CN115814276A - Multifunctional skin therapeutic apparatus and control method and system thereof - Google Patents

Abstract

The invention relates to the technical field of medical instruments and discloses a multifunctional skin therapeutic apparatus and a control method and a system thereof. The host of the therapeutic apparatus comprises a communication module, a control system, an air source module, a high-voltage power supply module and a power supply module; the control system comprises an acquisition module, a determination module and a control module; the control method comprises the following steps: acquiring a target working mode; matching a corresponding jet flow energy value range according to the target working mode, and determining a target jet flow energy value according to the matched jet flow energy value range; and sending corresponding control signals to the gas source module and the high-voltage power supply module so that the gas source module outputs corresponding working gas and the high-voltage power supply module outputs a correspondingly set high-voltage pulse power supply, and ionizing the introduced working gas by the plasma generating device according to the connected high-voltage pulse power supply to generate plasma jet. The invention can adjust the energy intensity of the plasma jet according to different skin problems.

Description

Multifunctional skin therapeutic apparatus and control method and system thereof

Technical Field

The invention relates to the technical field of medical instruments, in particular to a multifunctional skin therapeutic apparatus and a control method and a system thereof.

Background

The plasma is an ionized gaseous substance composed of atoms with part of electrons being deprived and positive and negative electrons generated after the atoms are ionized, and the substance exists in a fourth state except solid, liquid and gas. According to current research, plasmas can be applied in the medical field and can be used to treat skin problems. When the plasma energy is different, the effect on the skin is different, for example, when the skin is treated by using the plasma with lower energy, the skin can kill bacteria on the surface of the skin and can be used for treating acne and pox, and when the plasma with higher energy is used, the heat effect of the plasma energy can be utilized to act on the surface layer of the skin, remove dead cells of the epidermis and stimulate the differentiation of new cells, so that the aged skin is renewed. When plasma is used to treat skin, the plasma with proper energy intensity should be used to treat the skin according to different states of the skin, so that the skin treatment effect is optimal.

However, the existing plasma skin treatment devices generally do not have the function of adjusting the energy intensity of the plasma jet, and the plasma with single energy intensity is generally used for treating various skin problems. For example, CN110664604A discloses a detachable plasma skin treatment apparatus, which is detachably matched with different nursing head assemblies to realize the treatment of skin by using multiple functions such as plasma and EMS, but cannot adjust the plasma jet energy intensity for different skin problems; CN114099966A discloses a plasma cosmetic apparatus capable of reducing ozone odor by gas recycling, which can reduce odor caused by gases such as ozone, but also cannot adjust the plasma jet energy intensity for different skin problems.

Disclosure of Invention

The invention provides a multifunctional skin therapeutic apparatus and a control method and a control system thereof, which solve the technical problem that the existing plasma skin therapeutic apparatus can not adjust the energy intensity of plasma jet according to different skin problems.

The invention provides a control method of a multifunctional skin treatment instrument, which is applied to the skin treatment instrument and comprises the following steps:

acquiring a target working mode;

matching a corresponding jet flow energy value range according to the target working mode, and determining a target jet flow energy value according to the matched jet flow energy value range;

and sending corresponding control signals to the gas source module and the high-voltage power supply module according to the target working mode and the target jet energy value, so that the gas source module outputs correspondingly set working gas to the corresponding plasma generating device, and the high-voltage power supply module outputs correspondingly set high-voltage pulse power supply to the corresponding plasma generating device.

According to an implementable manner of the first aspect of the present invention, the obtaining the target operation mode includes:

and acquiring the target working mode through a communication module.

According to an implementable manner of the first aspect of the present invention, the obtaining the target operation mode includes:

receiving a first skin detection result sent by a skin detection device;

and matching a corresponding target working mode according to the first skin detection result.

According to a possible implementation manner of the first aspect of the present invention, the matching of the corresponding range of the jet energy values according to the target operation mode includes:

matching a corresponding jet flow energy value range from a first preset database according to the target working mode; and the first preset database stores the corresponding relation between the working mode and the jet flow energy value range.

According to an enabling aspect of the first aspect of the invention, the determining a target jet energy value from the matched range of jet energy values comprises:

and sending the matched jet flow energy value range to the communication module to feed back to a user, and receiving a target jet flow energy value fed back by the user.

According to another achievable mode of the first aspect of the present invention, the determining the target jet energy value according to the matched jet energy value range includes:

receiving a second skin detection result sent by the skin detection device;

determining an optimal jet energy value according to the second skin detection result and the matched jet energy value range, and sending the optimal jet energy value to the communication module to feed back to a user;

and receiving a target jet flow energy value fed back by the user and sent by the communication module.

According to a manner that can be realized by the first aspect of the present invention, the sending of the corresponding control signal to the gas source module and the high voltage power supply module according to the target operation mode and the target jet energy value includes:

matching corresponding working gas proportions from a second preset database according to the target working mode, and matching corresponding voltage amplitude, pulse frequency, pulse width and working gas flow rate from the second preset database according to the target jet energy value;

sending a corresponding control signal to the gas source module according to the matched working gas proportion and working gas flow rate;

sending a corresponding control signal to the high-voltage power supply module according to the matched voltage amplitude, pulse frequency and pulse width;

the second preset database stores the corresponding relation between the working mode and the working gas proportion and the corresponding relation between the jet flow energy value and the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate.

According to a manner that can be realized by the first aspect of the present invention, the sending a corresponding control signal to the high-voltage power module according to the matched voltage amplitude, pulse frequency and pulse width includes:

sending a corresponding control signal to a direct-current power supply submodule according to the matched voltage amplitude so that the direct-current power supply submodule outputs direct-current voltage with corresponding amplitude to the high-voltage pulse power supply submodule;

and sending a corresponding control signal to the high-voltage pulse power supply submodule according to the matched pulse frequency and pulse width so that the high-voltage pulse power supply submodule outputs a high-voltage pulse power supply with corresponding frequency and pulse width to the plasma generating device.

According to a manner that can be realized by the first aspect of the present invention, the sending a corresponding control signal to the gas source module according to the matched working gas proportion and working gas flow rate includes:

sending a switching signal to the switching device to enable the switching device to be opened, and outputting working gas;

and sending a corresponding control signal to the flow control device according to the matched working gas flow rate, so that the flow control device can deliver the working gas to the corresponding plasma generating device according to the corresponding working gas flow rate and proportion.

According to another implementation manner of the first aspect of the present invention, the sending corresponding control signals to the gas source module and the high voltage power supply module according to the target operating mode and the target jet energy value includes:

matching the identifier of the corresponding plasma generating device from a third preset database according to the target working mode;

sending corresponding control signals to the gas source module and the high-voltage power supply module according to the matched identifier so that the gas source module outputs working gas to the plasma generating device corresponding to the matched identifier and the high-voltage power supply module outputs high-voltage pulse power supply to the plasma generating device corresponding to the matched identifier;

and the third preset database stores the corresponding relation between the working mode and the identification of the plasma generating device.

In a second aspect, the present invention provides a control system for a multi-functional skin treatment apparatus, the control system comprising:

the acquisition module is used for acquiring a target working mode;

the determining module is used for matching a corresponding jet flow energy value range according to the target working mode and determining a target jet flow energy value according to the matched jet flow energy value range;

and the control module is used for sending corresponding control signals to the gas source module and the high-voltage power supply module according to the target working mode and the target jet flow energy value so as to enable the gas source module to output correspondingly set working gas to the corresponding plasma generating device and enable the high-voltage power supply module to output correspondingly set high-voltage pulse power supply to the corresponding plasma generating device.

According to an implementable manner of the second aspect of the present invention, the obtaining means comprises:

and the acquisition unit is used for acquiring the target working mode through the communication module.

According to an implementable manner of the second aspect of the present invention, the obtaining means comprises:

the first receiving unit is used for receiving a first skin detection result sent by the skin detection device;

and the first matching unit is used for matching the corresponding target working mode according to the first skin detection result.

According to an implementable manner of the second aspect of the invention, the determining module comprises:

the second matching unit is used for matching a corresponding jet flow energy value range from the first preset database according to the target working mode; and the first preset database stores the corresponding relation between the working mode and the jet flow energy value range.

According to an implementable manner of the second aspect of the invention, the determining module comprises:

and the interaction unit is used for sending the matched jet flow energy value range to the communication module to feed back to the user and receiving a target jet flow energy value fed back by the user.

According to another implementable manner of the second aspect of the present invention, the determining module comprises:

the second receiving unit is used for receiving a second skin detection result sent by the skin detection device;

the determining unit is used for determining an optimal jet energy value according to the second skin detection result and the matched jet energy value range and sending the optimal jet energy value to the communication module to feed back to a user;

and the third receiving unit is used for receiving the target jet flow energy value fed back by the user and sent by the communication module.

According to an implementable manner of the second aspect of the invention, the control module comprises:

the third matching unit is used for matching corresponding working gas proportions from a second preset database according to the target working mode and matching corresponding voltage amplitude, pulse frequency, pulse width and working gas flow rate from the second preset database according to the target jet flow energy value;

the first sending unit is used for sending a corresponding control signal to the gas source module according to the matched working gas proportion and working gas flow rate;

the second sending unit is used for sending a corresponding control signal to the high-voltage power supply module according to the matched voltage amplitude, pulse frequency and pulse width;

the second preset database stores the corresponding relation between the working mode and the working gas proportion and the corresponding relation between the jet flow energy value and the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate.

According to an implementable aspect of the second aspect of the present invention, the second transmitting unit includes:

the first sending subunit is used for sending a corresponding control signal to the direct-current power supply submodule according to the matched voltage amplitude so that the direct-current power supply submodule outputs direct-current voltage with corresponding amplitude to the high-voltage pulse power supply submodule;

and the second sending subunit is used for sending a corresponding control signal to the high-voltage pulse power supply submodule according to the matched pulse frequency and pulse width, so that the high-voltage pulse power supply submodule outputs a high-voltage pulse power supply with a corresponding frequency and pulse width to the plasma generation device.

According to an implementable aspect of the second aspect of the present invention, the first sending unit comprises:

the third sending subunit is used for sending a switching signal to the switching device so that the switching device is opened and the working gas is output;

and the fourth sending subunit is used for sending a corresponding control signal to the flow control device according to the matched working gas flow rate, so that the flow control device can deliver the working gas to the corresponding plasma generating device according to the corresponding working gas flow rate and proportion.

According to another implementable manner of the second aspect of the present invention, the control module comprises:

the fourth matching unit is used for matching the corresponding identifier of the plasma generating device from a third preset database according to the target working mode;

the third sending unit is used for sending corresponding control signals to the gas source module and the high-voltage power supply module according to the matched identifier so as to enable the gas source module to output working gas to the plasma generating device corresponding to the matched identifier and enable the high-voltage power supply module to output a high-voltage pulse power supply to the plasma generating device corresponding to the matched identifier;

and the third preset database stores the corresponding relation between the working mode and the identification of the plasma generating device.

The invention provides a multifunctional skin treatment instrument, which comprises a host and a handle, wherein the host comprises an air source module, a high-voltage power supply module, a power supply module and a control system of the multifunctional skin treatment instrument, which can be realized in any one way;

the handle comprises a plasma generating device;

the power supply module is connected with the control system, the gas source module, the high-voltage power supply module and the plasma generating device and is used for supplying power to each module;

the control system is connected with the air source module and the high-voltage power supply module and is used for controlling the air source module and the high-voltage power supply module to work;

the gas source module is connected with the plasma generating device and used for outputting correspondingly set working gas to the plasma generating device according to a control signal sent by a control system;

the high-voltage power supply module is connected with the plasma generating device and used for outputting a correspondingly set high-voltage pulse power supply to the plasma generating device according to a control signal sent by a control system.

According to an implementable aspect of the third aspect of the present invention, the host further comprises:

the communication module is connected with the control system and used for receiving information sent to the communication module by the control system, feeding back the information to a user, acquiring information fed back by the user and sending the information fed back by the user to the control system, wherein the information fed back by the user comprises a target working mode and a target jet energy value.

According to an enabling mode of the third aspect of the present invention, the multi-functional skin treatment apparatus further comprises:

and the skin detection device is connected with the control system and is used for detecting the skin state and sending the skin detection result to the control system.

According to an implementable manner of the third aspect of the present invention, the high-voltage power supply module includes:

the direct-current power supply submodule and the high-voltage pulse power supply submodule;

the direct-current power supply submodule is connected with the control system and the high-voltage pulse power supply submodule and is used for outputting direct-current voltage with corresponding amplitude to the high-voltage pulse power supply submodule according to a control signal sent by the control system;

the high-voltage pulse power supply submodule is connected with the control system and the plasma generating device and is used for outputting a high-voltage pulse power supply with corresponding frequency and pulse width to the plasma generating device according to a control signal sent by the control system.

According to one possible implementation of the third aspect of the invention, the gas source module comprises:

the air source submodule is composed of an air tank, a pressure reducing device, a switching device and a flow control device which are connected in sequence;

the gas tank is used for storing working gas;

the decompression device is used for decompressing the working gas stored in the gas tank;

the switch device is connected with the control system and is used for being switched on and switched off according to a control signal sent by the control system;

when the number of the gas source sub-modules is one, the flow control device is connected with the control system and the plasma generating device and is used for conveying working gas with corresponding flow rate to the plasma generating device according to a control signal sent by the control system;

when the air source submodule is multiple, the air source module further comprises a gas mixing device for mixing working gas, an input port of the gas mixing device is connected with an output port of each flow control device, an output port of the gas mixing device is connected with a plasma generating device, and the flow control devices adjust the flow rate and proportion of the working gas according to control signals sent by the control system and output the working gas to the gas mixing device.

According to one possible implementation of the third aspect of the invention, the handle comprises a plurality of structurally different plasma generating devices;

or the number of the handles is multiple, and the structures of the plasma generating devices arranged in the handles are different.

According to the technical scheme, the invention has the following advantages:

the multifunctional skin therapeutic apparatus comprises a host and a handle, wherein the host comprises a communication module, a control system, an air source module, a high-voltage power supply module and a power supply module, and the handle comprises a plasma generating device; the control system comprises an acquisition module, a determination module and a control module; the control method comprises the following steps: acquiring a target working mode; matching a corresponding jet flow energy value range according to the target working mode, and further determining a target jet flow energy value; sending corresponding control signals to the gas source module and the high-voltage power supply module according to the target working mode and the target jet flow energy value so as to enable the gas source module to output correspondingly set working gas and enable the high-voltage power supply module to output correspondingly set high-voltage pulse power supply, so that a plasma generating device in the handle ionizes the introduced working gas according to the connected high-voltage pulse power supply to generate plasma jet flow; the invention can solve different skin problems by selecting different working modes, realize skin treatment with multiple functions, adjust the energy intensity of the plasma jet according to the determined working modes, and carry out skin treatment with the optimal energy intensity of the plasma jet, so that the skin treatment effect is better, and better user experience is obtained.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

FIG. 1 is a block diagram illustrating the structural connections of a multi-functional skin treatment apparatus according to an alternative embodiment of the present invention;

FIG. 2 is a schematic view of the control principle of a multi-functional skin treatment apparatus according to an alternative embodiment of the present invention;

FIG. 3 is a flow chart of a method for controlling a multi-functional skin treatment apparatus according to an alternative embodiment of the present invention;

fig. 4 is a block diagram illustrating the structural connection of a control system of the multi-functional skin treatment apparatus according to an alternative embodiment of the present invention.

Reference numerals:

100-a host; 200-a handle;

1-a communication module; 2-a control system; 3-an air source module; 4-a high voltage power supply module; 5-a power supply module; 6-a plasma generating device;

31-a gas source sub-module; 311-gas tanks; 312-a pressure reduction device; 313-a switching device; 314-a flow control device; 41-a direct current power supply submodule; 42-high voltage pulse power supply submodule;

10-an acquisition module; 20-a determination module; 30-control module.

Detailed Description

The embodiment of the invention provides a multifunctional skin therapeutic apparatus and a control method and a control system thereof, which are used for solving the technical problem that the existing plasma skin therapeutic apparatus can not adjust the energy intensity of plasma jet according to different skin problems.

In order to make the objects, features and advantages of the present invention more obvious and understandable, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the embodiments described below are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise. The invention provides a control method of a multifunctional skin therapeutic apparatus.

Fig. 1 shows a schematic structural connection diagram of a multifunctional skin treatment apparatus provided by the embodiment of the invention. Referring to fig. 1, the multifunctional skin treatment instrument comprises a main machine 100 and a handle 200, wherein the main machine 100 comprises an air source module 3, a high-voltage power supply module 4, a power supply module 5 and a control system 2;

the handle 200 comprises a plasma generating device 6;

the power supply module 5 is connected with the control system 2, the gas source module 3, the high-voltage power supply module 4 and the plasma generating device and is used for supplying power to each module;

the control system 2 is connected with the air source module 3 and the high-voltage power supply module 4 and is used for controlling the air source module 3 and the high-voltage power supply module 4 to work;

the gas source module 3 is connected with the plasma generating device 6 and is used for outputting correspondingly set working gas to the plasma generating device 6 according to a control signal sent by the control system 2;

the high-voltage power supply module 4 is connected with the plasma generation device 6 and is used for outputting a correspondingly set high-voltage pulse power supply to the plasma generation device 6 according to a control signal sent by the control system 2.

The gas source module 3 is used for providing working gas for the plasma generating device 6, and the high-voltage power supply module is used for providing a high-voltage power supply of 1kV-30kV for the plasma generating device 6.

In one implementation, the host 100 further includes:

the communication module 1 is connected with the control system 2 and used for receiving information sent to the communication module 1 by the control system 2, feeding the information back to a user, acquiring information fed back by the user and sending the information fed back by the user to the control system 2, wherein the information fed back by the user comprises a target working mode and a target jet energy value.

In one enabling form, the multifunctional skin treatment apparatus further comprises:

skin detection means (not shown in fig. 1) connected to the control system 2 for detecting the skin condition and sending the skin detection result to the control system 2.

In one implementation, as shown in fig. 2, the high-voltage power module 4 includes:

a direct-current power supply submodule 41 and a high-voltage pulse power supply submodule 42;

the direct-current power supply submodule 41 is connected with the control system 2 and the high-voltage pulse power supply submodule 42, and the direct-current power supply submodule 41 is used for outputting direct-current voltage with corresponding amplitude to the high-voltage pulse power supply submodule 42 according to a control signal sent by the control system 2;

the high-voltage pulse power supply submodule 42 is connected to the control system 2 and the plasma generating device 6, and the high-voltage pulse power supply submodule 42 is configured to output a high-voltage pulse power supply with a corresponding frequency and a corresponding pulse width to the plasma generating device 6 according to a control signal sent by the control system 2.

In an implementable manner, the gas source module 3 comprises:

the air source submodule 31 is composed of an air tank 311, a pressure reducing device 312, a switch device 313 and a flow control device 314 which are connected in sequence;

the gas tank 311 is used for storing working gas;

the decompression device 312 is used to decompress the working gas stored in the gas tank 311;

the switch device 313 is connected with the control system 2 and is used for being turned on and off according to a control signal sent by the control system 2;

when the number of the gas source sub-modules 31 is one, the flow control device 314 is connected with the control system 2 and the plasma generation device 6, and the flow control device 314 is used for delivering working gas with a corresponding flow rate to the plasma generation device 6 according to a control signal sent by the control system 2;

when the gas source submodule 31 is multiple, the gas source module 3 further includes a gas mixing device for mixing the working gas, an input port of the gas mixing device is connected to each output port of the flow control device 314, an output port of the gas mixing device is connected to the plasma generating device 6, and the flow control device 314 adjusts the flow rate and proportion of the working gas according to the control signal sent by the control system 2 and outputs the working gas to the gas mixing device.

In one possible implementation, the handpiece 200 comprises a plurality of structurally different plasma-generating devices 6;

alternatively, the plurality of handgrips 200 may be provided, and the plasma generator 6 provided in each of the handgrips 200 may have a different structure.

Fig. 3 shows a flow chart of a control method of the multifunctional skin treatment apparatus according to the embodiment of the invention. The control method of the embodiment of the invention is applied to the multifunctional skin treatment apparatus shown in fig. 1, and the control method can be executed by the control system 2.

As shown in fig. 3, a control method of a multifunctional skin treatment apparatus provided by the embodiment of the present invention includes:

and S1, acquiring a target working mode.

The plasma jet energy values are different, the reached skin depths are different, and a user can select the corresponding plasma jet energy values to carry out skin treatment according to different skin problems. For simple user operation, a plurality of different working modes can be preset aiming at skin problems. For example, the jet stream can be one or more of acne removing, freckle removing, skin rejuvenation, anti-aging and guiding, and each working mode has a corresponding jet stream energy value range. The specific type of the working mode can be set according to the actual situation.

In one implementation, the obtaining the target operating mode includes:

and acquiring the target working mode through the communication module 1.

In specific implementation, a user selects a working mode based on the communication module 1, and then the working mode selected by the user is used as a target working mode. The communication module 1 may be a display screen or other devices that can interact with a user. As a specific implementation manner, when the communication module 1 is a touch display screen, a user can directly operate on the touch display screen to determine a target operating mode; when the communication module 1 is a non-touch display screen, a user inputs a target working mode in a key input mode.

In the embodiment, the user directly selects the target working mode through the communication module 1, and the method is simple and convenient.

In another implementation manner, for a multifunctional skin treatment apparatus including a skin detection device, when the target operation mode is determined by means of skin detection, the operation of step S1 includes:

and receiving a first skin detection result sent by the skin detection device, and matching a corresponding target working mode according to the first skin detection result.

The database of the method execution device/apparatus/system may be pre-stored with the corresponding relationship between various skin problems and the working mode, so that the optimal working mode suitable for the skin problems can be directly matched. For example, when acne is detected on the skin of the user, the acne removing working mode can be matched according to the skin detection result.

In this embodiment, automatic matching of the operation mode may be performed after skin detection of the skin of the user is performed.

And S2, matching a corresponding jet flow energy value range according to the target working mode, and determining a target jet flow energy value according to the matched jet flow energy value range.

In one implementation, the matching the corresponding range of jet energy values according to the target operation mode includes:

matching a corresponding jet flow energy value range from a first preset database according to the target working mode; and the first preset database stores the corresponding relation between the working mode and the jet flow energy value range.

The corresponding jet flow energy value range with the best skin effect can be determined in an experimental mode aiming at various working modes, and then the corresponding relation between the working modes and the jet flow energy value range is established and stored in the first preset database.

In one implementation, the determining a target jet energy value from the matched range of jet energy values includes:

and sending the matched jet flow energy value range to the communication module 1 to feed back to a user, and receiving a target jet flow energy value fed back by the communication module 1.

As an embodiment, the communication module 1 is a touch display screen, and a user can directly operate the touch display screen 1 to feed back the target jet energy value. As another embodiment, the communication module 1 is a non-touch display screen, and a user operates the communication module 1 by means of key input to prompt the communication module to feed back the target jet energy value. It should be noted that, when the target jet energy value is input through the key, the key may also be directly connected to the control system 2, so as to directly send the target jet energy value to the control system 2 without feedback through the communication module 1.

In this embodiment, a user may select a specific jet energy value according to the jet energy value range displayed by the communication module 1, and the communication module 1 performs feedback, so that the method execution device/apparatus/system may determine the target jet energy value according to the feedback information.

In another achievable form, for a multi-functional skin treatment apparatus including a skin detection device, the determining a target jet energy value based on the matched jet energy value range includes:

receiving a second skin detection result sent by the skin detection device, determining an optimal jet energy value according to the second skin detection result and the matched jet energy value range, sending the optimal jet energy value to the communication module 1 to feed back to a user, and receiving a target jet energy value fed back by the communication module 1.

The optimal jet energy value is obtained by research personnel through experiments, and has the optimal treatment effect on the skin problems corresponding to the skin detection result in the matched jet energy value range.

In this embodiment, the user may adjust the optimal jet energy value displayed by the communication module 1, and finally determine a specific jet energy value, that is, the specific jet energy value is used as the target jet energy value. The optimal jet energy value can be automatically determined according to the skin detection result after the skin of the user is detected, so that the user can refer to the optimal jet energy value.

It should be noted that, for the skin treatment apparatus including the skin detection device, two implementation manners for determining the target jet energy value may coexist, and in order to avoid conflict between the two implementation manners, a corresponding selection mechanism may be set. For example, timing may be performed when the jet energy value range is matched, the optimal jet energy value is determined according to the skin detection result and fed back when the skin detection result is received within the timing time period, and the matched jet energy value range is sent to the communication module 1 to be fed back to the user when the skin detection result is not received within the timing time period.

And S3, sending corresponding control signals to the gas source module 3 and the high-voltage power supply module 4 according to the target working mode and the target jet flow energy value, so that the gas source module 3 outputs correspondingly set working gas to the corresponding plasma generating device 6, and the high-voltage power supply module 4 outputs correspondingly set high-voltage pulse power supply to the corresponding plasma generating device 6.

According to the embodiment of the invention, the gas source module 3 can be controlled to output the set working gas through the selected target working mode and the target jet flow energy value, and the high-voltage power supply module 4 is controlled to output the set high-voltage pulse power supply, so that the plasma generating device 6 can ionize the set working gas according to the set high-voltage pulse power supply to generate the corresponding plasma jet flow, the regulation of the plasma jet flow energy intensity based on the working mode is realized, the skin treatment is carried out with the optimal plasma jet flow energy intensity, the skin treatment effect is better, and better user experience is obtained.

In an implementation manner, the sending corresponding control signals to the gas source module 3 and the high-voltage power supply module 4 according to the target operation mode and the target jet energy value includes:

matching corresponding working gas proportions from a second preset database according to the target working mode, and matching corresponding voltage amplitude, pulse frequency, pulse width and working gas flow rate from the second preset database according to the target jet energy value;

sending a corresponding control signal to the gas source module 3 according to the matched working gas proportion and working gas flow rate, and sending a corresponding control signal to the high-voltage power supply module 4 according to the matched voltage amplitude, pulse frequency and pulse width;

the second preset database stores the corresponding relation between the working mode and the working gas proportion and the corresponding relation between the jet energy value and the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate.

In the data stored in the second preset database, the working gas proportion corresponding to each working mode, the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate corresponding to each jet energy value are determined by research personnel through experiments, and the determined parameter values can enable the jet effect corresponding to the energy value to be the best.

For this embodiment, when the gas source module 3 receives the control signal of the method execution device/apparatus/system, it outputs the working gas corresponding to the working gas ratio and the working gas flow rate to the corresponding plasma generation apparatus 6, and when the high-voltage power supply module 4 receives the control signal of the control system 2, it outputs the high-voltage pulse power supply corresponding to the matched voltage amplitude, pulse frequency and pulse width to the corresponding plasma generation apparatus 6, so that the plasma generation apparatus 6 ionizes the introduced working gas according to the received high-voltage pulse power supply to generate the plasma jet.

In this embodiment, the corresponding parameters that can optimize the jet effect in each operating mode may be predetermined, so as to construct the corresponding relationship between the operating mode and the operating gas ratio, and the corresponding relationship between the jet energy value and the voltage amplitude, the pulse frequency, the pulse width, and the operating gas flow rate, and store them in the database. The working gas proportion is determined through the target working mode, the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate are determined through the target jet flow energy value, and the plasma capacity intensity based on the working mode can be adjusted through adjusting the working gas proportion, the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate.

In one implementation, the sending a corresponding control signal to the gas source module 3 according to the matched working gas proportion and working gas flow rate includes:

sending a switching signal to the switching device 313 to cause the switching device 313 to open;

when the number of the gas source sub-modules 31 is one, the control system 2 sends corresponding control signals to the flow control device 314 according to the matched flow rate of the working gas, so that the flow control device 314 delivers the working gas to the corresponding plasma generation device 6 according to the corresponding flow rate of the working gas; when the plurality of air source sub-modules 31 are provided, the air source module 3 further includes an air mixing device (not shown in fig. 3) for mixing the working air, an input port of the air mixing device is connected to an output port of each flow control device 314 through an air pipe, and the control system 2 sends a corresponding control signal to each flow control device 314 according to the matched working air proportion and working air flow rate, so that each flow control device 314 adjusts the flow rate and proportion of the working air according to the received control signal and outputs the working air to the air mixing device. The output port of the gas mixing device is connected with the input port of the plasma generating device 6 through a gas pipe, and the working gas which is uniformly mixed is provided for the plasma generating device 6.

In another implementation manner, the sending corresponding control signals to the gas source module 3 and the high-voltage power supply module 4 according to the target operating mode and the target jet energy value includes:

matching the corresponding identifier of the plasma generating device 6 from a third preset database according to the target working mode;

sending corresponding control signals to the gas source module 3 and the high-voltage power supply module 4 according to the matched identifier, so that the gas source module 3 outputs working gas to the plasma generating device 6 corresponding to the matched identifier, and the high-voltage power supply module 4 outputs a high-voltage pulse power supply to the plasma generating device 6 corresponding to the matched identifier;

wherein the third preset database stores the corresponding relationship between the working mode and the identifier of the plasma generating device 6.

Different experiences can be produced when the plasma generating device 6 with different structures acts on the skin. For example, some plasma generating devices 6 have a massaging structure that can massage simultaneously when the plasma jet generated by the plasma generating device 6 is applied to the skin. In this embodiment, the specific structure of the plasma generator 6 is not limited.

The invention also provides a control system of the multifunctional skin treatment instrument, which can be used as the control system 2 shown in figure 1 and can be used for executing the control method of the multifunctional skin treatment instrument disclosed by any one of the above embodiments of the invention.

Referring to fig. 4, fig. 4 is a block diagram illustrating the structural connection of the control system of the multifunctional skin treatment apparatus according to the embodiment of the present invention.

The system comprises:

an obtaining module 10, configured to obtain a target working mode;

the determining module 20 is configured to match a corresponding range of the jet energy value according to the target operating mode, and determine a target jet energy value according to the matched range of the jet energy value;

and the control module 30 is configured to send corresponding control signals to the gas source module 3 and the high-voltage power supply module 4 according to the target working mode and the target jet energy value, so that the gas source module 3 outputs a correspondingly set working gas to the corresponding plasma generation device 6, and the high-voltage power supply module 4 outputs a correspondingly set high-voltage pulse power supply to the corresponding plasma generation device 6.

In one implementation, the obtaining module 10 includes:

and the acquisition unit is used for acquiring the target working mode through the communication module 1.

In one implementation, the obtaining module 10 includes:

a first receiving unit, configured to receive a first skin detection result sent by the skin detection apparatus;

and the first matching unit is used for matching the corresponding target working mode according to the first skin detection result.

In one implementation, the determining module 20 includes:

the second matching unit is used for matching a corresponding jet flow energy value range from the first preset database according to the target working mode; the first preset database stores the corresponding relation between the working mode and the jet flow energy value range.

In one implementation, the determining module 20 includes:

and the interaction unit is used for sending the matched jet flow energy value range to the communication module 1 to feed back to the user and receiving a target jet flow energy value fed back by the user.

In another implementation manner, the determining module 20 includes:

the second receiving unit is used for receiving a second skin detection result sent by the skin detection device;

the determining unit is used for determining an optimal jet energy value according to the second skin detection result and the matched jet energy value range and sending the optimal jet energy value to the communication module 1 to feed back to a user;

and the third receiving unit is used for receiving the target jet flow energy value fed back by the user and sent by the communication module 1.

In one implementation, the control module 30 includes:

the third matching unit is used for matching corresponding working gas proportions from a second preset database according to the target working mode and matching corresponding voltage amplitude, pulse frequency, pulse width and working gas flow rate from the second preset database according to the target jet flow energy value;

the first sending unit is used for sending a corresponding control signal to the gas source module 3 according to the matched working gas proportion and working gas flow rate;

the second sending unit is used for sending a corresponding control signal to the high-voltage power supply module 4 according to the matched voltage amplitude, pulse frequency and pulse width;

the second preset database stores the corresponding relation between the working mode and the working gas proportion and the corresponding relation between the jet flow energy value and the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate.

In one implementation, the second sending unit includes:

a first sending subunit, configured to send a corresponding control signal to the dc power supply submodule 41 according to the matched voltage amplitude, so that the dc power supply submodule 41 outputs a dc voltage with a corresponding amplitude to the high-voltage pulse power supply submodule 42;

and a second sending subunit, configured to send a corresponding control signal to the high-voltage pulse power supply submodule 42 according to the matched pulse frequency and pulse width, so that the high-voltage pulse power supply submodule 42 outputs a high-voltage pulse power supply with a corresponding frequency and pulse width to the plasma generation device 6.

In one implementation, the first sending unit includes:

a third transmitting subunit, configured to transmit a switching signal to the switching device 313, so that the switching device 313 is turned on and the working gas is output;

and the fourth sending subunit is configured to send a corresponding control signal to the flow control device 314 according to the matched flow rate of the working gas, so that the flow control device 314 delivers the working gas to the corresponding plasma generation device 6 according to the corresponding flow rate and proportion of the working gas.

In another implementation, the control module 30 includes:

the fourth matching unit is used for matching the corresponding identifier of the plasma generating device 6 from the third preset database according to the target working mode;

a third sending unit, configured to send corresponding control signals to the gas source module 3 and the high-voltage power supply module 4 according to the matched identifier, so that the gas source module 3 outputs a working gas to the plasma generation device 6 corresponding to the matched identifier, and the high-voltage power supply module 4 outputs a high-voltage pulse power supply to the plasma generation device 6 corresponding to the matched identifier;

wherein the third preset database stores the corresponding relationship between the working mode and the identifier of the plasma generating device 6.

According to the embodiment of the invention, different skin problems can be solved by selecting different working modes, skin treatment with multiple functions can be realized, the plasma jet energy intensity can be adjusted according to the determined working modes, and skin treatment can be carried out with the optimal plasma jet energy intensity, so that the skin treatment effect is better, and better user experience is obtained.

It should be noted that the first preset database, the second preset database, and the third preset database may be the same database or different databases.

It can be clearly understood by those skilled in the art that, for convenience and simplicity of description, the specific working processes of the system, the device, and the module described above may refer to the corresponding processes in the foregoing method embodiments, and the specific beneficial effects of the system, the device, and the module described above may refer to the corresponding beneficial effects in the foregoing method embodiments, which are not described herein again.

In the several embodiments provided in the present application, it should be understood that the disclosed system, apparatus, and method may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, the division of the modules is only one type of logical functional division, and other divisions may be realized in practice, for example, a plurality of modules or components may be combined or integrated into another apparatus, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, devices or modules, and may be in an electrical, mechanical or other form.

The modules described as separate parts may or may not be physically separate, and parts displayed as modules may or may not be physical modules, may be located in one place, or may be distributed on a plurality of network modules. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment.

In addition, functional modules in the embodiments of the present invention may be integrated into one processing module, or each of the modules may exist alone physically, or two or more modules are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode.

The integrated module, if implemented in the form of a software functional module and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention, which is substantially or partly contributed by the prior art, or all or part of the technical solution may be embodied in a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to perform all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

The above-mentioned embodiments are only used for illustrating the technical solutions of the present invention, and not for limiting the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (17)

1. A control method of a multifunctional skin treatment instrument is applied to the skin treatment instrument and is characterized by comprising the following steps:

acquiring a target working mode;

matching a corresponding jet flow energy value range according to the target working mode, and determining a target jet flow energy value according to the matched jet flow energy value range;

and sending corresponding control signals to the gas source module and the high-voltage power supply module according to the target working mode and the target jet flow energy value, so that the gas source module outputs correspondingly set working gas to the corresponding plasma generating device, and the high-voltage power supply module outputs correspondingly set high-voltage pulse power supply to the corresponding plasma generating device.

2. The control method of the multifunctional skin treatment apparatus according to claim 1, wherein the obtaining the target operation mode comprises:

and acquiring the target working mode through a communication module.

3. The control method of the multifunctional skin treatment apparatus according to claim 1, wherein the obtaining the target operation mode comprises:

receiving a first skin detection result sent by a skin detection device;

and matching a corresponding target working mode according to the first skin detection result.

4. The control method of the multifunctional skin treatment apparatus according to claim 1, wherein the matching of the corresponding jet energy value range according to the target operation mode comprises:

matching a corresponding jet flow energy value range from a first preset database according to the target working mode; and the first preset database stores the corresponding relation between the working mode and the jet flow energy value range.

5. The control method of the multifunctional skin treatment apparatus according to claim 2, wherein the determining the target jet energy value according to the matched jet energy value range comprises:

and sending the matched jet flow energy value range to the communication module to feed back to a user, and receiving a target jet flow energy value fed back by the user.

6. The multifunctional skin treatment apparatus control method according to claim 2, wherein the determining the target jet energy value according to the matched jet energy value range comprises:

receiving a second skin detection result sent by the skin detection device;

determining an optimal jet energy value according to the second skin detection result and the matched jet energy value range, and sending the optimal jet energy value to the communication module to feed back to a user;

and receiving a target jet flow energy value fed back by the user and sent by the communication module.

7. The method for controlling a multi-functional skin treatment apparatus according to claim 1, wherein said sending corresponding control signals to a gas source module and a high voltage power supply module according to said target operation mode and said target jet energy value comprises:

matching corresponding working gas proportions from a second preset database according to the target working mode, and matching corresponding voltage amplitude, pulse frequency, pulse width and working gas flow rate from the second preset database according to the target jet energy value;

sending a corresponding control signal to the gas source module according to the matched working gas proportion and working gas flow rate;

sending a corresponding control signal to the high-voltage power supply module according to the matched voltage amplitude, pulse frequency and pulse width;

the second preset database stores the corresponding relation between the working mode and the working gas proportion and the corresponding relation between the jet flow energy value and the voltage amplitude, the pulse frequency, the pulse width and the working gas flow rate.

8. The method for controlling a multifunctional skin treatment apparatus according to claim 7, wherein the step of sending the corresponding control signal to the high voltage power module according to the matched voltage amplitude, pulse frequency and pulse width comprises:

sending a corresponding control signal to a direct-current power supply submodule according to the matched voltage amplitude so that the direct-current power supply submodule outputs direct-current voltage with corresponding amplitude to the high-voltage pulse power supply submodule;

and sending a corresponding control signal to the high-voltage pulse power supply submodule according to the matched pulse frequency and pulse width so that the high-voltage pulse power supply submodule outputs a high-voltage pulse power supply with corresponding frequency and pulse width to the plasma generating device.

9. The control method of the multifunctional skin treatment apparatus according to claim 7, wherein the sending of the corresponding control signal to the gas source module according to the matched working gas ratio and working gas flow rate comprises:

sending a switching signal to the switching device to enable the switching device to be opened, and outputting working gas;

and sending a corresponding control signal to the flow control device according to the matched working gas flow rate, so that the flow control device can deliver the working gas to the corresponding plasma generating device according to the corresponding working gas flow rate and proportion.

10. The method for controlling a multi-functional skin treatment apparatus according to claim 1, wherein said sending corresponding control signals to a gas source module and a high voltage power supply module according to said target operation mode and said target jet energy value comprises:

matching the identifier of the corresponding plasma generating device from a third preset database according to the target working mode;

sending corresponding control signals to the gas source module and the high-voltage power supply module according to the matched identifier so that the gas source module outputs working gas to the plasma generating device corresponding to the matched identifier and the high-voltage power supply module outputs high-voltage pulse power supply to the plasma generating device corresponding to the matched identifier;

and the third preset database stores the corresponding relation between the working mode and the identification of the plasma generating device.

11. A control system for a multi-functional skin treatment apparatus, the control system comprising:

the acquisition module is used for acquiring a target working mode;

the determining module is used for matching a corresponding jet flow energy value range according to the target working mode and determining a target jet flow energy value according to the matched jet flow energy value range;

and the control module is used for sending corresponding control signals to the gas source module and the high-voltage power supply module according to the target working mode and the target jet flow energy value so as to enable the gas source module to output correspondingly set working gas to the corresponding plasma generating device and enable the high-voltage power supply module to output correspondingly set high-voltage pulse power supply to the corresponding plasma generating device.

12. A multifunctional skin treatment instrument, comprising a host and a handle, wherein the host comprises an air source module, a high voltage power supply module, a power supply module and the control system of the multifunctional skin treatment instrument of claim 11;

the handle comprises a plasma generating device;

the power supply module is connected with the control system, the gas source module, the high-voltage power supply module and the plasma generating device and is used for supplying power to each module;

the control system is connected with the air source module and the high-voltage power supply module and is used for controlling the air source module and the high-voltage power supply module to work;

the gas source module is connected with the plasma generating device and used for outputting correspondingly set working gas to the plasma generating device according to a control signal sent by a control system;

the high-voltage power supply module is connected with the plasma generating device and used for outputting a correspondingly set high-voltage pulse power supply to the plasma generating device according to a control signal sent by a control system.

13. The multi-functional skin treatment instrument of claim 12, wherein said host further comprises:

the communication module is connected with the control system and used for receiving information sent to the communication module by the control system, feeding back the information to a user, acquiring information fed back by the user and sending the information fed back by the user to the control system, wherein the information fed back by the user comprises a target working mode and a target jet energy value.

14. The multifunctional skin treatment apparatus according to claim 13, further comprising:

and the skin detection device is connected with the control system and is used for detecting the skin state and sending the skin detection result to the control system.

15. The multifunctional skin treatment apparatus according to claim 12, wherein said high voltage power supply module comprises:

the direct-current power supply submodule and the high-voltage pulse power supply submodule;

the direct-current power supply submodule is connected with the control system and the high-voltage pulse power supply submodule and is used for outputting direct-current voltage with corresponding amplitude to the high-voltage pulse power supply submodule according to a control signal sent by the control system;

the high-voltage pulse power supply submodule is connected with the control system and the plasma generating device and is used for outputting a high-voltage pulse power supply with corresponding frequency and pulse width to the plasma generating device according to a control signal sent by the control system.

16. The multi-functional skin treatment instrument of claim 12, wherein said gas source module comprises:

the air source submodule is composed of an air tank, a pressure reducing device, a switching device and a flow control device which are connected in sequence;

the gas tank is used for storing working gas;

the decompression device is used for decompressing the working gas stored in the gas tank;

the switch device is connected with the control system and is used for being switched on and off according to a control signal sent by the control system;

when the number of the gas source sub-modules is one, the flow control device is connected with the control system and the plasma generating device and is used for conveying working gas with corresponding flow rate to the plasma generating device according to a control signal sent by the control system;

when the air source submodule is multiple, the air source module further comprises a gas mixing device for mixing working gas, an input port of the gas mixing device is connected with an output port of each flow control device, an output port of the gas mixing device is connected with a plasma generating device, and the flow control devices adjust the flow rate and proportion of the working gas according to control signals sent by the control system and output the working gas to the gas mixing device.

17. The multifunctional skin treatment apparatus according to claim 12, wherein said handle comprises a plurality of plasma generation devices having different structures;

or the number of the handles is multiple, and the structures of the plasma generating devices arranged in the handles are different.

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