KR20200054556A - Dynamic iontophoresis apparatus for mask sheet - Google Patents

Abstract

The present invention relates to a dynamic iontophoresis performing apparatus of a mask sheet, comprising: a skin impedance measurement unit implemented on a mask sheet, and applying an electric current to an electrode pattern for each independent main region to measure skin impedance for each main region; a skin condition determination unit determining skin conditions for each main region based on the skin impedance for each main region; and a dynamic current stimulation pattern generation unit performing dynamic iontophoresis by providing a current stimulation intensity for each main region, applied, based on the skin conditions for each main region, to the electrode pattern for each main region. Therefore, the present invention analyzes skin information of a user in real-time by using the mask sheet, thereby providing effective skin penetration of cosmetic substances.

Description

DYNAMIC IONTOPHORESIS APPARATUS FOR MASK SHEET

The present invention relates to a technique for performing dynamic ion tophoresis of a mask sheet, and more specifically, a dynamic ion of a mask sheet capable of providing effective skin penetration of a cosmetic material by analyzing user's skin information in real time through the mask sheet. It relates to an apparatus for performing toporesis.

Since the epidermis of the upper layer of the skin constituting the skin perceives the cosmetic as a toxin and interferes with the absorption of the cosmetic, the amount of the substantially absorbed cosmetic may be very small. Iontophoresis (iontophoresis) is a technique for increasing the absorption of cosmetics or drugs in such skin, so that a microscopic current flows through the skin so that the active ingredient contained in the charged drug or cosmetics penetrates into the skin by electric repulsion. How to do that. Recently, it has been applied to mask packs and the like to maximize the cosmetic effect.

Korean Registered Patent No. 10-0849392 (2008.07.24) relates to a pad device for introducing ions and a hyperhidrosis treatment device using the same, which can be applied to the face and has no skin irritation, chemical burns, and no fear of electric burns. have. In addition, the device according to the present invention can be configured in a small size, and thus, it can be easily used in offices, homes, and outdoors, not hospitals, by maximizing portability using USB power or batteries.

Korean Registered Patent No. 10-0628946 (2006.09.20) relates to a mask pack set using a micro-current, an insulating first backing layer, a first electric formed of a material having electrical conductivity in contact with the first backing layer A conductive layer, and a mask pack including an active material-containing layer formed to contact the first electrically conductive layer and containing the active material, a power supply unit including a battery for supplying electrical energy, and a flexible wiring unit By including, the active material can be applied to the mask pack and micro-current flows through the active material, thereby maximizing skin absorption of the active material.

Korean Registered Patent No. 10-0849392 (2008.07.24) Korean Registered Patent No. 10-0628946 (2006.09.20)

One embodiment of the present invention is to provide a device for performing a dynamic ion tophoresis of a mask sheet capable of providing effective skin penetration of a cosmetic material by analyzing user's skin information in real time through a mask sheet.

An embodiment of the present invention is to provide a device for performing dynamic ion toporesis of a mask sheet capable of independently providing dynamic ion toporesis for each major region by separately collecting and analyzing skin condition information for each major region of the face do.

According to an embodiment of the present invention, an apparatus for performing dynamic ion toporesis of a mask sheet capable of providing dynamic ion toporesis according to an effective component determined based on the collected skin information and estimating skin condition information of the entire face Want to provide.

Among the embodiments, the device for performing dynamic ion tophoresis of a mask sheet is a skin impedance measuring unit that is implemented on a mask sheet and measures current by applying a current to an electrode pattern for each major part independent of each other to measure skin impedance for each major part, the main part Dynamic ion tophore by providing skin stimulation unit for determining skin condition for each major region based on skin impedance per star and current stimulation strength for each major region applied to the electrode pattern for each major region based on the skin condition for each major region And a dynamic current stimulation pattern generator for performing iontophoresis.

The skin impedance measurement unit may measure the skin impedance for each major region by applying the same current to the electrode pattern for each major region for the same time period.

The skin condition determination unit may generate an estimated user skin profile by estimating the skin condition of the entire face based on the skin condition for each major region.

The skin condition determination unit may receive the user's interaction, modify the estimated user skin profile to determine a user skin profile, and finally determine skin conditions for each major region.

The dynamic current stimulation pattern generation unit may determine an active ingredient of the mask sheet to be provided according to the skin condition of each major region.

The dynamic current stimulation pattern generation unit may determine a dynamic current stimulation pattern according to the determined effective component to simultaneously determine a current stimulation period according to the current stimulation intensity for each major region.

Among the embodiments, the apparatus for performing dynamic ion tophoresis of a mask sheet further includes a skin care history processing unit that stores the dynamic current stimulation pattern as a skin care history in a smartphone.

When the storage is completed, the skin care history processing unit may provide a degree of improvement of the user's skin condition through comparative analysis with an existing skin care history.

The disclosed technology can have the following effects. However, since the specific embodiment does not mean that all of the following effects should be included or only the following effects are included, the scope of rights of the disclosed technology should not be understood as being limited thereby.

The apparatus for performing dynamic ion tophoresis of a mask sheet according to an embodiment of the present invention may independently provide and provide dynamic ion tophoresis for each major region by separately collecting and analyzing skin condition information for each major region of the face.

The apparatus for performing dynamic ion tophoresis of a mask sheet according to an embodiment of the present invention estimates skin condition information of the entire face based on the collected information and provides dynamic ion tophoresis according to the active ingredient determined based on the skin condition information Can be.

1 is a view illustrating a system for performing dynamic ion tophoresis of a mask sheet according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating an apparatus for performing dynamic ion tophoresis in FIG. 1.
FIG. 3 is a flowchart illustrating a process of performing a dynamic ion toporesis performed in the apparatus for performing dynamic ion toporesis in FIG. 1.
FIG. 4 is a flowchart illustrating an embodiment of a process of performing dynamic ion tophoresis performed in the apparatus for performing dynamic ion tophoresis in FIG. 1.
FIG. 5 is an exemplary view illustrating a method of connecting the dynamic ion tophoresis performing apparatus and the mask sheet in FIG. 1.
FIG. 6 is an exemplary diagram illustrating a process of generating a current stimulation pattern based on an active ingredient in the dynamic ion tophoresis performing apparatus in FIG. 1.

Since the description of the present invention is merely an example for structural or functional description, the scope of the present invention should not be interpreted as being limited by the examples described in the text. That is, since the embodiments can be variously changed and have various forms, it should be understood that the scope of the present invention includes equivalents capable of realizing technical ideas. In addition, the purpose or effect presented in the present invention does not mean that a specific embodiment should include all of them or only such an effect, and the scope of the present invention should not be understood as being limited thereby.

Meanwhile, the meaning of terms described in the present application should be understood as follows.

Terms such as "first" and "second" are for distinguishing one component from other components, and the scope of rights should not be limited by these terms. For example, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component.

When a component is said to be "connected" to another component, it may be understood that other components may exist in the middle, although they may be directly connected to the other component. On the other hand, when a component is said to be "directly connected" to another component, it should be understood that no other component exists in the middle. On the other hand, other expressions describing the relationship between the components, that is, "between" and "immediately between" or "neighboring to" and "directly neighboring to" should be interpreted similarly.

Singular expressions are to be understood as including plural expressions unless the context clearly indicates otherwise, and terms such as “comprises” or “have” are used features, numbers, steps, actions, components, parts or the like. It is to be understood that a combination is intended to be present, and should not be understood as pre-excluding the existence or addition possibility of one or more other features or numbers, steps, actions, components, parts or combinations thereof.

In each step, the identification code (for example, a, b, c, etc.) is used for convenience of explanation. The identification code does not describe the order of each step, and each step clearly identifies a specific order in context. Unless stated, it may occur in a different order than specified. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

The present invention can be embodied as computer readable code on a computer readable recording medium, and the computer readable recording medium includes all kinds of recording devices in which data readable by a computer system is stored. . Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, and optical data storage devices. In addition, the computer-readable recording medium can be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

All terms used herein have the same meaning as generally understood by a person skilled in the art to which the present invention pertains, unless otherwise defined. The terms defined in the commonly used dictionary should be interpreted as being consistent with the meanings in the context of the related art, and cannot be interpreted as having ideal or excessively formal meanings unless explicitly defined in the present application.

1 is a view illustrating a system for performing dynamic ion tophoresis of a mask sheet according to an embodiment of the present invention.

Referring to FIG. 1, the system 100 for performing dynamic ion tophoresis of a mask sheet may include a mask sheet 110, a device 130 for performing dynamic ion tophoresis, and a database 150.

The mask sheet 110 may correspond to a beauty product capable of supplying various nutrients and moisture to the skin using a sheet made according to the shape of the face. The mask sheet 110 may be manufactured in various forms, and may be implemented as being limited to use only for a specific part of the face. In one embodiment, the mask sheet 110 may be implemented by including a microelectrode, the microelectrode may be disposed only in all or a part of the mask sheet 110 or may be disposed by forming a constant pattern, The mask sheet 110 may be implemented by being separately arranged in a specific area. In one embodiment, the mask sheet 110 may be connected to the dynamic ion tophoresis performance device 130 through a network.

In one embodiment, the mask sheet 110 may be provided with a micro needle (micro needle) penetrating the user's skin on one surface. The micro needle (micro needle) corresponds to a micro-sized micro-structure such that the human sensory organs do not feel pain, and may provide an effect of effectively delivering a bioactive substance to the subdermal dermal layer. In another embodiment, the mask sheet 110 may be implemented such that microneedles are provided for each major part of the face, and an intensive dynamic ion tophoresis may be performed by arranging microelectrodes with respect to the region where the microneedles are combined.

The dynamic ion tophoresis performance device 130 may collect information about a user's skin condition in real time through the mask sheet 110, and analyze it to dynamically generate a current stimulation pattern for each major region. It may correspond to a computing device. Ion toporesis is one of the methods of drug transdermal delivery, and may correspond to a technique for introducing an image component of the dermal layer of the skin using microcurrent. In particular, Ion Toporesis can provide dozens of times more skin permeation effect than the conventional simple diffusion method, and is called 'needle-free injection', and it can minimize skin damage with its own pulsed iontophoretic injection technology. have. The dynamic ion tophoresis performance device 130 may be connected to the mask sheet 110 and a wired network or a wireless network such as Bluetooth or WiFi, and may perform communication with the mask sheet 110 through a wired or wireless network. .

In one embodiment, the device for performing dynamic ion tophoresis 130 may store information required in the process of performing dynamic ion tophoresis in conjunction with the database 150. Meanwhile, unlike the FIG. 1, the dynamic ion tophoresis performance device 130 may be implemented by including the mask sheet 110 or the database 150 therein.

The database 150 may store various pieces of information required in the process of performing the dynamic ion toporesis on the basis of the skin condition for each major region by the dynamic ion toporesis performing apparatus 130. For example, the database 150 may store skin conditions for each major region received from the mask sheet 110, and estimate the skin condition of the entire face based on the skin conditions for each major region, thereby estimating the estimated user skin profile. It may be stored, but is not limited thereto, and information collected or processed in various forms may be stored in a process of performing a dynamic ion tophoresis based on skin conditions for each major region.

FIG. 2 is a block diagram illustrating an apparatus for performing dynamic ion tophoresis in FIG. 1.

Referring to FIG. 2, the device for performing dynamic ion tophoresis 130 includes a skin impedance measurement unit 210, a skin condition determination unit 230, a dynamic current stimulation pattern generation unit 250, and a skincare history processing unit 270. And it may include a control unit 290.

The skin impedance measurement unit 210 may be implemented on the mask sheet 110 and apply current to the electrode patterns for each major region independent of each other to measure skin impedance for each major region. The mask sheet 110 may configure an electrode pattern for each major region by arranging fine electrodes separated into independent regions for the main region, for example, forehead, eye, nose, and mouth, and the skin impedance measurement unit 210 ) Is connected to the electrode pattern for each main part to apply a current to measure skin impedance for each main part. Here, the electrode pattern is implemented by being included in the mask sheet 110, and the movement path of the current and the location of the skin to which the current is directly transferred may be changed depending on the arrangement and arrangement, and may be implemented with a conductive material such as a conductive film.

In one embodiment, the skin impedance measurement unit 210 may measure the skin impedance for each major region by applying the same current to the electrode pattern for each major region for the same time period. The skin impedance measurement unit 210 can minimize the indirect effect on the skin impedance measurement result by applying the collection conditions from the electrode pattern to all of the main areas. Since the electrode patterns for each main region implemented on the mask sheet 110 are independently configured, the skin impedance measurement unit 210 applies the same conditions as the intensity, time, etc. of the current provided to each electrode pattern from the main region. Can effectively measure the skin impedance.

In one embodiment, the skin impedance measurement unit 210 may measure a current or voltage flowing between mutually spaced electrode patterns. The electrode patterns disposed on the mask sheet 110 may be independently arranged for each main portion, and the electrode pattern for each main portion may be composed of a single electrode pattern or a plurality of different electrode patterns. When the electrode pattern for a specific main part is composed of a plurality of electrode patterns, and each electrode pattern is spaced apart from each other, the skin impedance measurement unit 210 measures the intensity of the current or the magnitude of the voltage flowing between the different electrode patterns. Can be. The measured current or voltage may be utilized by the skin condition determination unit 230 to determine the skin condition for the corresponding main site.

The skin condition determination unit 230 may determine the skin condition for each major region based on the skin impedance for each major region. The skin condition determining unit 230 may determine moisture, oiliness, color, elasticity, etc. as the skin condition for each major part based on the skin impedance, and may provide information on the skin condition according to the skin impedance stored in the database 150. Can be utilized. In another embodiment, the skin condition determination unit 230 may adjust skin conditions for each major region according to skin impedance in consideration of user's body information. Even the same skin impedance may have different skin conditions according to the user's body characteristics, and the skin condition determination unit 230 determines the skin condition based only on the skin impedance or additionally considers the user's body information. Can decide.

In one embodiment, the skin condition determination unit 230 may generate an estimated user skin profile by estimating the skin condition of the entire face based on the skin condition for each major region. The skin condition determination unit 230 may determine the skin condition of the entire face by integrating the skin conditions for each major region, and generate an estimated user skin profile using the skin conditions for each major region and the skin condition of the entire face. The estimated user skin profile may be used as an index for the current estimated skin condition of the user, including skin condition for each major region, skin condition information for the entire face, and body information of the user. In particular, the dynamic ion tophoresis performance device 130 is a skin condition determination unit 230 by learning the estimated user skin profile including information about the skin condition of the entire face according to the skin condition for each major region in advance It can be used to estimate the skin condition of the entire face from the star skin condition.

In one embodiment, the skin condition determination unit 230 may receive the user's interaction and modify the estimated user skin profile to determine the user's skin profile and finally determine the skin condition for each major region. The skin condition determining unit 230 may provide the estimated user skin profile to the user, and may perform a correction on the estimated user skin profile by receiving a confirmation or modification request of the user. Correction to the estimated user skin profile may be performed through a method in which the user selects a measurement result for a specific major region to perform skin condition measurement for the corresponding major region, and updates the skin condition through direct input from the user. Method can be used.

The dynamic current stimulation pattern generation unit 250 may perform dynamic iontophoresis by providing current stimulation intensity for each major region applied to the electrode pattern for each major region based on the skin condition for each major region. The dynamic iontophoresis may correspond to performing real-time or periodic control for the iontophoresis. More specifically, the dynamic current stimulation pattern generation unit 250 may control the current stimulation applied to the electrode pattern formed for each of the major regions based on the skin condition for each major region.

In particular, the dynamic current stimulation pattern generation unit 250 may be operated organically with the skin condition determination unit 230 to perform periodic control. The dynamic current stimulation pattern generation unit 250 generates intensity and time of current stimulation for each major region as a current stimulation pattern, and re-measures the skin condition through the skin condition determination unit 230 when current supply according to the current stimulation pattern is completed. The current stimulation pattern can be regenerated by reflecting the re-measured results. The dynamic current stimulation pattern generation unit 250 may perform dynamic ion tophoresis through repetition of a corresponding process.

In one embodiment, the dynamic current stimulation pattern generation unit 250 may determine an active ingredient of the mask sheet 110 to be provided according to skin conditions for each major region. The active ingredient may correspond to the cosmetic ingredient applied to the mask sheet 110, and since the cosmetic effect varies depending on the main region and skin condition, the most effective active ingredient is determined under the conditions to determine the effect of the mask sheet 110. Can be improved.

More specifically, the dynamic current stimulation pattern generation unit 250 may determine the current stimulation pattern for the corresponding main part based on the determined effective component. The mask sheet 110 may form an electrode pattern of an independent region for each major region, and may be implemented by including different active ingredients for each electrode pattern. Accordingly, the dynamic current stimulation pattern generation unit 250 may perform optimized ion tophoresis for each major region by determining the most effective active ingredient according to the skin condition for each major region.

In one embodiment, the dynamic current stimulation pattern generation unit 250 may determine a dynamic current stimulation pattern according to the determined effective component to simultaneously determine the current stimulation period according to the current stimulation intensity for each main part. The dynamic current stimulation pattern generation unit 250 may determine the current stimulation intensity and period based on the current stimulation pattern table including the current stimulation intensity and current stimulation cycle according to the current stimulation pattern. For example, if the active ingredient for each major region is determined, one of a plurality of predefined current stimulation patterns may be determined according to the active ingredient, and the current stimulation pattern may be searched for in the current stimulation pattern table to correspond to the current stimulus intensity and The cycle can be determined.

In one embodiment, the dynamic current stimulation pattern generation unit 250 may determine the current stimulation pattern in consideration of both user conditions such as characteristics of the main site, skin condition, and body information, and environmental conditions such as time, weather, and temperature. . Since the user's skin can be influenced not only by the user's current body condition, but also by the current weather or surrounding environment, the dynamic current stimulation pattern generator 250 considers environmental factors around the user, resulting in the final current. Stimulus patterns can be generated.

In one embodiment, the dynamic current stimulation pattern generation unit 250 calculates the effective component absorption rate for each major site during the process of performing dynamic ion tophoresis, and performs the ion tophoresis performance when the effective ingredient absorption rate exceeds a specific criterion. Not much can be stopped independently. The effective component absorption rate may be mathematically calculated based on a dynamic ion tophoresis providing time, current intensity, and period, or may be determined by estimating according to a change in skin impedance for each major region.

For example, as the active ingredient is absorbed into the skin, the skin impedance may increase, and as the dynamic ion tophoresis progresses, the rate of change of the skin impedance may gradually decrease from a high value to a low value. When the rate of change of the skin impedance falls below a threshold, it is determined that the active ingredient of the mask sheet 110 is mostly absorbed by the skin, and the dynamic current stimulation pattern generation unit 250 may stop dynamic ion tophoresis of the corresponding main site. . The dynamic current stimulation pattern generation unit 250 provides independent ion tophoresis for each major region and can simultaneously measure skin impedance for each major region in real time, and as a result, calculates an effective portion absorption rate or skin impedance change rate for each major region. Therefore, it is possible to automatically determine whether to stop dynamic ion tophoresis for each major site.

The skincare history processing unit 270 may store the dynamic current stimulation pattern as a skincare history in the smartphone. When the device for performing dynamic ion tophoresis 130 is implemented as a beauty device rather than a smartphone, the device for performing dynamic ion tophoresis 130 may operate in conjunction with a smartphone. Here, the beauty device may correspond to a dedicated device for use of the mask sheet 110, and may include a function for providing ion tophoresis of the mask sheet 110. The skincare history processing unit 270 stores skincare history including skin impedance, active ingredient, skin condition, and dynamic current stimulation pattern for each major region, and can be utilized in performing dynamic ion tophoresis for the same user in the future.

In one embodiment, the skincare history processing unit 270 may provide a degree of improvement of the user's skin condition through comparison analysis with an existing skincare history when storage is completed. The skin care history processing unit 270 extracts information such as a skin care cycle through the mask sheet 110 based on the skin care history, the most recent point of use, and the rate of improvement after skin care, and thus the mask sheet 110 for the current user The degree of improvement in skin condition as a result of use can be calculated and provided. The degree of skin condition improvement may include information on whether the skin condition is improved for each major region and the entire face, and numerical information.

The control unit 290 controls the overall operation of the dynamic ion tophoresis performance device 130, the skin impedance measurement unit 210, the skin condition determination unit 230, the dynamic current stimulation pattern generation unit 250 and skin care A control flow or data flow between the history processing units 270 may be managed.

FIG. 3 is a flowchart illustrating a process of performing a dynamic ion toporesis performed in the apparatus for performing dynamic ion toporesis in FIG. 1.

Referring to FIG. 3, the device for performing dynamic ion tophoresis 130 is implemented on the mask sheet 110 through the skin impedance measurement unit 210 and applies current to electrode patterns for each major region independent of each other, so that each major region Skin impedance may be measured (step S310). The dynamic ion tophoresis performing apparatus 130 may determine the skin condition for each major region based on the skin impedance for each major region through the skin condition determination unit 230 (step S330).

The dynamic ion tophoresis performing apparatus 130 provides dynamic stimulation intensity by providing current stimulation intensity for each major part applied to the electrode pattern for each major part based on the skin condition for each major part through the dynamic current stimulation pattern generator 250 Forresis may be performed (step S350). The dynamic ion tophoresis performing apparatus 130 may store the dynamic current stimulation pattern as a skincare history in a smartphone through the skincare history processing unit 270 (step S370).

In one embodiment, the dynamic current stimulation pattern generation unit 250 may respectively determine execution times for dynamic ion tophoresis for each major region based on skin conditions for each major region. For example, the dynamic current stimulation pattern generation unit 250 determines the execution time of the dynamic ion toporesis for the first main site is 10 minutes according to the skin condition, and the execution time for the second main site is 5 You can decide in minutes. That is, the dynamic current stimulation pattern generation unit 250 considers that the skin condition of the first main region is worse than the skin condition of the second main region, thereby prolonging the dynamic ion tophoresis for the first main region. By providing, it may be possible to intensively manage the first main site.

In one embodiment, the dynamic current stimulation pattern generation unit 250 manages a plurality of times according to a management cycle determined according to skin sensitivity of a corresponding main site with respect to a performance time related to a dynamic ion tophoresis determined based on a skin condition You can decide when to start. For example, when the execution time for providing the dynamic ion toporesis for the forehead among the face regions is determined to be 10 minutes according to the skin condition of the corresponding region, the dynamic current stimulation pattern generator 250 may be determined according to the skin sensitivity of the forehead. A total of 10 management points can be determined by dividing the determined management cycle into 1 minute intervals.

As a result, the dynamic current stimulation pattern generation unit 250 performs dynamic ion re-measurement, skin condition re-determination, and renewal of the current stimulation pattern at 1 minute intervals from the start of the dynamic ion tophoresis. Sheath can be performed. Skin sensitivity, which determines the frequency of care, is a measure of the degree of influence by foreign substances, and can be determined and stored in advance for each major part of the face, for example, forehead, cheeks, nose, mouth, and eyes. As the skin sensitivity can be increased. The higher the skin sensitivity, the shorter the maintenance cycle of dynamic ion tophoresis for the site.

In one embodiment, the dynamic current stimulation pattern generation unit 250 sets a plurality of management time points according to a management cycle calculated through the following equation for the execution time for the dynamic ion tophoresis determined based on the skin condition Can decide.

[Mathematics]

Here, P _i is the management cycle for the main region i, T _i is the execution time for the main region i, k is the proportionality constant, S _i is the skin sensitivity to the main region i, n is the entire main region The number of, N _i is the number of major sites currently being performed by the dynamic ion tophoresis.

Therefore, the maintenance cycle for the main region i may be proportional to the execution time for the main region, and inversely proportional to the skin sensitivity. In addition, the management cycle for the main region i may be proportional to the ratio of the main region currently being performed by the dynamic ion tophoresis among all the main regions except the corresponding main region. The skin sensitivity may have a higher value as the skin is sensitive, and thus, a maintenance cycle is shortly calculated for a main region having a high skin sensitivity, so that dynamic ion tophoresis can be repeatedly performed more frequently.

In one embodiment, the dynamic current stimulation pattern generation unit 250 may determine the longest and the shortest execution time for the execution time for the dynamic ion tophoresis for each major region, and the difference between the execution times is critical If the time is exceeded, it is possible to provide preliminary ion tophoresis for the shortest run time for the main site associated with the longest run time, and then start to provide dynamic ion toporesis for the entire major site.

Here, the preliminary ion tophoresis is for improving the disconnection of the ion tophoresis by major regions, which may occur due to the difference in the execution time according to the provision of the independent ion tophoresis by major regions. It may correspond to the ion tophoresis in a form in which the maintenance cycle or the strength of provision is relatively reduced compared to the tophoresis. The dynamic current stimulation pattern generation unit 250 performs the ion toporesis alone on the main site associated with the longest execution time when the difference in the execution time of the dynamic ion toporesis for each main area is large. It is possible to provide intensive skin care for the entire face by allowing the provided dynamic ion tophoresis to be provided simultaneously.

FIG. 4 is a flowchart illustrating an embodiment of a process of performing dynamic ion tophoresis performed in the apparatus for performing dynamic ion tophoresis in FIG. 1.

Referring to FIG. 4, the device for performing dynamic ion tophoresis 430 may acquire skin impedance for each major region in conjunction with the mask sheet 410. To this end, the mask sheet 410 may independently configure the electrode pattern for each major region, independently measure the skin impedance for each major region, and perform a dynamic ion toporesis on the skin impedance for each major region (430) ). The apparatus for performing dynamic ion tophoresis 430 may receive data through wireless communication with a mask sheet 410 and a separate device connected to the mask sheet 410 or attached to the mask sheet 410.

The apparatus for performing dynamic ion tophoresis 430 may determine the skin condition of each user's main part based on the skin impedance information and the skin condition information stored in the database 450. In one embodiment, the apparatus for performing dynamic ion toporesis 430 may generate and store a skin condition table for skin impedance and skin condition for each major region in the database 450. The dynamic ion tophoresis performing apparatus 430 may generate a skin condition table based on data collected from various users, and may generate a skin condition classification model as a skin condition table through machine learning.

In one embodiment, the device for performing dynamic ion tophoresis 430 may estimate skin conditions for the entire face based on the skin condition for each major region, and based on the skin condition for each major region and the skin condition for the entire face It is possible to determine the active ingredient for each major part. Here, the active ingredient may correspond to a cosmetic material applied to the mask sheet 410, and the mask sheet 410 may be embodied by different active ingredients for each main part. The apparatus for performing dynamic ion tophoresis 430 may generate a current stimulation pattern for each major region according to an effective component determined for each major region. Since the current stimulation to be absorbed by the skin is different according to the active ingredient, the dynamic ion tophoresis performing device 430 can determine the most optimal active ingredient based on the skin condition of each user's major parts, and It is possible to generate a current stimulation pattern optimized for absorption.

In one embodiment, the apparatus for performing dynamic ion tophoresis 430 may generate and store a current stimulation pattern table for the current stimulation pattern for effective classification. The dynamic ion tophoresis performing apparatus 430 may generate a current stimulation pattern table based on information on the current stimulation pattern for effective classification by reflecting feedback information provided by various users, and model a current stimulation pattern through machine learning. Can be generated as a current stimulation pattern table. In addition, the current stimulation pattern table may include matching information for the current stimulation pattern for effective classification. The current stimulation pattern may correspond to numerical information regarding the intensity, time, and frequency of the current supplied to the electrode pattern applied to the mask sheet 410, and may be expressed as a current stimulation pattern vector composed of the corresponding values.

The apparatus for performing dynamic ion tophoresis 430 may control the intensity, period, and frequency of the current stimulation for each electrode pattern of the mask sheet 410 according to the current stimulation pattern determined for each main region. In one embodiment, the device for performing dynamic ion tophoresis 430 may interwork with a user's smartphone 470, and may generate information generated in the process of performing dynamic ion tophoresis on the mask sheet 410. It can be provided to the smartphone 470.

That is, the dynamic ion tophoresis performance device 430 may provide a degree of improvement in the user's skin condition as a result of comparison analysis with the existing skin care history through interworking with the smartphone 470. In another example, the comparative analysis with the skincare history may be performed inside the smartphone 470, for example, an application installed on the smartphone 470 may be linked with the dynamic ion tophoresis performance device 430 When the dynamic ion tophoresis to the mask sheet 410 is performed, the degree of improvement of the user's skin condition may be automatically analyzed and provided to the user.

FIG. 5 is an exemplary view illustrating a method of connecting the dynamic ion tophoresis performing apparatus and the mask sheet in FIG. 1.

Referring to FIG. 5, the device for performing dynamic ion tophoresis 130 may be connected to the mask sheet 110 through a cable (Figure (a)). In addition, the dynamic ion tophoresis performance device 130 may be connected to the mask sheet 110 through wireless communication (Figure (b)). In particular, when wirelessly connected to the mask sheet 110, the dynamic ion tophoresis performance device 130 may be connected through NFC (Near Field Communication) or Bluetooth. In this case, the mask sheet 110 may be implemented by including a separate communication device therein for wireless communication with the dynamic ion tophoresis performing device 130, and the communication device is an electrode pattern applied to the mask sheet 110 It can be electrically connected to.

In one embodiment, the dynamic ion tophoresis performing apparatus 130 may be implemented as a device including a low-frequency stimulator capable of providing a current stimulation pattern to the mask sheet 110, and a separate independent device from the low-frequency stimulator It can be implemented to perform dynamic ion tophoresis by interlocking with a low-frequency stimulator. In addition, the dynamic ion tophoresis performance device 130 may be implemented by being included in a smart phone, in which case the smart phone may perform the role of the dynamic ion tophoresis performance device 130. For example, when the smart phone performs the role of the dynamic ion tophoresis performing device 130, the electrode pattern for each main part of the mask sheet 110 and each may be connected through a separate cable, connected to each electrode pattern A plurality of cables may be connected to one earphone terminal.

FIG. 6 is an exemplary diagram illustrating a process of generating a current stimulation pattern based on an active ingredient in the dynamic ion tophoresis performing apparatus in FIG. 1.

Referring to FIG. 6, the device for performing dynamic ion tophoresis 130 may determine an active ingredient of the mask sheet 110 to be provided according to the skin condition of each main part through the dynamic current stimulation pattern generation unit 250, The dynamic current stimulation pattern generation unit 250 may generate a current stimulation pattern based on the determined effective component. In FIG. 6, the dynamic current stimulation pattern generation unit 250 may generate a current stimulation pattern for each major region by utilizing the current stimulation pattern table stored in the database 150.

In one embodiment, the dynamic current stimulation pattern generation unit 250 may generate and store the current stimulation pattern table (Figure (a)) in the database 150 in advance, and classify the current stimulation based on feedback from users. After learning the feedback according to the pattern, a current stimulation pattern model (Figure (b)) can be generated and stored in the database 150. In this case, the training data used in the current stimulation pattern model may consist of an active ingredient and a current stimulation pattern vector, and the current stimulation pattern vector may be composed of various enzymes constituting the current stimulation pattern, for example, In Figure (a), the current stimulation vector for the current stimulation pattern for active ingredient 1 can be expressed as {time, intensity, ...} = {10, 2, ...}.

Although described above with reference to preferred embodiments of the present invention, those skilled in the art variously modify and change the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You can understand that you can.

100: dynamic ion tophoresis performance system of the mask sheet
110: mask sheet 130: dynamic ion tophoresis device
150: database
210: skin impedance measurement unit 230: skin condition determination unit
250: dynamic current stimulation pattern generating unit 270: skin care history processing unit
290: control
410: mask sheet 430: dynamic ion toporesis performance device
450: Database 470: Smartphone

Claims (8)

A skin impedance measurement unit implemented in a mask sheet and applying current to an electrode pattern for each major region independent of each other to measure skin impedance for each major region;
A skin condition determination unit for determining skin conditions for each major region based on the skin impedance for each major region; And
Dynamic of a mask sheet including a dynamic current stimulation pattern generator that performs dynamic iontophoresis by providing current stimulation intensity for each major region applied to the electrode pattern for each major region based on the skin condition for each major region Ion tophoresis performance device.
According to claim 1, wherein the skin impedance measurement unit
A device for performing dynamic ion tophoresis of a mask sheet, characterized in that the same current is applied to the electrode pattern for each major region for the same time period to measure skin impedance for each major region.
According to claim 1, wherein the skin condition determining unit
A device for performing dynamic ion tophoresis of a mask sheet, characterized by generating an estimated user skin profile by estimating the skin condition of the entire face based on the skin condition for each major region.
The method of claim 3, wherein the skin condition determining unit
A device for performing dynamic ion tophoresis of a mask sheet, characterized by determining the user's skin profile by determining the user's skin profile by receiving the user's interaction, and finally determining the skin condition for each major region.
The method of claim 1, wherein the dynamic current stimulation pattern generating unit
A device for performing dynamic ion tophoresis of a mask sheet, characterized in that it determines an active ingredient of the mask sheet to be provided according to the skin condition for each major region.
The method of claim 5, wherein the dynamic current stimulation pattern generating unit
A device for performing dynamic ion tophoresis of a mask sheet, characterized in that by determining a dynamic current stimulation pattern according to the determined effective component, the current stimulation period according to the current stimulation intensity for each major region is determined together.
According to claim 1,
A device for performing dynamic ion tophoresis of a mask sheet, further comprising a skin care history processing unit that stores the dynamic current stimulation pattern as a skin care history in a smartphone.
The method of claim 7, wherein the skin care history processing unit
When the storage is completed, a device for performing dynamic ion topography of a mask sheet, characterized in that it provides a degree of improvement of a user's skin condition through a comparative analysis with an existing skin care history.

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