Non-invasive skin care system having microwave-applied skin lifting function

The non-invasive skin beauty system uses microwaves to contract collagen and form new collagen, enhancing skin elasticity and safety, while optimizing treatments with AI and cooling, addressing the limitations of non-invasive and invasive procedures.

WO2026134731A1PCT designated stage Publication Date: 2026-06-25SEVEN U CO LTD

Patent Information

Authority / Receiving Office
WO · WO
Patent Type
Applications
Current Assignee / Owner
SEVEN U CO LTD
Filing Date
2025-11-21
Publication Date
2026-06-25

AI Technical Summary

Technical Problem

Non-invasive skin procedures lack immediate and definite effects, and may cause skin irritation or pain, while invasive procedures pose safety risks and recovery issues.

Method used

A non-invasive skin beauty system using microwaves to vibrate moisture and concentrate heat in the dermis layer, promoting collagen contraction and formation, with cooling to protect the skin surface and reduce pain, and utilizing AI for optimized microwave irradiation based on skin condition measurement.

Benefits of technology

Enhances skin elasticity through collagen formation, improves safety and satisfaction by reducing pain, and provides customized beauty solutions like skin lifting, obesity treatment, and fat reduction.

✦ Generated by Eureka AI based on patent content.

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Abstract

The present invention relates to a non-invasive skin care system having a microwave-applied skin lifting function and, more specifically, to a non-invasive skin care system having a microwave-applied skin lifting function, which performs a skin procedure in a non-invasive manner, and vibrates moisture in the skin by using microwaves to concentrate heat on the dermis layer, thereby contracting collagen fibers and promoting the formation of new collagen, to enable a skin-lifting effect and the maintenance of more elastic skin. In addition, the non-invasive skin care system can improve safety and procedural satisfaction by cooling a skin contact area during the microwave procedure to protect the skin surface and reduce pain.
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Description

Non-invasive skin beauty system with microwave-applied skin lifting function

[0001] The present invention relates to a non-invasive skin beauty system having a microwave-applied skin lifting function, wherein a skin treatment is performed in a non-invasive manner, and by using microwaves to vibrate moisture within the skin and concentrate heat in the dermis layer, the collagen fibers contract and the formation of new collagen is promoted, thereby providing a skin lifting effect to maintain more elastic skin, and furthermore, the safety and satisfaction of the treatment can be improved by cooling the skin contact area during the microwave treatment to protect the skin surface and reduce pain.

[0002] Generally, the skin is composed of three layers: the epidermis, the dermis, and the subcutaneous fat layer, which perform a barrier function to maintain homeostasis on the surface. The epidermis is the outermost layer of the skin and, depending on its location and function, consists of several layers such as the stratum corneum, stratum lucidum, stratum granulosum, stratum spinosum, and stratum basale, which are responsible for functions such as protection, defense, and secretion.

[0003] The skin can generally be divided into three layers: the epidermis, dermis, and subcutaneous fat layer. The epidermis consists of a stratum corneum 10–20 µm thick and a stratum 50–100 µm thick layer. The epidermis is the thinnest and outermost layer of the skin. In particular, the stratum corneum serves as the primary barrier protecting the body from transdermal absorption and water loss.

[0004] The dermis, located below the epidermis and constituting the majority of the skin, consists of a papillary layer containing water, proteins, carbohydrates, mucopolysaccharides, minerals, and inorganic salts in a jelly-like state, where capillaries involved in blood circulation and lymphatic vessels transporting lymph are located, and a reticular layer containing collagen, a connective tissue fiber associated with skin wrinkles, elastin, an elastic fiber providing skin elasticity, and a matrix (a water reservoir).

[0005] Recently, as described in Patent Document 1, various forms of skin procedures are being performed for skin aesthetics, such as skin lifting. Among these, the most representative methods include applying beneficial substances containing nutrients to the skin, directly injecting active ingredients into the skin, and using lasers or high frequency to induce regeneration and activity of the skin layers.

[0006] Non-invasive procedures are those that do not involve skin incisions, such as ultrasound and radiofrequency, while minimally invasive procedures are those that involve minimal invasiveness, such as botulinum toxin and HA fillers. Invasive procedures are those that invade the body by making incisions or holes in the skin, such as facelifts, liposuction, and breast augmentation.

[0007] Non-invasive procedures have the advantage of being painless because they do not involve processes such as skin incisions or making holes as in invasive procedures, and they also eliminate safety issues and recovery problems at the invasive site.

[0008] However, non-invasive procedures have limitations in that they cannot confirm immediate and definite effects compared to invasive procedures, and even in the case of non-invasive procedures, depending on the method of treatment, there is a problem of potentially causing unnecessary skin irritation or pain that does not align with the purpose of the procedure.

[0009] Therefore, there is a need to develop technology that can enhance the effectiveness of non-invasive procedures while maintaining the advantages of such procedures, which do not cause safety issues like incisions, and prevent skin damage that may result from these procedures.

[0010] The present invention aims to solve the above-mentioned problems by performing a skin procedure in a non-invasive manner, using microwaves to vibrate moisture within the skin and concentrate heat in the dermis layer to contract collagen fibers and promote the formation of new collagen, thereby providing a skin-lifting effect to maintain more elastic skin, and furthermore, by cooling the skin contact area during the microwave procedure to protect the skin surface and reduce pain, the invention aims to improve safety and satisfaction with the procedure.

[0011] In addition, the objective is to measure the skin condition of the patient and utilize this measurement data to optimize whether or not to perform microwave irradiation based on artificial intelligence, thereby enabling the application of the most suitable skin beauty method for each patient, as well as to further improve not only the efficiency of microwave irradiation but also safety by enabling real-time monitoring of the microwave irradiation process.

[0012] In addition, the objective is to enable the accumulation and verification of the skin data of the subject through the system described above, and to utilize this to provide customized skin beauty solutions such as not only skin lifting but also obesity treatment, fat reduction, and skin elasticity improvement.

[0013] The problems that the present invention aims to solve are not limited to those mentioned above, and other problems that the present invention aims to solve that are not mentioned herein will be clearly understood by those skilled in the art from the description below.

[0014] The present invention comprises: a skin condition measuring unit (100) that measures the skin condition of a subject and generates skin condition signal information; a skin condition judgment unit (200) that receives the skin condition signal information measured by the skin condition measuring unit (100) and generates microwave irradiation judgment signal information for the subject based on the received skin condition signal information; and a microwave treatment unit (300) that receives the microwave irradiation judgment signal information determined by the skin condition judgment unit (200), irradiates microwaves onto the skin according to the received microwave irradiation judgment signal information, and generates microwave irradiation state signal information as the microwaves are irradiated. and a monitoring unit (400) that receives microwave irradiation status signal information generated by the microwave treatment unit (300), monitors the received microwave irradiation status signal information, and notifies the operator; wherein the skin condition measurement unit (100) includes a skin measurement sensor that detects the skin condition by contacting the skin of the subject, and the skin condition judgment unit (200) includes a learning module (210) that stores and learns skin condition signal information measured by the skin condition measurement unit (100) for a certain period in a skin condition where microwave irradiation is not required; and a judgment module (220) that generates microwave irradiation judgment signal information including whether to irradiate the subject by comparing the skin condition signal information learned by the learning module (221) with the skin condition signal information generated in real time by the skin condition measurement unit (100); and the microwave treatment unit (300) is a means for irradiating microwaves by adhering to the skin of the subject, 2.A non-invasive skin beauty system having a microwave-applied skin lifting function is provided as a technical solution, characterized by comprising: a handpiece unit (310) including a microwave irradiation unit (311) that generates a microwave of 45 GHz and a cooling unit (312) that cools the skin at a skin contact area; and a display unit (320) that displays to the operator skin condition signal information generated by the skin condition measuring unit (100), microwave irradiation judgment signal information including whether or not to irradiate microwave generated by the skin condition judgment unit (200), microwave irradiation status signal information generated by the microwave treatment unit (300), and monitoring information of the monitoring unit (400) based on the microwave irradiation status signal information.

[0015] The present invention performs a skin treatment in a non-invasive manner by using microwaves to vibrate moisture within the skin and concentrate heat in the dermis layer, thereby contracting collagen fibers and promoting the formation of new collagen. This provides a skin-lifting effect, allowing for the maintenance of more elastic skin. Furthermore, by cooling the skin contact area during the microwave treatment, the invention protects the skin surface and reduces pain, thereby improving safety and treatment satisfaction.

[0016] In addition, by measuring the skin condition of the patient and utilizing this measurement data to optimize whether or not to perform microwave irradiation based on artificial intelligence, it is possible to apply the most suitable skin beauty method for each patient, and by enabling real-time monitoring of the microwave irradiation process, it has the effect of further improving not only the efficiency of microwave irradiation but also safety.

[0017] Furthermore, the aforementioned system enables the accumulation and verification of the patient's skin data, and by utilizing this, it is effective in providing customized skin beauty solutions such as not only skin lifting but also obesity treatment, fat reduction, and skin elasticity improvement.

[0018] FIG. 1 is a block diagram showing the overall configuration of a non-invasive skin beauty system according to the present invention.

[0019] FIG. 2 is a block diagram illustrating a skin condition determination unit according to the present invention.

[0020] FIG. 3 is a block diagram illustrating a microwave treatment unit according to the present invention.

[0021] FIG. 4 is a block diagram illustrating a monitoring unit according to the present invention.

[0022] FIG. 5 is a block diagram illustrating the overall configuration of a non-invasive skin beauty system according to the present invention.

[0023] FIG. 6 is a drawing embodying a handpiece portion according to the present invention.

[0024] <Explanation of Drawing Symbols>

[0025] 100 : Skin condition measurement section

[0026] 200 : Skin condition judgment unit

[0027] 210 : Learning Module

[0028] 220 : Judgment Module

[0029] 220-1 : Skin condition signal information storage unit

[0030] 220-2 : Change Value Calculation Unit

[0031] 220-3 : State Derivation Section

[0032] 300: Microwave treatment unit

[0033] 310: Handpiece section

[0034] 311: Microwave Irradiation Unit

[0035] 312 : Cooling section

[0036] 320 : Display section

[0037] 400 : Monitoring Department

[0038] 410 : Notification Information Determination Unit

[0039] 420 : Notification Department

[0040] The present invention comprises: a skin condition measuring unit (100) that measures the skin condition of a subject and generates skin condition signal information; a skin condition judgment unit (200) that receives the skin condition signal information measured by the skin condition measuring unit (100) and generates microwave irradiation judgment signal information for the subject based on the received skin condition signal information; and a microwave treatment unit (300) that receives the microwave irradiation judgment signal information determined by the skin condition judgment unit (200), irradiates microwaves onto the skin according to the received microwave irradiation judgment signal information, and generates microwave irradiation state signal information as the microwaves are irradiated. and a monitoring unit (400) that receives microwave irradiation status signal information generated by the microwave treatment unit (300), monitors the received microwave irradiation status signal information, and notifies the operator; wherein the skin condition measurement unit (100) includes a skin measurement sensor that detects the skin condition by contacting the skin of the subject, and the skin condition judgment unit (200) includes a learning module (210) that stores and learns skin condition signal information measured by the skin condition measurement unit (100) for a certain period in a skin condition where microwave irradiation is not required; and a judgment module (220) that generates microwave irradiation judgment signal information including whether to irradiate the subject by comparing the skin condition signal information learned by the learning module (221) with the skin condition signal information generated in real time by the skin condition measurement unit (100); and the microwave treatment unit (300) is a means for irradiating microwaves by adhering to the skin of the subject, 2.A non-invasive skin beauty system having a microwave-applied skin lifting function is provided as the best form for implementing the invention, characterized by comprising: a handpiece unit (310) including a microwave irradiation unit (311) that generates a microwave of 45 GHz and a cooling unit (312) that cools the skin at a skin contact area; and a display unit (320) that displays to the practitioner skin condition signal information generated by the skin condition measuring unit (100), microwave irradiation judgment signal information including whether or not to irradiate microwave generated by the skin condition judgment unit (200), microwave irradiation status signal information generated by the microwave treatment unit (300), and monitoring information of the monitoring unit (400) based on the microwave irradiation status signal information.

[0041] Here, the judgment module (220) may include: a skin condition signal information storage unit (220-1) in which learned skin condition signal information and real-time generated skin condition signal information are stored; a change value calculation unit (220-2) that calculates a change value by substituting the real-time generated skin condition signal information into the learned skin condition signal information; and a state derivation unit (220-3) that generates microwave irradiation judgment signal information including whether to irradiate a patient with microwaves by substituting the change value into previously learned state classification information.

[0042] And the monitoring unit (400) may include: a notification information determining unit (410) that generates notification information determining a character, color, sound, or number to display the microwave irradiation status signal information based on a display classification for each classified status information corresponding to the microwave irradiation status signal information generated by the microwave treatment unit (300); and a notification unit (420) that provides the notification information to the display unit (320) of the microwave treatment unit (300).

[0043] The advantages and features of the embodiments of the present invention, and the methods for achieving them, will become clear by referring to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below but may be implemented in various different forms. These embodiments are provided merely to ensure that the disclosure of the present invention is complete and to fully inform those skilled in the art of the scope of the invention, and the present invention is defined only by the scope of the claims. Throughout the specification, the same reference numerals refer to the same components.

[0044] In describing the embodiments of the present invention, specific descriptions of known functions or configurations will be omitted if it is determined that such detailed descriptions could unnecessarily obscure the essence of the invention. Furthermore, the terms described below are defined in consideration of their functions in the embodiments of the present invention, and these definitions may vary depending on the intentions or practices of the user or operator. Therefore, such definitions should be based on the content throughout this specification.

[0045] Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings.

[0046] FIG. 1 is a block diagram showing the overall configuration of a non-invasive skin beauty system according to the present invention, FIG. 2 is a block diagram showing a skin condition judgment unit according to the present invention, FIG. 3 is a block diagram showing a microwave treatment unit according to the present invention, FIG. 4 is a block diagram showing a monitoring unit according to the present invention, FIG. 5 is a block diagram showing the overall configuration of a non-invasive skin beauty system according to the present invention, and FIG. 6 is a drawing showing a handpiece unit according to the present invention.

[0047] Referring to FIGS. 1 to 6, the skin drug delivery system according to the present invention includes a skin condition measuring unit (100), a skin condition determining unit (200), a microwave treatment unit (300), and a monitoring unit (400).

[0048] The above skin condition measuring unit (100) measures the skin condition of a subject and generates skin condition signal information, and includes a skin measuring sensor that detects the skin condition by contacting the subject's skin.

[0049] Here, the skin measurement sensor described above can be equipped with various sensors capable of measuring skin moisture, oil, elasticity, temperature, wrinkles, degree of contamination, etc., and numerous such sensors are already publicly known. Furthermore, various publicly known sensors can be selectively applied without being limited to sensors of specific products or structures.

[0050] The skin condition judgment unit (200) receives skin condition signal information measured by the skin condition measurement unit (100) and generates microwave irradiation judgment signal information for the subject based on the received skin condition signal information, and includes a learning module (210) and a judgment module (220).

[0051] More specifically, the skin condition signal information measured by the skin condition measuring unit (100) for a certain period in a skin condition where microwave irradiation is not required is stored and learned through the learning module (210), and the skin condition signal information learned by the learning module (221) is compared with the skin condition signal information generated in real time by the skin condition measuring unit (100) through the judgment module (220) to generate microwave irradiation judgment signal information including whether or not to irradiate the subject with microwaves.

[0052] To this end, the judgment module (220) includes a skin condition signal information storage unit (220-1), a change value calculation unit (220-2), and a state derivation unit (220-3). More specifically, the learned skin condition signal information and the real-time generated skin condition signal information are stored in the skin condition signal information storage unit (220-1), the change value is calculated by substituting the real-time generated skin condition signal information into the learned skin condition signal information through the change value calculation unit (220-2), and the change value is substituted into the learned state classification information through the state derivation unit (220-3) to generate microwave irradiation judgment signal information including whether to irradiate microwaves to the subject.

[0053] Here, the above state classification information refers to information that is pre-learned to determine the state by classifying it into state A when the range of the change value is A, for example, when the change value is 10 or more, it refers to information classified as 'microwave treatment required'.

[0054] Meanwhile, the learning module (210) and the judgment module (220) can use known Artificial Intelligence (AI) modules. That is, it is possible to build an AIoT (Artificial Intelligence of Things) based system through the fusion of the various sensors and the AI ​​modules.

[0055] Here, the artificial intelligence module may be a CNN (Convolutional Neural Networks) model that includes an Inception module in a GAP (Global Average Pooling) layer.

[0056] The artificial intelligence module can produce desired data by learning the weights of multiple inputs through deep learning. In addition, various models such as RNN (Recurrent Neural Network), DNN (Deep Neural Network), and DRNN (Dynamic Recurrent Neural Network) can be utilized as artificial intelligence network models for this learning.

[0057] Here, RNN is a deep learning technique that considers current and past data simultaneously, and a Recurrent Neural Network (RNN) represents a neural network in which the connections between units constituting the artificial neural network form a directed cycle. Furthermore, various methods can be used for structures that can construct a Recurrent Neural Network (RNN); for example, representative examples include the Fully Recurrent Network, Hopfield Network, Elman Network, Echo State Network (ESN), Long Short-Term Memory Network (LSTM), Bi-directional RNN, Continuous-Time RNN (CTRNN), Hierarchical RNN, and Second-Order RNN. Additionally, methods such as Gradient Descent, Hessian Free Optimization, and Global Optimization Method can be used to train the Recurrent Neural Network (RNN).

[0058] Furthermore, conventional CNNs suffer from the problem of high processing speed and computational load. Since the present invention requires iterative computation using immediate additional data, a lighter algorithm is necessary. Therefore, Global Average Pooling (GAP) layers and Inception modules can be applied to the CNN model. Generally, CNNs stack many convolution layers, resulting in a large number of filters. A large number of filters implies that feature maps accumulate accordingly. In other words, it means that the dimensionality of the CNN is very high.

[0059] Handling high dimensions requires a large number of parameters capable of handling them. However, if the number of parameters becomes too large, problems such as overfitting can occur during training. Therefore, a method is needed to reduce dimensionality by decreasing the number of parameters used in the filters. The layer in CNNs that performs this role is the pooling layer.

[0060] In this case, GAP solves this problem by extracting the average from each feature and moving it directly to the classification layer. Consequently, because it directly associates features with categories while preserving the spatial information of the previous feature maps, it can generate a confidence map (= feature map) that indicates which parts of the obtained feature maps played a major role in classifying them into a specific class. Since it does not require separate parameter optimization, it has the advantage of low computational load and the ability to prevent overfitting.

[0061] The Inception architecture is a form in which a small neural network is added inside a neural network, and the small neural network inside is called the Inception module. The Inception module can reduce the feature map through 1x1 convolution, making it effective in terms of processing speed and computational load.

[0062] Accordingly, the above artificial intelligence module may apply a CNN model including an Inception module to the GAP (Global Average Pooling) layer.

[0063] In addition, each communication unit described above or below may utilize Bluetooth, ZigBee, Ultra WideBand (UWB), or Wi-Fi.

[0064] The microwave treatment unit (300) receives microwave irradiation judgment signal information determined by the skin condition judgment unit (200), irradiates microwaves onto the skin according to the received microwave irradiation judgment signal information, and generates microwave irradiation status signal information as the microwaves are irradiated. The microwave treatment unit includes a handpiece unit (310) and a display unit (320).

[0065] More specifically, the handpiece part (310) is a means for irradiating microwaves in close contact with the skin of a patient and includes a microwave irradiation part (311) that generates microwaves of 2.45 GHz and a cooling part (312) that cools the skin at the skin contact area to protect the skin and reduce pain, etc.

[0066] Here, the microwave irradiation is performed by operating a handpiece by the operator. That is, after the operator confirms the microwave irradiation judgment signal information determined by the skin condition judgment unit (200) through the display unit (320), the operator operates the handpiece to correspond to the information, thereby performing microwave irradiation.

[0067] In addition, the display unit (320) displays to the operator skin condition signal information generated by the skin condition measuring unit (100), microwave irradiation judgment signal information including whether or not to irradiate microwaves generated by the skin condition judgment unit (200), microwave irradiation status signal information generated by the microwave treatment unit (300), and monitoring information of the monitoring unit (400) based on the microwave irradiation status signal information.

[0068] Here, the microwave irradiation unit (311) is a handpiece comprising a module that generates microwaves of 2.45 GHz, and is already known as a means applicable to the skin as in Patent Documents 2 and 3, etc., and any known microwave irradiation means can be applied without being limited to a specific product or structure.

[0069] In addition, the device configuration of the microwave treatment unit (300) including the handpiece unit (310) and the display unit (320) may be applied such as the device configuration described in Patent Documents 4 to 7, which were previously filed by the applicant of the present invention.

[0070] Meanwhile, microwave irradiation status signal information resulting from microwave irradiation is information that is displayed as 'good' when microwave irradiation by the handpiece is performed smoothly in accordance with preset frequency or time, or 'bad' when it is not performed smoothly. This information may be displayed directly on the display unit (320) or may be displayed on the display unit (320) in the form of notification information through the monitoring unit (400).

[0071] The monitoring unit (400) receives microwave irradiation status signal information generated by the microwave treatment unit (300), monitors the received microwave irradiation status signal information, and notifies the operator, and includes a notification information determination unit (410) and a notification unit (420).

[0072] More specifically, based on a display classification by pre-classified status information corresponding to the microwave irradiation status signal information generated in the microwave treatment unit (300), a character, color, sound, or number to display the microwave irradiation status signal information is determined through the notification information determining unit (410) to generate notification information, and the notification information is provided to the display unit (320) of the microwave treatment unit (300) through the notification unit (420).

[0073] Here, the above-mentioned classification of display information by status information refers to information that classifies display means such as text (check handpiece), color (blinking red), sound (warning sound), or number (numerical value of the degree of defect) when the microwave irradiation status signal information is 'defective', so that when the status information is A, A notification information is displayed.

[0074] Accordingly, the present invention enables a non-invasive skin treatment by using microwaves to vibrate moisture within the skin and concentrate heat in the dermis layer, thereby contracting collagen fibers and promoting the formation of new collagen, which in turn provides a skin lifting effect and allows for maintaining more elastic skin. Furthermore, it improves safety and treatment satisfaction by cooling the skin contact area during the microwave treatment to protect the skin surface and reduce pain. Additionally, it enables the application of the most suitable skin beauty method for each patient by measuring the patient's skin condition and optimizing the microwave irradiation based on artificial intelligence using this measurement data. Moreover, it further improves not only the efficiency of microwave irradiation but also safety by enabling real-time monitoring of the microwave irradiation process. Furthermore, through the above-mentioned system, it enables the accumulation and verification of the patient's skin data, and by utilizing this data, it enables the provision of customized skin beauty solutions such as skin lifting, obesity treatment, fat reduction, and skin elasticity improvement.

[0075] Meanwhile, in order to prevent the handpiece part (310) from slipping from the user's hand during the procedure, an anti-slip epoxy resin-based foam cover may be placed on the outer surface of the handle of the handpiece part (310).

[0076] More specifically, the foam cover may be formed by mixing 100 parts by weight of a resin mixture in which epoxy resin and polyurethane resin are mixed in a weight ratio of 1:1 to 2.5:1 as a base material, 2 to 3 parts by weight of an inorganic filler in which zeolite and activated carbon are mixed in a weight ratio of 1:1 to 2:1 as an inorganic filler for anti-slip purposes, 1 to 1.5 parts by weight of vinyltriethoxysilane as a dispersant to improve the dispersibility of the inorganic filler, 1 to 2 parts by weight of dicumyl peroxide as a crosslinking agent, and 1 to 2 parts by weight of azodicarbonamide as a foaming agent, and then foam molding the mixture into a cover shape.

[0077] In this case, if each of the above compositions and their contents deviate from the above range, there is a concern that the efficiency of improving anti-slip performance may decrease.

[0078] The present invention is not limited to the embodiments described above and has a diverse scope of application. Furthermore, it is understood that anyone with ordinary knowledge in the field to which the present invention pertains can make various modifications without departing from the essence of the invention as claimed in the claims.

[0079] The present invention enables a non-invasive skin treatment by using microwaves to vibrate moisture within the skin and concentrate heat in the dermis layer, thereby contracting collagen fibers and promoting the formation of new collagen. This provides a skin lifting effect, allowing for the maintenance of more elastic skin. Furthermore, by cooling the skin contact area during the microwave treatment, the skin surface can be protected and pain reduced, thereby improving safety and treatment satisfaction. Additionally, by measuring the skin condition of the patient and utilizing this measurement data to optimize the decision to apply microwaves based on artificial intelligence, the most suitable skin beauty method for each patient can be applied. Moreover, by enabling real-time monitoring of the microwave irradiation process, not only can the efficiency of microwave irradiation but also safety can be further improved. Furthermore, the system allows for the accumulation and verification of the patient's skin data, and by utilizing this data, customized skin beauty solutions such as skin lifting, obesity treatment, fat reduction, and skin elasticity improvement are provided. Therefore, it is expected to be widely used in the industry.

Claims

1. A skin condition measuring unit (100) that measures the skin condition of a subject and generates skin condition signal information; A skin condition judgment unit (200) that receives skin condition signal information measured by the skin condition measurement unit (100) and generates microwave irradiation judgment signal information for a subject based on the received skin condition signal information; A microwave treatment unit (300) that receives microwave irradiation judgment signal information determined by the skin condition judgment unit (200), irradiates microwaves onto the skin according to the received microwave irradiation judgment signal information, and generates microwave irradiation state signal information as the microwaves are irradiated; and A monitoring unit (400) that receives microwave irradiation status signal information generated from the microwave treatment unit (300), monitors the received microwave irradiation status signal information, and notifies the operator; wherein The above skin condition measuring unit (100) is, It includes a skin measurement sensor that detects the skin condition by contacting the skin of the subject, and The above skin condition judgment unit (200) is, A learning module (210) that stores and learns skin condition signal information measured by the skin condition measuring unit (100) for a certain period in a skin condition where microwave irradiation is not required; and The above-mentioned learning module (221) compares the skin condition signal information learned by the above-mentioned learning module (221) with the skin condition signal information generated in real time by the above-mentioned skin condition measurement unit (100) to generate microwave irradiation judgment signal information including whether to irradiate microwaves to the subject; and The above microwave treatment unit (300) is, A handpiece part (310) comprising a microwave irradiation part (311) that generates a microwave of 2.45 GHz and a cooling part (312) that cools the skin at the skin contact area, as a means for irradiating microwaves in close contact with the skin of a patient; and A non-invasive skin beauty system having a microwave-applied skin lifting function, characterized by including: skin condition signal information generated by the skin condition measuring unit (100); microwave irradiation judgment signal information including whether or not to irradiate microwave generated by the skin condition judgment unit (200); microwave irradiation status signal information generated by the microwave treatment unit (300); and a display unit (320) that displays monitoring information of the monitoring unit (400) based on the microwave irradiation status signal information to the practitioner.

2. In Paragraph 1, The above judgment module (220) is, Skin condition signal information storage unit (220-1) that stores learned skin condition signal information and real-time generated skin condition signal information; A change value calculation unit (220-2) that calculates a change value by substituting real-time generated skin condition signal information into the learned skin condition signal information; and A non-invasive skin beauty system having a microwave-applied skin lifting function, characterized by including a state derivation unit (220-3) that generates microwave irradiation judgment signal information including whether to irradiate a subject with microwaves by substituting the above change value into pre-learned state classification information.

3. In Paragraph 1, The above monitoring unit (400) is, A notification information determining unit (410) that generates notification information determining a character, color, sound, or number to display the microwave irradiation status signal information based on a display classification for each classified status information corresponding to the microwave irradiation status signal information generated in the microwave treatment unit (300); and A non-invasive skin beauty system having a microwave-applied skin lifting function, characterized by including: a notification unit (420) that provides the above notification information to the display unit (320) of the microwave treatment unit (300).