energy received by the electrode pads 229 and the hand tool 228 may not be limiting, for example, in some examples, the electrode pads 229 may also receive square wave microcurrent, or the like. In some examples, the superimposed wave micro-current generator 2241 outputs the superimposed wave micro-current to the electrode pad 229, the electrode pad 229 is connected with the heater 2212 by a mechanical fixing means; the square wave micro-current generator 2251 outputs a square wave micro-current to the hand tool 228, and the hand tool 228 may be connected to the vibrator 2222 in a mechanically fixed manner. In this case, thermal energy, kinetic energy or electric energy can be conducted to the skin, thereby performing physical therapy on the skin.

As shown in fig. 12, in some examples, the working device 22 may also include a position feedback 289. In some examples, an in-place feedback 289 is disposed between the main controller 212 and the electrode pads 229, or/and between the main controller 212 and the hand piece 228, such that the electrode pads 229 and/or the hand piece 228 feed back feedback information to the main controller 212.

As shown in fig. 12, in some examples, the process of obtaining the intensity parameter by the main controller 212 of the working device 22 based on the information component may be further modified by the main controller 212 based on the feedback information in the in-place feedback device 289, for example, the corresponding intensity parameter may be modified based on the impedance information of the skin of the human body in the feedback information, thereby improving the therapeutic effect of the skin therapy apparatus.

According to the three aspects of the disclosure, a skin treatment apparatus and a device capable of simultaneously responding in a multifunctional mode and performing parameter regulation and control, and a parameter adjustment method thereof can be provided.

While the present disclosure has been described in detail in connection with the drawings and examples, it should be understood that the above description is not intended to limit the disclosure in any way. Those skilled in the art can make modifications and variations to the present disclosure as needed without departing from the true spirit and scope of the disclosure, which fall within the scope of the disclosure.

Claims (15)

1. A parameter adjustment method of a skin physiotherapy apparatus, comprising:

receiving regulation and control information, and identifying selection information and basic strength information in the regulation and control information;

identifying a working mode based on the selection information and identifying an information component in the base strength information based on the working mode;

obtaining an intensity parameter based on the information component and performing physical therapy on the skin based on the intensity parameter.

2. The parameter adjustment method according to claim 1,

and if the working mode is a superposed wave mode, identifying whether the information component comprises a conductivity intensity information component and a heating intensity information component.

3. The parameter adjustment method according to claim 2,

if the information component comprises the electric conduction strength information component and does not comprise the heating strength information component, acquiring an electric conduction strength parameter based on the electric conduction strength information component, acquiring a superposed wave strength quantity based on the electric conduction strength parameter and carrying out electric physical therapy on the skin based on the superposed wave strength quantity.

4. The parameter adjustment method according to claim 2,

if the information component comprises the electric conduction strength information component and the heating strength information component, acquiring an electric conduction strength parameter based on the electric conduction strength information component and acquiring a heating strength parameter based on the heating strength information component, acquiring a superposed wave strength quantity based on the electric conduction strength parameter and carrying out electric physical therapy on the skin based on the superposed wave strength quantity, and carrying out thermal physical therapy on the skin based on the heating strength parameter.

5. The parameter adjustment method according to claim 1,

and if the working mode is a square wave mode, identifying whether the information component comprises a basic intensity information component or not, and whether the regulation and control information comprises a vibration intensity parameter or not.

6. The parameter adjustment method according to claim 5,

if the information component comprises the basic strength information component and the regulation and control information does not comprise the vibration strength parameter, obtaining a basic strength parameter based on the basic strength information component, obtaining a square wave strength based on the basic strength parameter and carrying out electric physical therapy on the skin based on the square wave strength.

7. The parameter adjustment method according to claim 5,

if the information component comprises the basic strength information component and the regulation and control information comprises the vibration strength parameter, obtaining a basic strength parameter based on the basic strength information component and a square wave strength quantity based on the basic strength parameter, carrying out electric physical therapy on the skin based on the square wave strength quantity, and carrying out mechanical physical therapy on the skin based on the vibration strength parameter.

8. The parameter adjustment method according to claim 1,

further comprising: generating feedback information based on the working mode and identifying the basic strength information based on the feedback information.

9. A skin physiotherapy device is characterized by comprising a first identification module, a second identification module, a conversion module and an output module, wherein the first identification module receives regulation and control information and identifies selection information and basic strength information in the regulation and control information, the second identification module selects a working mode of the output module based on the selection information in the regulation and control information and identifies an information component in the basic strength information based on the selected working mode, and the conversion module obtains a strength parameter based on the information component; the output module performs physical therapy on the skin based on the intensity parameter.

10. Skin treatment apparatus according to claim 9,

if the working mode is a superimposed wave mode, the second identification module identifies whether the information component comprises a conductance intensity information component and a heating intensity information component,

if the information component comprises the electric conduction strength information component and does not comprise the heating strength information component, the conversion module obtains an electric conduction strength parameter based on the electric conduction strength information component and obtains a superposed wave strength quantity based on the electric conduction strength parameter, and the output module carries out electric physical therapy on the skin based on the superposed wave strength quantity;

if the information component comprises the electric conduction strength information component and the heating strength information component, the conversion module obtains an electric conduction strength parameter based on the electric conduction strength information component, obtains a heating strength parameter based on the heating strength information component, obtains a superposed wave strength quantity based on the electric conduction strength parameter, and the output module performs electric physical therapy on the skin based on the superposed wave strength quantity and performs thermal physical therapy on the skin based on the heating strength parameter.

11. Skin treatment apparatus according to claim 9,

if the working mode is a square wave mode, the second identification module identifies whether the information component comprises a basic intensity information component or not, whether the regulation and control information comprises a vibration intensity parameter or not,

if the information component comprises the basic strength information component and the regulation and control information does not comprise the vibration strength parameter, the conversion module obtains a basic strength parameter based on the basic strength information component, obtains a square wave strength based on the basic strength parameter, and the output module performs electric physical therapy on the skin based on the square wave strength;

if the information component comprises the basic strength information component and the regulation and control information comprises the vibration strength parameter, the conversion module obtains the basic strength parameter based on the basic strength information component and obtains the square wave strength based on the basic strength parameter, and the output module carries out electric physical therapy on the skin based on the square wave strength and carries out mechanical physical therapy on the skin based on the vibration strength parameter.

12. A skin physiotherapy apparatus is characterized by comprising a controller and a working device, wherein the controller receives regulation and control information and identifies selection information and basic strength information in the regulation and control information, the controller selects a working mode of the working device based on the selection information in the regulation and control information and identifies an information component in the basic strength information based on the selected working mode, the working device obtains an intensity parameter based on an identification result of the controller, and the working device performs physiotherapy on skin based on the intensity parameter.

13. Skin treatment device according to claim 12,

the working device comprises a waveform generator, a heating assembly for outputting thermal energy, a superposed wave micro-current generating assembly for outputting superposed wave micro-current, a square wave micro-current generating assembly for outputting square wave micro-current and a vibration assembly for outputting mechanical energy.

14. Skin treatment device according to claim 13,

if the operation mode is a superimposed wave mode, the controller identifies whether the information component includes a conductance intensity information component and a heating intensity information component,

if the information component comprises the conductance intensity information component and does not comprise the heating intensity information component, the working device obtains a conductance intensity parameter based on the conductance intensity information component, obtains a superposed wave intensity quantity based on the conductance intensity parameter, and outputs a superposed wave micro-current to the skin based on the superposed wave intensity quantity;

if the information component comprises the conductance intensity information component and the heating intensity information component, the working device obtains a conductance intensity parameter based on the conductance intensity information component, obtains a heating intensity parameter based on the heating intensity information component, obtains a superposed wave intensity quantity based on the conductance intensity parameter, outputs a superposed wave micro-current to the skin based on the superposed wave intensity quantity, and outputs heat energy to the skin based on the heating intensity parameter.

15. Skin treatment device according to claim 13,

if the working mode is a square wave mode, identifying whether the information component comprises a basic intensity information component and whether the regulation information comprises a vibration intensity parameter,

if the information component comprises the basic strength information component and the regulation and control information does not comprise the vibration strength parameter, the working device obtains a basic strength parameter based on the basic strength information component, obtains a square wave strength based on the basic strength parameter, and outputs square wave micro-current to skin based on the square wave strength;

if the information component comprises the basic strength information component and the regulation and control information comprises the vibration strength parameter, the working device obtains the basic strength parameter based on the basic strength information component, obtains the square wave strength based on the basic strength parameter, outputs square wave micro-current to the skin based on the square wave strength, and outputs mechanical energy to the skin based on the vibration strength parameter.

Images